Energy Worksheet – Part III. Enabling Technologies
Part III. Enabling Technologies
(Hint: GSR includes glossary and abbreviation sections)
1. What is VRE? Why is energy storage becoming more important part of energy systems?
Ans.
2. What is pumped storage?
Ans.
3. How much was global battery storage? How much of an increase over 2019?
Ans.
4. What is the largest form of thermal energy storage? It is most commonly used in conjunction with which renewable energy?
Ans.
5. Why did renewable hydrogen interest rise in 2020? (Note: GSR considers hydrogen a storage technology.)
Ans.
6. Why are electric vehicles important for the use of renewable energy?
Ans.
7. What is a typical heat pump?
Ans.
Ecology Workbook (part
2
) – Food Chains/Webs
GE
1
3
02 – A. John
Instructions: Using the same species as you did in part 1, do the following:
Food Chains and Webs
1 Food
What does your selected species eat?
What animals eat your selected species?
2 Food Chains
2.1 Diagram
Based on your observations, draw a food chain which includes your selected species. Completely
label the diagram, including what role (producer, etc.) each species represents.
1
Figure 1: Food Web in Chesapeake Bay, USA
2.2 Role
Is your selected species a producer, primary consumer, secondary consumer, or other (specify)?
2
3 Food Web
Draw a food web with as much of your observation area as possible (be sure to include your
selected species)
3
Part I. Solar Energy
1. What is the total amount of power capacity for solar photovoltaics now? How much was added in 2020?
Ans.
2. What three countries have the biggest markets for solar PV?
Ans.
3. What is the status of floating solar?
Ans.
4. What is agricultural PV?
Ans.
5. What has happened to solar PV module prices?
Ans.
6. Why did solar CSP markets grow very slow (1.6%) in 2020 compared to previous years?
Ans.
7. Since 2010, has the costs of CSP gone up or down? By how much?
Ans.
Part II. Wind Energy
1. How much wind power capacity was added in 2020? What is total global wind power capacity?
Ans.
2. GSR states that the record amount of added wind power was primarily due to policy mechanisms. What are some of these policy mechanisms?
Ans.
3. What has made wind energy more competitive and allowed it to compete with fossil fuels?
Ans.
4. Which had more investment – offshore wind power or offshore oil and gas?
Ans.
5. Which countries had more than 20% share of electricity was wind power?
Ans.
RENE WABL E S 202 1
GLOBAL S TAT US REP OR T
2021
2
EXECUTIVE DIRECTOR
Rana Adib
REN21
PRESIDENT
Arthouros Zervos
National Technical University of Athens (NTUA)
R E N 2 1 M E M B E R S
MEMBERS AT L ARGE
Michael Eckhart
Mohamed El-Ashry
David Hales
Kirsty Hamilton
Peter Rae
GOVERNMENTS
Afghanistan
Austria
Brazil
Denmark
Dominican Republic
Germany
India
Mexico
Norway
Republic of Korea
South Africa
Spain
United Arab Emirates
United States of America
SCIENCE AND ACADEMIA
AEE – Institute for Sustainable
Technologies (AEE INTEC)
Council on Energy, Environment and
Water (CEEW)
Fundación Bariloche (FB)
International Institute for Applied
Systems Analysis (IIASA)
International Solar Energy Society (ISES)
National Renewable Energy
Laboratory (NREL)
National Research University Higher
School of Economics, Russia (HSE)
South African National Energy
Development Institute (SANEDI)
The Energy and Resources
Institute (TERI)
INDUSTRY ASSOCIATIONS
Africa Minigrid Developers Association
(AMDA)
Alliance for Rural Electrification (ARE)
American Council on Renewable
Energy (ACORE)
Associação Portuguesa de Energias
Renováveis (APREN)
Association for Renewable Energy of
Lusophone Countries (ALER)
Chinese Renewable Energy Industries
Association (CREIA)
Clean Energy Council (CEC)
European Renewable Energies
Federation (EREF)
Global Off-Grid Lighting Association
(GOGLA)
Global Solar Council (GSC)
Global Wind Energy Council (GWEC)
Indian Renewable Energy Federation
(IREF)
International Geothermal Association
(IGA)
International Hydropower Association
(IHA)
Renewable Energy Solutions for Africa
(RES4Africa) Foundation
Solar Power Europe
World Bioenergy Association (WBA)
World Wind Energy Association
(WWEA)
INTER-GOVERNMENTAL
ORGANISATIONS
Asia Pacific Energy Research Centre
(APERC)
Asian Development Bank (ADB)
ECOWAS Centre for Renewable
Energy and Energy Efficiency
(ECREEE)
European Commission (EC)
Global Environment Facility (GEF)
International Energy Agency (IEA)
International Renewable Energy
Agency (IRENA)
Islamic Development Bank (IsDB)
Regional Center for Renewable
Energy and Energy Efficiency
(RCREEE)
United Nations Development
Programme (UNDP)
United Nations Environment
Programme (UNEP)
United Nations Industrial Development
Organization (UNIDO)
World Bank (WB)
NGOS
Association Africaine pour
l’Electrification Rurale (Club-ER)
CLASP
Clean Cooking Alliance (CCA)
Climate Action Network International
(CAN-I)
Coalition de Ciudades Capitales
de las Americas (CC35)
Energy Cities
Euroheat & Power (EHP)
Fundación Energías Renovables (FER)
Global 100% Renewable Energy
Global Forum on Sustainable
Energy (GFSE)
Global Women’s Network for the
Energy Transition (GWNET)
Greenpeace International
ICLEI – Local Governments for
Sustainability
Institute for Sustainable Energy
Policies (ISEP)
International Electrotechnical
Commission (IEC)
Jeunes Volontaires pour
l’Environnement (JVE)
Mali Folkecenter (MFC)
Power for All
Renewable Energy and Energy
Efficiency Partnership (REEEP)
Renewable Energy Institute (REI)
Renewables Grid Initiative (RGI)
SLOCAT Partnership for Sustainable
Low Carbon Transport
Solar Cookers International (SCI)
Sustainable Energy for All (SEforALL)
World Council for Renewable
Energy (WCRE)
World Future Council (WFC)
World Resources Institute (WRI)
World Wildlife Fund (WWF)
3
R E N E WA B L E E N E R G Y
P OL IC Y NE T WORK
FOR THE 2 1s t CENTURY
REN21 is the only global renewable energy community of actors
from science, governments, NGOs and industry. We provide up-to-date
and peer-reviewed facts, figures and analysis of global developments
in technology, policies and markets. Our goal: enable decision-makers
to make the shift to renewable energy happen – now.
The most successful organisms, such as an octopus, have a decentralised
intelligence and “sensing” function. This increases responsiveness to a
changing environment. REN21 incarnates this approach.
Our more than 2,000 community members guide our co-operative work.
They reflect the vast array of backgrounds and perspectives in society.
As REN21’s eyes and ears, they collect information and share intelligence,
by sending input and feedback. REN21 takes all this information to better
understand the current thinking around renewables and change norms.
We also use this information to connect and grow the energy debate with
non-energy players.
Our annual publications, the Renewables Global Status Report and
the Renewables in Cities Global Status Report, are probably the world’s
most comprehensive crowdsourced reports on renewables. It is a truly
collaborative process of co-authoring, data collection and peer reviewing.
RENEWABLES 2021 GLOBAL STATUS REPORT
Renewables in 2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Ongoing Challenges Towards a
Renewables-Based World . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Buildings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Industry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
Transport . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
Renewable Energy and Climate Change Policy . . . . . . 63
Heating and Cooling in Buildings . . . . . . . . . . . . . . . . . . . 69
Industry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
Transport . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
Systems Integration of Variable Renewable Electricity . . 83
GLOBAL OVERVIEW 2801
POLICY L ANDSCAPE 5802
Bioenergy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
Geothermal Power and Heat . . . . . . . . . . . . . . . . . . . . . . . 100
Hydropower . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106
Ocean Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
Solar Photovoltaics (PV) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Concentrating Solar Thermal Power (CSP) . . . . . . . . . . 133
Solar Thermal Heating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
Wind Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146
MARKE T AND
INDUSTRY TRENDS 8803
Overview of Energy Access . . . . . . . . . . . . . . . . . . . . . . . . . 165
Technologies and Markets . . . . . . . . . . . . . . . . . . . . . . . . . . 167
Business Model Innovations . . . . . . . . . . . . . . . . . . . . . . . . 172
Financing for Renewables-Based Energy Access . . . . 173
National Policy Developments . . . . . . . . . . . . . . . . . . . . . . 178
DISTRIBUTED RENEWABLES
FOR ENERGY ACCESS 16204
REP OR T CI TAT ION
REN21. 2021.
Renewables 2021 Global Status Report
(Paris: REN21 Secretariat).
ISBN 978-3-948393-03-8
Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Foreword . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Executive Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
GSR 2021
TABLE OF CONTENTS
4
Investment in Renewable Energy Capacity . . . . . . . . . . 183
Deploying Renewable Energy Through
Climate Finance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 191
Divestment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193
Integration of Renewables in the Power Sector . . . . . . 199
Advances in the Integration of
Renewables in Transport and Heating . . . . . . . . . . . . . . . 203
Enabling Technologies for Systems Integration . . . . . . 204
Heat Pumps . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 205
Electric Vehicles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 208
Energy Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 211
INVESTMENT FLOWS 18205
ENERGY SYSTEMS
INTEGRATION AND
ENABLING TECHNOLOGIES 19606
Renewable Energy and Carbon Intensity . . . . . . . . . . . . 217
Decarbonisation of End-Use Sectors . . . . . . . . . . . . . . . . 221
Drivers of Business Demand for Renewable Energy . . . 230
Renewable Electricity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231
Renewable Heating and Cooling in Industry . . . . . . . . . 234
Renewables in Transport . . . . . . . . . . . . . . . . . . . . . . . . . . . 236
ENERGY EFFICIENCY,
RENEWABLES AND
DECARBONISATION 21607
FE ATURE:
BUSINESS DEMAND
FOR RENEWABLES 22808
Energy Units and Conversion Factors . . . . . . . . . . . . . . . 240
Data Collection and Validation . . . . . . . . . . . . . . . . . . . . . . 241
Methodological Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242
Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 245
List of Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 253
Photo Credits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254
Endnotes: see full version online at www.ren21.net/gsr
DISCL A IMER:
REN21 releases issue papers and reports to emphasise the importance
of renewable energy and to generate discussion on issues central to the
promotion of renewable energy. While REN21 papers and reports have
benefited from the considerations and input from the REN21 community,
they do not necessarily represent a consensus among network participants
on any given point. Although the information given in this report is the best
available to the authors at the time, REN21 and its participants cannot be
held liable for its accuracy and correctness.
The designations employed and the presentation of material in the maps
in this report do not imply the expression of any opinion whatsoever
concerning the legal status of any region, country, territory, city or area or of
its authorities, and is without prejudice to the status of or sovereignty over
any territory, to the delimitation of international frontiers or boundaries and
to the name of any territory, city or area.
5
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBARS TABLE S
Table 1. Renewable Energy Indicators 2020 . . . . . . . . . 40
Table 2. Top Five Countries 2020 . . . . . . . . . . . . . . . . . . . . 41
Table 3. COVID-19’s Impacts on Employment in Segments
of the Renewable Energy Supply Chain . . . . . . 56
Table 4. New Net Zero Emission and Carbon-Neutral
Targets Set by Countries/Regions in 2020 . . . . 65
Table 5. Targets and Policies for Renewable
Hydrogen, 2020 . . . . . . . . . . . . . . . . . . . . . . . . . . 73
Table 6. Renewable Energy Targets and Policies, 2020 . . 84
Table 7. Distributed Renewables Policies for Electricity
Access, Selected Countries, 2020 . . . . . . . . . . 180
Table 8. Distributed Renewables Policies for Clean
Cooking Access, Selected Countries, 2020 . . . . 181
Sidebar 1. Oil and Gas Suppliers and the Renewable
Energy Transition . . . . . . . . . . . . . . . . . . . . . . . . . 38
Sidebar 2. Impacts of COVID-19 on Renewable
Energy-Related Jobs in 2020 . . . . . . . . . . . . . . . 56
Sidebar 3. Renewable Energy in COVID-19 Stimulus
Packages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
Sidebar 4. “Subsidy Swaps” as a Means to Shift
Financial Support Towards Renewables . . . . . 67
Sidebar 5. Policy Support for Renewable Hydrogen . . . . . 72
Sidebar 6. Renewable Electricity Generation Costs
in 2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160
Sidebar 7. COVID-19 and Energy Demand in
Buildings, Industry and Transport . . . . . . . . . . 220
Sidebar 8. Decarbonisation Through Monitoring,
Reporting and Verification Systems . . . . . . . . 222
B OX E S
Box 1. Renewable Hydrogen in the GSR . . . . . . . . . . . . .31
Box 2. Renewable Energy in Cities . . . . . . . . . . . . . . . . . . 34
Box 3. Sustainability in the GSR . . . . . . . . . . . . . . . . . . . . . 35
Box 4. Trade Policy, Local Content Requirements
and Renewables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Box 5. Utility-Led Activity to Support Renewables . . . . 78
Box 6. Bioenergy and the Bioeconomy . . . . . . . . . . . . . . 97
Box 7. Small-Scale Wind Power . . . . . . . . . . . . . . . . . . . . 159
Box 8. Energy Access, Health and COVID-19 . . . . . . . 165
Box 9. Organisations Leveraging Business
Demand for Renewables . . . . . . . . . . . . . . . . . . . . 231
Box 10. Amazon’s Sourcing of Renewable Electricity . . . 233
Box 11. Elpitiya Plantations’ Sourcing of
Renewable Heat . . . . . . . . . . . . . . . . . . . . . . . . . . . . 235
GSR 2021
TABLE OF CONTENTS
6
Comments and questions are
welcome and can be sent to
gsr@ren21.net
mailto:gsr%40ren21.net?subject=
FIGURE S
Figure 1. Renewable Energy Shares and Targets, G20
Countries, 2019 and 2020 . . . . . . . . . . . . . . . . . . . . . . . 32
Figure 2. Estimated Renewable Energy Share of Total
Final Energy Consumption, 2009 and 2019 . . . . . . 33
Figure 3. Estimated Growth in Modern Renewables
as Share of Total Final Energy Consumption
Between 2009 and 2019 . . . . . . . . . . . . . . . . . . . . . . . . 36
Figure 4. Renewable Share of Total Final Energy
Consumption, by Final Energy Use, 2018 . . . . . . . . 37
Figure 5. Spending on Renewable Energy versus Total
Capital Expenditure, Selected Oil and Gas
Companies, 2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Figure 6. Renewable Energy Contribution to Heating in
Buildings, by Technology, 2009 and 2019 . . . . . . . . 43
Figure 7. Annual Additions of Renewable Power Capacity,
by Technology and Total, 2014-2020 . . . . . . . . . . . . . 52
Figure 8. Shares of Net Annual Additions in Power
Generating Capacity, 2010-2020 . . . . . . . . . . . . . . . . 53
Figure 9. Global Electricity Production by Source, and
Share of Renewables, 2010-2020 . . . . . . . . . . . . . . . . 54
Figure 10. Number of Countries with Renewable Energy
Regulatory Policies, 2010-2020 . . . . . . . . . . . . . . . . . . 60
Figure 11. Status of Countries in Meeting Their 2020
Renewable Energy Targets and Setting
New Ones . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .61
Figure 12. Countries with Selected Climate Change
Policies, Early 2021 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
Figure 13. Sectoral Coverage of National Renewable
Heating and Cooling Financial and Regulatory
Policies, as of End-2020 . . . . . . . . . . . . . . . . . . . . . . . . . 70
Figure 14. National and Sub-National Renewable
Transport Mandates, End-2020 . . . . . . . . . . . . . . . . . .74
Figure 15. Targets for Renewable Power and Electric
Vehicles, as of End-2020 . . . . . . . . . . . . . . . . . . . . . . . . 76
Figure 16. Renewable Energy Feed-in Tariffs and
Tenders, 2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
Figure 17. Estimated Shares of Bioenergy in Total Final
Energy Consumption, Overall and by End-Use
Sector, 2019 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
Figure 18. Global Bioenergy Use for Heating,
by End-Use, 2009-2019 . . . . . . . . . . . . . . . . . . . . . . . . . .91
Figure 19. Global Production of Ethanol, Biodiesel and HVO/
HEFA Fuel, by Energy Content, 2010-2020 . . . . . . . 93
Figure 20. Global Bioelectricity Generation, by Region,
2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
Figure 21. Geothermal Power Capacity and Additions,
Top 10 Countries and Rest of World, 2020 . . . . . . 100
Figure 22. Geothermal Direct Use, Estimates for
Top 10 Countries and Rest of World, 2020 . . . . . . 103
Figure 23. Hydropower Global Capacity, Shares of
Top 10 Countries and Rest of World, 2020 . . . . . . 106
Figure 24. Hydropower Capacity and Additions,
Top 10 Countries for Capacity Added, 2020 . . . . . .107
Figure 25. Solar PV Global Capacity and Annual Additions,
2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
Figure 26. Solar PV Global Capacity, by Country and
Region, 2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
Figure 27. Solar PV Capacity and Additions, Top 10
Countries for Capacity Added, 2020 . . . . . . . . . . . . 120
Figure 28. Solar PV Global Capacity Additions, Shares of
Top 10 Countries and Rest of World, 2020 . . . . . . 122
Figure 29. Concentrating Solar Thermal Power Global
Capacity, by Country and Region, 2010-2020 . . . 134
Figure 30. Thermal Energy Storage Global Capacity and
Annual Additions, 2010-2020 . . . . . . . . . . . . . . . . . . . 135
Figure 31. Solar Water Heating Collectors Global Capacity,
2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
Figure 32. Solar Water Heating Collector Additions, Top 20
Countries for Capacity Added, 2020 . . . . . . . . . . . . 139
Figure 33. Solar District Heating, Global Annual Additions
and Total Area in Operation, 2010-2020 . . . . . . . . 142
Figure 34. Wind Power Global Capacity and Annual
Additions, 2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . 146
Figure 35. Wind Power Capacity and Additions, Top 10
Countries for Capacity Added, 2020 . . . . . . . . . . . . .147
Figure 36. Wind Power Offshore Global Capacity by
Region, 2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153
Figure 37. Global Levelised Costs of Electricity from Newly
Commissioned Utility-Scale Renewable Power
Generation Technologies, 2010 and 2020 . . . . . . . . 161
Figure 38. Top 7 Countries with the Highest Electricity
Access Rate from Distributed Renewable
Energy Solutions, 2019 . . . . . . . . . . . . . . . . . . . . . . . . . 164
Figure 39. Population with Access to Modern Energy
Cooking Services, by Region, 2020 . . . . . . . . . . . . . 166
Figure 40. Per Capita Production of Biogas for Cooking,
Selected Countries, 2015 and 2020 . . . . . . . . . . . . . 168
Figure 41. Sales Volumes of Affiliated Off-Grid Solar
Systems, Selected Regions, 2019 and 2020 . . . . . .170
Figure 42. Shares of Installed Mini-Grids by Technology,
March 2020 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171
Figure 43. Annual Commitments to Off-Grid Renewable
Energy, by Type of Investor, 2013-2019 . . . . . . . . . . .174
Figure 44. Shares of Off-Grid Solar Financing, by Type
of Funding, 2012-2020 . . . . . . . . . . . . . . . . . . . . . . . . . .175
Figure 45. Key Improvements in RISE Indicators,
Selected Regions, 2010, 2015 and 2019 . . . . . . . . . .178
Figure 46. Global Investment in Renewable Power Capacity
in Developed, Emerging and Developing
Countries, 2010-2020 . . . . . . . . . . . . . . . . . . . . . . . . . . 184
Figure 47. Global Investment in Renewable Energy
Capacity, by Country and Region, 2010-2020 . . . 186
Figure 48. Global Investment in Renewable Energy Capacity,
by Technology, 2010, 2019 and 2020 . . . . . . . . . . . . 188
Figure 49. Energy Investments in COVID-19 Recovery
Packages of 31 Countries, January 2020
to April 2021 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189
Figure 50. Share of Renewable Energy Funding in
Climate Mitigation Finance from Multilateral
Development Banks, 2015-2019 . . . . . . . . . . . . . . . . 192
Figure 51. Estimated Global Investment in New Power
Capacity, by Type, 2020 . . . . . . . . . . . . . . . . . . . . . . . . 195
Figure 52. Share of Electricity Generation from Variable
Renewable Energy, Top Countries, 2020 . . . . . . . . 199
Figure 53. Transmission Projects to Integrate Higher
Shares of Renewables . . . . . . . . . . . . . . . . . . . . . . . . . 202
Figure 54. Coupling of the Power, Thermal and Transport
Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 204
Figure 55. Electric Car Global Sales, Top Countries and
Rest of World, 2015-2020 . . . . . . . . . . . . . . . . . . . . . . 208
Figure 56. Share of Global Energy Storage Installed
Capacity, by Technology, 2019 and 2020 . . . . . . . . . 211
Figure 57. Estimated Impact of Renewables and Energy
Efficiency on Global Carbon Intensity, 2013-2018 . . 219
Figure 58. Change in Carbon Intensity of Final Energy
Consumption and Share of Modern Renewables,
Selected Countries, 2008-2018 . . . . . . . . . . . . . . . . . 221
Figure 59. Number of Countries with Carbon Emission
Monitoring, Reporting and Verification Policies,
by Region, 2010-2019 . . . . . . . . . . . . . . . . . . . . . . . . . . 223
Figure 60. Carbon Intensity and Share of Electricity in
Industry, Selected Countries, 2008-2018 . . . . . . . . 225
Figure 61. Indexed Carbon Intensity and Kilometres
Travelled, Passenger Vehicles in Selected
Countries, 2008-2018 . . . . . . . . . . . . . . . . . . . . . . . . . . 227
Figure 62. Corporate Renewable Energy PPAs, Global
Capacity and Annual Additions, 2015-2020 . . . . . 232
7
RENEWABLES 2021 GLOBAL STATUS REPORT
8
This report was commissioned by REN21 and produced in
collaboration with a global network of research partners.
Financing was provided by the German Federal Ministry for
Economic Cooperation and Development (BMZ), the German
Federal Ministry for Economic Affairs and Energy (BMWi) and
the UN Environment Programme. A large share of the research
for this report was conducted on a voluntary basis.
REN21 is committed to mobilising global action to meet
the United Nations Sustainable Development Goals.
9
A C K N O W L E D G E M E N T S
REN2 1 RE SE ARCH DIREC TION TE AM
Hannah E. Murdock
Duncan Gibb
Thomas André
SPECIAL ADVISORS
Janet L. Sawin (Sunna Research)
Adam Brown
Lea Ranalder
CHAPTER AUTHORS
Thomas André (REN21)
Adam Brown
Ute Collier (Green Energy Insights)
Christopher Dent (Edge Hill University)
Bärbel Epp (Solrico)
Duncan Gibb (REN21)
Chetna Hareesh Kumar (REN21)
Fanny Joubert (EcoTraders)
Ron Kamara (EcoTraders)
Nathalie Ledanois
Rachele Levin
Hannah E. Murdock (REN21)
Janet L. Sawin (Sunna Research)
Jonathan Skeen (The SOLA Group)
Freyr Sverrisson (Sunna Research)
Glen Wright (Institute for Sustainable Development and
International Relations)
RESEARCH AND PROJECT SUPPORT
(REN21 SECRETARIAT)
Chetna Hareesh Kumar, Fabio Passaro
Flávia Guerra, Ni Made Dwi Sastriani, Hend Yaqoob,
Stefanie Gicquel, Vibhushree Hamirwasia,
Gwamaka Kifukwe, Yu Yuan-Perrin
COMMUNICATIONS SUPPORT
(REN21 SECRETARIAT)
Tammy Mayer, Laura E. Williamson
Andreas Budiman, Olivia Chen, Katherine Findlay,
Alyssa Harris, Jessica Jones-Langley, Florencia Urbani
EDITING, DESIGN AND LAYOUT
Lisa Mastny, Editor
Leah Brumer, Editor
weeks.de Werbeagentur GmbH, Design
PRODUCTION
REN21 Secretariat, Paris, France
SIDEBAR AUTHORS
Daron Bedrosyan (Energy Sector Management
Assistance Program – ESMAP)
Richard Bridle (International Institute for
Sustainable Development – IISD)
Rabia Ferroukhi (International Renewable
Energy Agency – IRENA)
Celia Garcia (IRENA)
Ivetta Gerasimchuk (IISD)
Arslan Khalid (IRENA)
Muna Abucar Osman (ESMAP)
Tigran Parvanyan (ESMAP)
Pablo Ralon (IRENA)
Michael Renner (IRENA)
Michael Taylor (IRENA)
Hong Yang (ESMAP)
REGIONAL CONTRIBUTORS
CENTRAL AND EAST AFRICA
Mark Hankins (African Solar Designs); Fabrice Fouodji
Toche (Vista Organisation for Education and Social
Development in Africa)
LATIN AMERICA AND CARIBBEAN
Aliosha Behnisch, Gonzalo Bravo, Ignacio Sagardoy
(Fundación Bariloche)
MIDDLE EAST AND NORTH AFRICA
Maged K. Mahmoud, Sara Ibrahim, Akram Almohamd,
Elaff Alfadel (Regional Center for Renewable Energy
and Energy Efficiency – RCREEE)
SOUTHERN AFRICA
Joseph Ngwawi, Kizito Sikuka (Southern African
Research and Documentation Centre)
Note: Some individuals have contributed in more than
one way to this report. To avoid listing contributors
multiple times, they have been added to the group where
they provided the most information. In most cases, the
lead country, regional and topical contributors also
participated in the Global Status Report (GSR) review
and validation process.
RENEWABLES 2021 GLOBAL STATUS REPORT
LEAD COUNTRY CONTRIBUTORS
Austria
Jasmin Haider (Austrian Federal Ministry
for Climate Action)
Australia
Mike Cochran (APAC Biofuel Consultants
– an Ecco Consulting Pty Ltd and
EnergyQuest Pty Ltd joint venture);
Sharon Denny (Global Futuremakers);
Veryan Patterson (University of Tasmania)
Bolivia
Ramiro Juan Trujillo Blanco (Universidad
Católica Boliviana San Pablo)
Brazil
Ricardo Lacerda Baitelo and Rodrigo
Sauaia (Associação Brasileira de Energia
Solar Fotovoltaica – ABSOLAR); Javier
Farago Escobar (Harvard University School
of Engineering and Applied Sciences);
Suani Teixeira Coelho (University of São
Paulo Institute of Energy and Environment);
Clarissa Maria Forecchi Gloria (Divisão de
Promoção de Energia, Itamaraty)
Canada
Christina Caouette
(Natural Resources Canada)
Chile
Rafael Caballero (Energy consultant)
China
João Graça Gomes (China-UK Low Carbon
College, Shanghai Jiao Tong University);
Frank Haugwitz (Asia Europe Clean Energy
(Solar) Advisory Co. Ltd – AECEA); Lihui Xu
(Tsinghua University); Hayan Qin, Guiyong
Yu and Hui Yu (Chinese Wind Energy
Association – CWEA)
Colombia
Andres Rios (Renewable energy expert)
Costa Rica
Guido Godinez and Jairo Quirós-Tortós
(The Electric Power and Energy Research
Laboratory – Universidad de Costa Rica)
Denmark
Jonas Hamann (Danfoss)
Egypt
Hagar Abdel Nabi, Wessam El-Baz,
Ahmed El-Guindy, Omar Oraby
(Nexus Analytica LLC)
France
Romain Mauger (University of Groningen);
Romain Zissler (Renewable Energy Institute)
Germany
Roman Buss (Renewables Academy);
Sebastian Hermann (German
Environment Agency); Alexandra
Langenheld (Agora Energiewende)
Ghana
Nana Asare Obeng-Darko (University of
Eastern Finland Law School)
Greece
Panagiotis Fragkos (E3Modelling);
Costas Travasaros (Greek Solar Industry
Association – EBHE); Ioannis Tsipouridis,
Sara Anastasiou (RED Pro)
Hungary
Csaba Vaszko (Geographer)
India
Sreenivas Chigullapalli (Indian Institute of
Technology Madras); Amit Kumar (The
Energy and Resources Institute – TERI);
Yogesh Kumar Singh (National Institute
of Solar Energy); Amit Saraogi (Oorja
Development Solutions Limited); Daksha
Vaja (Community Science Centre, Vadodara)
Indonesia
Marissa Malahayati (National Instititute
for Environmental Studies)
Japan
Hironao Matsubara (Institute for
Sustainable Energy Policies); Naoko
Matsumoto (Ferris University)
Jordan
Samer Zawaydeh (Association of Energy
Engineers)
Liberia
Wemogar Elijah Borweh
(University of Liberia)
Mexico
Genice Kirat (Instituto de Energías
Renovables, National Autonomous
University of Mexico – UNAM)
Morocco
Lydia El Bouazzati
(Energy policy consultant)
Nepal
Sujan Adhikari (Institute of Engineering,
Thapathali Campus)
Nigeria
Norbert Edomah (Pan-Atlantic
University); Iyabo Olanrele (Nigerian
Institute of Social and Economic
Research); Tolulope Peyibomi Amusat
(Pamodzi Bio Energy Solutions); Austine
Sadiq Okoh (Benue State University,
Makurdi)
Philippines
Manuel Peter (Manila Observatory)
Portugal
Mariana Carvalho, Madalena Lacerda,
Miguel Santos, Susana Serôdio
(Portuguese Renewable Energy
Association – APREN)
Russian Federation
Georgy Ermolenko (Institute for Energy,
National Research University Higher
School of Economics)
Saudi Arabia
Valeria Cantello (Desert Technologies)
South Africa
Sabatha Mthwecu (Solar Rais)
Spain
Silvia Vera García (Institute for the
Diversification and Saving of Energy –
IDAE); Gonzalo Martin (Protermosolar);
Antonio Moreno-Munoz (Universidad de
Cordoba)
Sri Lanka
Namiz Musafer (Integrated
Development Association – IDEA)
Sudan
Mohamed Alhaj (Clean Energy 4 Africa)
Suriname
Abadal Colomina (Inter-American
Development Bank)
Sweden
Abdenour Achour (Chalmers
University of Technology)
Ukraine
Andriy Konechenkov (Ukrainian Wind
Energy Association), Galyna Trypolska
(Institute for Economics and Forecasting,
National Academy of Sciences of Ukraine)
United Arab Emirates
Beatrix Schmuelling (United Arab
Emirates Ministry of Climate Change
and Environment)
Uruguay
Ministry of Industry, Energy and Mining
Vietnam
Neeraj Joshi (Internationale Projekt
Consult GmbH); Tran Phuong Dong
(Vietnam National University Ho Chi
Minh City, University of Science)
Zimbabwe
Shorai Kavu (Ministry of Energy and
Power Development)
10
A C K N O W L E D G E M E N T S (continued)
LEAD TOPICAL CONTRIBUTORS
BIOENERGY
Cristina Calderon, Martin Colla (Bioenergy
Europe); Bharadwaj Kummamuru (World
Bioenergy Association)
BUILDINGS
Meredith Annex (BloombergNEF);
William Burke (Architecture 2030);
Christina Hageneder (Deutsche
Gesellschaft für Internationale
Zusammenarbeit – GIZ); Femke de Jong
(European Climate Foundation); Adrian
Hiel (Energy Cities); Richard Lowes
(University of Exeter); Vincent Martinez
(Architecture 2030); Mariangiola Fabbri,
Arianna Vitali (Buildings Performance
Institute of Europe – BPIE); Nora
Steurer (Global Alliance for Buildings
and Construction, United Nations
Environment Programme – UNEP);
Louise Sunderland (Regulatory
Assistance Project)
BUSINESS DEMAND FOR
RENEWABLES (FEATURE)
Gabriel de Malleray, Amy Haddon
(Schneider Electric); Tibor Fisher
(German Energy Agency – dena); Rainer
Hinrichs-Rahlwes (European Renewable
Energies Federation); Lucy Hunt (World
Business Council for Sustainable
Development); Yann Kulp (eIQ
Mobility); Christiane Mann; Dave Renne
(International Solar Energy Society);
Stephanie Weckend (IRENA)
DATA
Nazik Elhassan, Adrian Whiteman
(IRENA); Duncan Millard (Consultant)
DISTRIBUTED RENEWABLES
FOR ENERGY ACCESS
Donee Alexander, Colm Fay, Peter
George, Julie Ipe, Kip Patrick, Asna
Towfiq (Clean Cooking Alliance); Fabiani
Appavou (Ministry of Finance and
Economic Development); Benjamin Attia
(WoodMac); Juliette Besnard (ESMAP);
William Brent (Power for All); Kelly
Brinkler; Arthur Contejean (International
Energy Agency – IEA); Harry Clemens
(Hivos); Brian Dean, Ben Hartley, Alvin
Jose, Alice Uwamaliya (Sustainable
Energy for All – SEforALL); Laura
Fortes, Sjef Ketelaars, Susie Wheeldon
(GOGLA); Shaily Jha (Council on Energy,
Environment and Water – CEEW);
Daniel Kitwa (Africa Minigrid Developers
Association – AMDA); Wim Jonker Klunne
(Consultant); Bonsuk Koo (ESMAP);
Arvydas Lebedys, Costanza Strinati and
Adrian Whiteman (IRENA); Yann Tanvez
(International Finance Corporation)
ENERGY EFFICIENCY
Freyr Sverrisson (Advisor; Sunna Research);
Dusan Jakovljevic (Energy Efficiency in
Industrial Processes); Rod Janssen (Energy
in Demand); Benoît Lebot (Ministère de la
Transition Ecologique et Solidaire)
ENERGY SYSTEMS INTEGRATION
Simon Mueller (Energy Transition
Catalytics); Luis Munuera (IEA); Charlie
Smith (Energy Systems Integration
Group); Owen Zinaman (National
Renewable Energy Laboratory)
GEOTHERMAL POWER AND HEAT
Marit Brommer, Margaret Krieger
(International Geothermal Association – IGA)
GLOBAL OVERVIEW
Zuzana Dobrotkova (World Bank); Paolo
Frankl (IEA); Frank Haugwitz (AECEA);
Tomas Kåberger (Renewable Energy
Institute); Ruud Kempener (European
Commission, Renewable Energy Policy
Unit); Paul H. Suding (Indipendent
Consultant); Griffin Thompson
(Georgetown University)
HEAT PUMPS
Meredith Annex (BloombergNEF); Richard
Lowes (University of Exeter); Thomas
Nowak (European Heat Pump Association);
Nancy Wang (Chinaiol); Cooper Zhao
(China Heat Pump Association)
HEATING AND COOLING
Marit Brommer (Advisor; IGA), François
Briens (IEA)
HYDROPOWER
Alex Campbell, Cristina Diez Santos
(International Hydropower Association);
Wim Jonker Klunne (Energy4Africa);
Eva Kremere (United Nations Industrial
Development Organization – UNIDO)
INVESTMENT
Françoise d’Estais, Myriem Touhami
Kadiri, Sophie Loran (UNEP); Lucile
Dufour (Energy Policy Tracker); Malin
Emmerich, Christine Gruening, Ulf
Moslener (Frankfurt School of Finance
and Management); Angus McCrone
(BloombergNEF); Alan Meng (Climate
Bonds Initiative)
OCEAN POWER
Ana Brito e Melo (WavEC Offshore
Renewables); Rémi Collombet, Rémi
Gruet (Ocean Energy Europe)
POLICY
Valerie Bennett, Justin Malecki (Ontario
Energy Board); Emanuele Bianco, Sufyan
Diab (IRENA); Maxine Jordan (IEA); Julia
Levin (Environmental Defence)
SOLAR PHOTOVOLTAICS
Alice Detollenaere (Becquerel Institute);
Denis Lenardič (pvresources); Gaëtan
Masson (Becquerel Institute and
IEA Photovoltaic Power Systems
Programme); Paula Mints (SPV Market
Research); Dave Renne (International
Solar Energy Society); Michael Schmela
(SolarPower Europe)
SOLAR THERMAL HEATING
AND COOLING
Hongzhi Cheng (Sun’s Vision); Pedro
Dias (Solar Heat Europe); Monika Spörk-
Dür (AEE – Institute for Sustainable
Technologies); He Tao, Ruicheng Zheng
(China Academy of Building Research)
TRANSPORT
Flávia Guerra (REN21); Nikola
Medimorec, Karl Peet (SLOCAT
Partnership on Sustainable, Low Carbon
Transport); Patrick Oliva (Paris Process
on Mobility and Climate); Marion Vieweg
(Current Future)
WIND POWER
Stefan Gsänger, Jean-Daniel Pitteloud
(World Wind Energy Association); Ivan
Komusanac (WindEurope); Feng Zhao
(Global Wind Energy Council); American
Clean Power Association
11
RENEWABLES 2021 GLOBAL STATUS REPORT
PEER RE VIEWERS AND OTHER CONTRIBUTORS
Mussa Abbasi Mussa (Ministry of Energy,
Tanzania); Hagar AbdelNabi (Nexus
Analytica LLC); Adedoyin Adeleke
(International Support Network for African
Development); Disha Agarwal (Council
on Energy, Environment and Water); Iqbal
Akbar (Technical University of Berlin);
Udochukwu B. Akuru (Tshwane University
of Technology, South Africa &
University of Nigeria, Nsukka); Mohammad
Albtowsh; Noor Eldin Alkiswani (EDAMA);
Nevin Alija (NOVA Law Green Lab, NOVA
School of Law); Reem Almasri (EDAMA);
Farrah Ali-Khan (Ontario Ministry of
Environment, Conservation and Parks);
Mohammad Alnajideen (Cardiff School of
Engineering); Eros Artuso (Terra Consult
Sàrl); Diana Athamneh (EDAMA); Patrick
Atouda Beyala (SOAS University of
London); Shakila Aziz (United International
University); Sarah Baird (Let There Be Light
International); Stefan Bakker (Consultant);
Krishnan Balasankari (Renewable Cogen
Asia); Jessica Battle (World Wildlife Fund);
Matthieu Ballu (European Commission);
Alex Beckitt (Hydro Tasmania); Nikolay
Belyakov (Independent consultant);
Tabitha Benney (University of Utah);
Markus Bissel (GIZ); Linh H. Blanning
(Voltalia); Rina Bohle Zeller (Vestas);
Adriano Bonotto (Divisão de Promoção de
Energia, Itamaraty); Emilio Bravo (Mexico
Low Emission Development Program, US
Agency for International Development);
Jesse Broehl (ACPA); Emmanuel Branche
(EDF); Roman Buss (Renewables
Academy AG); Rebecca Camilleri (Energy
& Water Agency, Malta); Valeria Cantello
(Energrid); Tamojit Chatterjee (SEforALL);
Joan Chahenza (AMDA); Sandra Chavez
(Powerhouse); Mwewa Chikonkolo Mwape
(ZESCO Limited); Jan Clyncke (PV Cycle);
Olivia Coldrey (SEforALL); Penelope
Crossley (The University of Sydney); Edgar
Hernan Cruz Martinez (Climate finance
consultant); Tabaré A. Currás (World
Wildlife Fund); David Jonathan D’Souza
(IMDEA Energy Institute); Pablo del Río
(Spanish National Research Council –
CSIC); Irene Di Padua (Solar Heat Europe
and European Solar Thermal Industry
Federation); Antonello Di Pardo (Gestore
dei Servizi Energetici); Renato Domith
Godinho (German Federal Ministry for
Economic Cooperation and Development
– BMZ); Christine Eibs Singer (SEforALL);
Mariam El Forgani (Libyan Ministry
of Electricity and Renewable Energy);
Khalil Elahee (University of Mauritius);
Myagmardorj Enhkmend (Mongolian Wind
Energy Association); Yasemin Erboy Ruff
(CLASP); Jose Etcheverry (York University);
Ashkan Etemad (LEEDinIran); Colm
Fay (Clean Cooking Alliance); Ezequiel
Ferrer (SolarPACES); Robert Fischer
(Luleå University of Technology); Jason
Fisher (Isleofrocks); Mindy Fox (Solar
Cookers International); Anna Freeman
(Clean Energy Council); Sabine Fröning
(Communication Works); Therese Galea
(Energy & Water Agency, Malta); Thomas
Garabetian (European Geothermal Energy
Council); Shirish Garud (TERI); Christoph
Graecen (ESMAP); Thakshila Gunaratna
(Clean Energy Council); Qin Haiyan
(Chinese Wind Energy Association); Kirsty
Hamilton (Chatham House); Gang He
(Department of Technology and Society,
Stony Brook University); Sebastian
Hermann (Germany Environment Agency);
Miguel Herrero Cangas (SolarPower
Europe); Pippa Howard (FFI); Lizzy lgbine
(Nigerian Women Agro Allied Farmers
Association); Tetsunari Iida (Institute for
Sustainable Energy Policies); Arnulf Jaeger-
Waldau (European Commission, Joint
Research Centre); Rob de Jong (UNEP);
Mohamed Atef Kamel (Freelance energy
consultant); Phubalan R. Karunakaran
(WWF-Malaysia); Hwajin Kim (United
Nations Institute for Training and Research);
Bozhil Kondev (Consultant); Manoj
Kumar Singh (ISOBARS Energy); Mercè
Labordena (SolarPower Europe); Oliver
Lah (Wuppertal Institute for Climate,
Environment and Energy); Maryse Labriet
(ENERIS); Debora Ley (Latinoamérica
Renovable); Holger Loew (Renewables
Grid Initiative); Luca Longo (UNIDO);
Juergen Lorenz (jlbtc, ENPOWER); Detlef
Loy (Loy Energy Consulting); Joshua
Loughman (Arizona State University);
Juan Roberto Lozano (Emerging Leaders
in Environmental and Energy Policy
Network); Fabio Lucantonio (independent
consultant); Marissa Malahayati (National
Instititute for Environmental Studies);
Anik Masfiqur Rahman (Ontario Power
Generation); Rihardian Maulana Wicaksono
(Institut Teknologi Sumatera); Lionel
Mbanda (North China Electric Power
University); Emi Mizuno (SEforALL);
Saurabh Motiwala (Akshat Jyoti Solutions);
Divyam Nagpal (University College
London); Zaibul Nisa (Planetive); Laura
Maria Noriega Gamarra (ICLEI–Local
Governments for Sustainability); Jesse
Nyokabi (Green Energy); Dania Carolina
Ortiz Acosta (MIT-Portugal Program); Brian
Park (Inuvialuit Regional Corporation);
Tomasz Pawelec (UNIDO); Jem Porcaro
(SEforALL); Elisa Portale (ESMAP);
Magdolna Prantner (Wuppertal Institute
for Climate, Environment and Energy);
Pallav Purohit (International Institute for
Applied Systems Analysis); Muhammad Ali
Qureshi (UNIDO); Daya Ram Nhuchhen
(Transition Accelerator); Oliver Rapf
(Buildings Performance Institute Europe);
Atul Raturi (University of the South Pacific);
Roelof Reineman (Roelof Reineman);
Niels Reise (Communication Works);
Maria Riabova (Moscow State Institute of
International Relations, MGIMO University);
Christoph Richter (Deutsches Zentrum für
Luft- und Raumfahrt e.V. – DLR); Eleazar
Rivera (Ashrae Mexico); Vera Rodenhoff
(German Ministry of the Environment);
Javier Eduardo Rodriguez (Colibri Energy
SAS); Judit Rodriguez Manotas (UNIDO);
Ingrid Rohrer (SEforALL); Ahmed
Rontas (Raguinot); Heather Rosmarin
(InterAmerican Clean Energy Institute);
Raffaele Rossi (SolarPower Europe);
Clotilde Rossi di Schio (SEforALL); Philip
Russell (Mexico Energy News); Felipe
Sabadini (RWTH Aachen University);
Olga Savchuck (IN Center for Innovation,
Technology and Policy Research); Miguel
Schloss (Surinvest Ltd.); Nicole Schrön
(German Federal Ministry for Economic
Affairs and Energy); Cecile Seguineaud
(Independant energy consultant); Luc
Severi (SEforALL); Fares Shmayssani
(Lebanese University); Ralph Sims
(Massey University); Karla Solis (Regional
Collaboration Centre of Latin America,
United Nations Framework Convention
on Climate Change); Rafel Soria Penafiel
(Universidad San Francisco de Quito,
Ecuador); Laiz Souto (University of
Girona); Satrio Swandiko; Yael Taranto
(SHURA Energy Transition Center);
Tanguy Tomes (Palladium); Dong Tran
(Department of Environment, University
of Natural Sciences, National University
of Ho Chi Minh City); Hoa Tran (GIZ);
Patricia Villarroel Sáez (Court of Appeal
of Valparaíso, Chile); Prof. Dr. Tanay Sidki
Uyar (Marmara Universitesi); Xinfang Wang
(University of Birmingham); Peter Yang
(Case Western Reserve University); Prof.
Noureddine Yassaa (Algerian Commission
for Renewable Energy and Energy
Efficiency); Arthouros Zervos (National
Technical University of Athens); Zedong
Zhang; Eduarda Zoghbi (SEforALL).
12
A C K N O W L E D G E M E N T S (continued)
F O R E W O R D
2020 was a year of disruption. The pandemic had a tragic impact on our communities but our health benefited from the
extreme drop in fossil fuel use. It was also a year of new norms in the renewable energy sector. Ambition increased at
an accelerated pace with a dramatic expansion of net zero emission targets. Increasing pressure from citizens and civil
society led courts to force countries to strengthen their own climate plans, while the private sector purchased record
amounts of renewable energy.
However, the past teaches us that ambition is not enough. It must be translated into action. While this year’s Renewables
2021 Global Status Report (GSR) shows continuing progress in the power sector, the share of renewables in heating and
transport has barely changed from past levels. Despite all the rhetoric, we are nowhere near the necessary paradigm shift
towards a clean, healthier and more equitable energy future.
Clearly, we need a structural shift. It’s not just about deploying and installing renewables. It’s also about conserving
energy, integrating energy efficiency AND leaving fossil fuels in the ground. It’s time to stop talking only about gigawatts of
installed capacity. We must emphasise how renewables can support development, economic development and a cleaner,
healthier environment. If we are to achieve the energy transition, we need to integrate renewables across all economic
sectors.
This year’s report shows that governments need to act more aggressively and press forward with renewables in all
sectors. The window of opportunity is closing and efforts must be ramped up significantly. This will not be easy. The share
of fossil fuels in overall final energy demand is as high as it was a decade ago. While renewables grew almost 5% per year
from 2009 to 2019, fossil fuel shares remained at around 80% over the same period. And with fossil fuel subsidies in 2019
totalling USD 550 billion – almost double the total investment in renewables – the last 10 years of climate policy promises
have shown themselves to be mostly empty words.
One way to accelerate development is to define the uptake of renewable energy as a key performance indicator (KPI).
To borrow a business adage, “What gets measured gets done.” By measuring our performance, we can close the gap
between ambition and target. And how better to measure our progress towards a clean energy transition? We must use
the share of renewable energy in final energy consumption as a KPI and link it to every economic activity, every budget,
every single purchase. This may sound overly ambitious, but we need urgent action. We cannot afford to make any more
commitments that do not produce action. This needs to happen now.
I hope that the pages of this report contain the data and information you need to continue your work in making renewable
energy the new norm. I would like to thank all those who have contributed to this year’s edition. Particular thanks go to
the Research Direction Team of Hannah E. Murdock, Duncan Gibb and Thomas André; Special Advisors Janet L. Sawin,
Adam Brown and Lea Ranalder; the many authors; our editors, Lisa Mastny and Leah Brumer; our designers, Caren
Weeks, Nicole Winter and Sebastian Ross; and all those who provided data and participated in the peer review process.
Once again, this report illustrates the power of a collective process.
Rana Adib
Executive Director, REN21
June 2021
13
Cascades Inc. diverts three-quarters of the residual materials from its plants away from landfills, using them in
biomass boilers or to fertilise farmland, and has committed to achieving 100% renewable electricity by 2030.
ES
E X ECU T I V E
SUMM A R Y
01 GLOBAL OVERVIEW
Despite the impacts of the COVID-19 pandemic, renewable
energy set a record in new power capacity in 2020 and was the
only source of electricity generation to register a net increase
in total capacity. Investment in renewable power capacity rose,
although slightly, for the third consecutive year, and corporations
continued to break records for sourcing renewable electricity.
More countries shifted towards renewables for the electrification
of heat. Although production of transport biofuels declined,
electric vehicle (EV) sales expanded, as did the linking of EVs and
renewable power, although to a lesser extent. China was among
the countries that strengthened their commitments to action on
the climate crisis, setting a carbon-neutral target. The United
States re-joined the Paris Agreement in early 2021.
Meanwhile, previous obstacles to progress in the renewable
energy sector persisted during 2020. They include the slow
increase in the share of renewables in total final energy
consumption (TFEC), inadequate innovation in some sectors, the
need for infrastructure development, the lack of affordability in
some markets, the absence of sufficient policy and enforcement,
and ongoing support for fossil fuels.
For the first time, the number of countries with renewable energy
support policies did not increase from the previous year. Despite
greater interest in net zero targets during 2020, these targets
do not necessarily cover all greenhouse gases or sectors, nor
do they necessarily lead to increased attention to renewables
or to success in meeting renewable energy targets. While such
targets are in place in nearly all countries, many countries were
not on track to achieve their 2020 targets in multiple sectors, and
many had not yet set new targets as their 2020 targets expired.
In addition, investments in fossil fuels outlined in COVID-19
recovery packages worldwide were six times greater than the
level of investments allocated to renewable energy.
As in past years, the highest share of renewable energy use was
in the electricity sector (26% renewables); however, electrical end-
uses accounted for only 17% of total final energy consumption. The
transport sector, meanwhile, accounted for an estimated 32% of
TFEC and had the lowest share of renewables (3.3%). The remaining
thermal energy uses, which include space and water heating, space
cooling, and industrial process heat, represented more than half
(51%) of TFEC; of this, renewables supplied some 11%.
As of 2019, modern renewable energy (excluding the traditional
use of biomass) accounted for an estimated 11.2% of TFEC, up
from 8.7% a decade earlier. Despite tremendous growth in some
renewable energy sectors, the share of renewables has increased
only moderately each year. This is due to rising global energy
demand, continuing consumption of and investment in new fossil
fuels, and declining traditional use of biomass (which has led to a
shift towards fossil fuels).
This slow progress points to the complementary and fundamental
roles of energy conservation, energy efficiency and renewables in
reducing the contribution of fossil fuels to meeting global energy
needs and reducing emissions. With the concentration of carbon
dioxide (CO2) in the atmosphere still rising to record levels even
as emissions have fallen, it has become increasingly clear that a
structural shift is needed to reach long-term climate targets.
15
RENEWABLES 2021 GLOBAL STATUS REPORT
BUILDINGS
Renewable energy meets a growing portion of final
energy demand in buildings, although its share is still
less than 15%.
Renewables remained the fastest growing source of energy in
buildings, increasing 4.1% annually on average between 2009 and
2019. The highest growth was in electricity use, whereas heating
with renewable energy rose more slowly. Modern bioenergy
(such as the use of wood-based fuel in efficient stoves) still
represented the largest source of renewables in the buildings
sector, especially in providing heat, although its growth has
been roughly stagnant..
The use of renewable electricity for heat (for example, through
electric heat pumps) provided the second largest renewable
energy contribution to heat demand and showed the greatest
growth in recent years. Solar thermal heat, geothermal heat and
district energy networks also have grown quickly, albeit starting
from a smaller base. Policies to stimulate renewable energy
uptake in buildings remain relatively scarce, although many
options exist to improve efficiency in new and existing buildings,
expand access to electricity and clean cooking, and encourage
the use of renewables.
INDUSTRY
The share of renewables in industrial energy demand
remains small, particularly in sectors that require high
temperatures for processing.
Renewable energy accounts for only around 14.8% of total
industrial energy demand and is used mainly in industries with low-
temperature requirements for process heat. In heavy industries
– iron and steel, cement, and chemicals – renewables accounted
for less than 1% of the combined energy demand in 2018.
Bioenergy (mainly biomass) supplies around 90% of renewable
heat in the industrial sector, primarily in industries where biomass
waste and residues are produced on-site. Renewable electricity
accounts for the second largest share (10%) of renewable
industrial heat, although it represented only 1% of total industrial
heat consumption in 2019. Solar thermal and geothermal
technologies accounted for less than 0.05% of total final industrial
energy use in 2018.
The COVID-19 pandemic temporarily reduced industrial
energy demand, with global bioenergy use in industry falling
4% in 2020. Measures to promote the uptake of renewables
in industries received limited attention in COVID-19 stimulus
packages, although some countries announced renewable
hydrogen strategies or investment plans to support industrial
decarbonisation. By the end of 2020, only 32 countries had at
least one renewable heating and cooling policy for industry (all of
them economic incentives, such as subsidies, grants, tax credits
or loan schemes).
Despite tremendous
growth in some renewable
energy sectors, the share
of renewables has
increased only
moderately
each year.
16
TRANSPORT
After falling initially, transport energy demand rebounded
by the end of the year. Trends show rising demand and a
stagnant share of renewable energy.
The COVID-19 pandemic had significant impacts on the
transport sector and its use of renewable energy. Transport
activity and energy demand fell sharply in the early months of
2020 but rebounded by year’s end. Longer-term trends have
shown that growth in energy demand for transport has far
outpaced that for other sectors.
Transport remains the sector with the lowest share of
renewables, as oil and petroleum products (and 0.8% non-
renewable electricity) continue to meet nearly all global
transport energy needs (95.8%). Biofuels and renewable
electricity met small shares of those needs (3.1% and 0.3%,
respectively). Following a decade of steady growth, biofuel
production decreased in 2020 due to the overall decline in
transport energy demand, while electric car sales increased
41% during the year. The use of or investment in renewable
hydrogen and synthetic fuels for transport increased in some
regions but remained relatively minimal.
Overall, the transport sector is not on track to meet global
climate targets. Many countries still lack a holistic strategy
for decarbonising transport. Such a strategy could greatly
decrease energy demand in the sector and thus allow for the
renewable share in transport to increase.
POWER
Driven by solar photovoltaic (PV) and wind power, the
renewable power sector surged in the second half of 2020
to overcome the pandemic’s impacts.
Installed renewable power capacity grew by more than
256 gigawatts (GW) during the pandemic, the largest ever
increase. Continuing a trend dating back to 2012, net additions
of renewable power generation capacity outpaced net
installations of both fossil fuel and nuclear power capacity
combined. China again led the world in renewable capacity
added, accounting for nearly half of all installations in 2020
and leading the global markets for concentrating solar thermal
power (CSP), hydropower, solar PV and wind power.
China added nearly 117 GW, bringing online more renewable
capacity in 2020 than the entire world did in 2013 and almost
doubling its additions from 2019. By the end of 2020, at least
19 countries had more than 10 GW of non-hydropower
renewable capacity, up from 5 countries in 2010. Renewable
energy reached a record share – an estimated 29% – of the
global electricity mix. Despite these advances, renewable
electricity continued to face challenges in achieving a larger
share of global electricity generation, due in part to persistent
investment in fossil fuel (and nuclear) power capacity.
China
added nearly 117 GW of
renewable power, bringing
online more capacity in
2020 than the entire world
did in 2013.
17
02 POLICY LANDSCAPE
Despite the COVID-19 crisis, policy support for renewables
generally remained strong throughout 2020.
By the end of 2020, nearly all countries had in place renewable
energy support policies, although with varying degrees of ambition.
Corporate commitments to renewable energy also increased
during the year, led by market-based drivers such as action on
climate change and the declining costs of renewable electricity.
While the suite of renewable energy policies implemented during
the year was affected in part by the COVID-19 pandemic, it also
evolved in response to increased action on climate change, falling
costs of renewables, evolving network and system integration
demands, and the changing needs and realities of different
jurisdictions.
RENEWABLE ENERGY AND
CLIMATE CHANGE POLICY
2020 was an important year for climate change policy
commitments.
Although the COVID-19 crisis was the central political focus of
the year, commitments to climate change mitigation stood out.
Overall, 2020 was an important milestone for climate change
policy, as many countries’ greenhouse gas targets for the year
expired. Countries set new targets, and many committed to
carbon neutrality.
While some jurisdictions enacted climate change policies that
indirectly stimulate the uptake of renewable energy, a growing
number adopted comprehensive policies directly linking
decarbonisation with increased deployment of renewables.
Policy mechanisms implemented in 2020 that can indirectly
stimulate interest in renewable energy included fossil fuel bans
and phase-outs, greenhouse gas emission reduction targets, and
carbon pricing and emission trading systems. In addition, at least
six regional, national and state/provincial governments adopted
comprehensive, cross-sectoral climate policies that include direct
support for renewables.
HEATING AND COOLING IN BUILDINGS
Despite the enormous potential for renewable energy in
heating and cooling, policy developments in heating and
cooling for buildings in 2020 remained limited, outstripped
by policies aimed at electricity generation and transport.
Financial incentives were the most common mechanism used to
encourage renewable heating and cooling in buildings in 2020. All
such policies enacted or revised during the year were in Europe.
Evidence also points to growing interest in electrification of heating
and cooling, which can increase the penetration of renewables
in the buildings sector if the electricity used is generated from
renewable sources. In 2020, policy makers in a number of
national and sub-national jurisdictions focused rising attention
on policies targeting building heating and cooling electrification.
Energy efficiency policies also received international attention.
INDUSTRY
Policy developments related to increasing the share of
renewables in industry remained scarce in 2020, compared
with policies directed at all other end-use sectors.
Although renewable energy solutions for industrial uses are
available, they are not yet competitive with fossil fuels, and
policy support remains critical for increasing renewables in this
sector. However, such support remained rare in 2020. By year’s
end, only 32 countries had some form of renewable heating and
cooling policy for industry (no change from 2019), with financial
incentives being the most common form of policy support.
18
TRANSPORT
Decision makers are focusing increasingly on expanding
the use of renewables in the transport sector, with an
emphasis on transport electrification.
Although biofuels continue to be a central component of road
transport policy frameworks, the electrification of transport
received much of the attention in 2020. Policies aimed at transport
electrification are not renewable energy policies in and of
themselves, but they offer the potential for greater penetration of
renewable electricity in the sector, to the extent that the electricity
used for charging vehicles is generated from renewable sources.
As in past years, policy makers focused most of their attention on
road transport. EV policies became increasingly popular in 2020,
although the vast majority of these continued to lack a direct
link to renewable electricity generation. However, the number of
countries with EV policies that do have a direct link to renewables
increased from two to three during the year.
Rail, aviation and shipping still receive much less policy attention
than road transport, even though they are the fastest growing
transport sub-sectors and account for a rising share of total final
energy use in transport.
POWER
As in previous years, the power (electricity generation)
sector continued to receive significant renewable energy
policy attention in 2020.
The power sector continued to receive the bulk of renewable
energy policy attention in 2020, as in previous years. Targets
were the most popular form of intervention: by the end of 2020,
137 countries had some form of renewable electricity target,
compared with 166 in 2019.
Although feed-in policies remain a widely used policy mechanism
for supporting renewable power, in 2020 the shift continued from
feed-in policies (set administratively) to competitive remuneration
through tenders and auctions. Despite the continued popularity
of net metering policies, some jurisdictions began transitioning
away from net metering or modified their programmes to charge
customers fees for participating.
Financial incentives, while always an important policy tool, were
especially important for the power sector in 2020 as a result of
the COVID-19 pandemic.
SYSTEMS INTEGRATION OF VARIABLE
RENEWABLE ELECTRICIT Y (VRE)
Many jurisdictions with relatively high shares of renewables
are implementing policies designed to ensure the successful
integration of VRE into the broader energy system.
The policy push for systems integration of renewables and
enabling technologies, such as energy storage, focuses
primarily on increasing power system flexibility and control, as
well as grid resilience. Policies to advance the integration of VRE
focused on market design, improving electricity transmission
and distribution system infrastructure, and supporting the
deployment of energy storage.
EV policies
became increasingly
popular in 2020, although
the vast majority of
these continued to lack a
direct link to renewable
electricity generation.
19
RENEWABLES 2021 GLOBAL STATUS REPORT
03 MARKET AND INDUSTRY TRENDS
BIOENERGY
Modern bioenergy provided 5.1% of total global final energy
demand in 2019, accounting for around half of all renewable
energy in final energy consumption.
Modern bioenergy provided 9.5% of the heat required in industry
and agriculture in 2019, an increase of around 16% since 2009.
Bioenergy also provided 5% of the heat needed for buildings,
with this use up 7% over the decade.
Biofuels – mostly ethanol and biodiesel – provide around 3%
of transport energy. In 2020, global biofuel production fell
5% due to the impacts of the COVID-19 pandemic on overall
transport energy demand. Ethanol production declined around
8%, with an 11% drop in production in the United States, the
major producer. Global biodiesel production increased slightly
to meet higher blending levels in Indonesia (the world’s largest
biodiesel producer) and in Brazil, as well as higher demand in
the United States.
In the electricity sector, bioenergy’s contribution rose 6% in
2020, reaching 602 terawatt-hours (TWh). China remained
the largest generator of bio-electricity, followed by the United
States and Brazil.
The most notable industry trend was rising investment in
hydrotreated vegetable oil (HVO), with a 12% increase in
production in 2020. Plans were announced for many additional
plants, which could more than quadruple current capacity. HVO
production would then exceed that of FAME (fatty acid methyl
ester) biodiesel.
GEOTHERMAL POWER AND HEAT
Geothermal electricity generation totalled around 97 TWh in
2020, while direct use of geothermal heat reached about 128
TWh (462 petajoules).
An estimated 0.1 GW of new geothermal power generating capacity
came online in 2020, bringing the global total to around 14.1 GW. The
year saw relatively little growth in capacity compared to recent years
(attributed in part to pandemic-related disruption), with almost all
new facilities located in Turkey. The United States and Japan added
minor amounts of geothermal power capacity in 2020.
Direct use of geothermal energy for thermal (heat) applications is
highly concentrated geographically, with only four countries – China,
Turkey, Iceland and Japan – accounting for three-quarters of the
energy consumed. Direct use has grown at an average rate of nearly
8% in recent years, with space heating being the primary driver.
Some of the most active markets lack access to high-temperature
resources and often face higher costs and greater technical
challenges to accessing geothermal heat. Countries with noteworthy
activity in 2020 included France, Germany and the Netherlands.
The geothermal industry was characterised by project delays and
by meagre and highly concentrated market growth. The main
focus continued to be on technological innovation, such as new
resource recovery techniques and seismic risk mitigation, with the
aim of improving the economics, lowering the development risk
and strengthening prospects for expanded resource development.
However, as in past years, the hopes of expanding geothermal
development beyond the relatively few and concentrated centres of
existing activity remained largely unmet. High costs and project risks
have continued to deter investment in most places, especially in the
absence of government support (such as feed-in tariffs and risk
mitigation funds), although certain pockets of innovation attracted
new investment from established entities in the energy industry.
In 2020,
global biofuel
production
fell 5% due to the impacts
of the COVID-19 pandemic
on overall transport energy
demand.
20
HYDROPOWER
The global hydropower market grew in 2020, but China was
responsible for more than half of capacity additions.
Despite a 24% increase in capacity additions, driven mainly by
China, the global hydropower market did not recover in 2020
after several years of deceleration. The effects of the COVID-19
pandemic were notable, with the market slowing as construction
was halted temporarily, component supply chains were disrupted,
and energy demand fell. New capacity was an estimated 19.4 GW,
raising the total global installed capacity to around 1,170 GW.
Global hydropower generation increased 1.5% in 2020 to reach
an estimated 4,370 TWh, representing around 16.8% of the
world’s total electricity generation.
China added 12.6 GW of hydropower capacity in 2020, its largest
addition of the previous five years, and regained the lead from
Brazil in commissioning new hydropower capacity, followed by
Turkey, India and Angola. Pumped storage capacity increased
slightly (up 1.5 GW, or 0.9%), with projects in China and Israel,
bringing total capacity to 160 GW. Several large pumped storage
projects were in the pipeline, including in Australia, Greece,
India, Portugal, Scotland and Turkey, in part to support growth
in solar PV and wind power.
The hydropower industry continued to face challenges as well
as opportunities, with both of these affected by the pandemic-
induced recession. Challenges included operational and technical
factors, environmental and social acceptability, a global decline
in wholesale electricity prices, and adverse climate impacts on
hydropower production and infrastructure. Opportunities for
industry expansion included technology improvements and
increased performance, the remaining untapped potential of
smaller resources, synergies with VRE, and increased needs for
grid flexibility.
OCEAN POWER
Ocean power represented the smallest portion of the
renewable energy market, yet new targets for ocean power
capacity were set during the year.
Ocean power represents the smallest portion of the renewable
energy market, with most projects focused on relatively
small-scale demonstration and pilot projects of less than
1 megawatt (MW). Net additions in 2020 totalled around 2 MW,
with an estimated 527 MW of operating capacity at year’s end.
Ocean power technologies are steadily advancing towards
commercialisation, and tidal turbines continued to demonstrate
their reliability. However, consistent policy and revenue support
remain critical.
Development activity is concentrated primarily in Europe, and
particularly off the coast of Scotland, but has increased steadily
in China, the United States and Canada. The resource potential
of ocean energy is enormous, but it remains largely untapped
despite decades of development efforts.
The ocean power industry experienced delays of planned
deployments due to COVID-19, and developers redirected
their focus to device and project development. Operational
tidal turbines continued to generate power reliably and to
move towards commercialisation. Across the sector, financial
and other support from governments, particularly in Europe
and North America, continued to boost private investments in
ocean power technologies, especially tidal stream and wave
power devices.
21
RENEWABLES 2021 GLOBAL STATUS REPORT
SOL AR PHOTOVOLTAICS (PV)
Solar PV had another record-breaking year, adding as much
as an estimated 139 GW, for an estimated total of 760 GW.
Pending policy changes drove much of the growth in the top
three markets – China, the United States and Vietnam – but
several other countries saw noteworthy expansion.
Favourable economics have boosted interest in distributed
rooftop solar PV systems. In 2020, growth in this market share
was due mainly to a rush of installations in Vietnam in advance
of the expiry of the country’s feed-in tariff; however, Australia,
Germany and the United States also saw significant increases
as homeowners invested in home improvements during the
pandemic.
South Australia achieved one of the world’s highest levels
of solar penetration in 2020. The state’s power system has
become the world’s first large-scale system to approach the
point at which rooftop solar PV effectively eliminates demand
for electricity from the grid.
The solar PV industry rode a roller coaster in 2020, driven largely
by pandemic-related disruptions, as well as by accidents at
polysilicon facilities in China and a shortage of solar glass. These
disruptions, due in large part to heavy reliance on China as the
world’s dominant producer, combined with concerns about
possible forced labour in polysilicon production, led to calls in
many countries for the creation of local supply chains.
Despite the multiple challenges, new actors entered the sector.
Competition and price pressures continued to motivate investment
to improve efficiencies, reduce costs and improve margins.
The solar PV industry has become the major driver of growth in
polysilicon production and accounts for a rising share of demand
for other resources and materials, such as glass and silver. In
most countries, recycling panels at the end of their useful life –
as a means to reclaim these resources and minimise associated
environmental impacts – is only starting to gain attention.
CONCENTRATING SOL AR THERMAL
POWER (CSP)
Despite declining costs, CSP capacity grew in only one
country during 2020.
Global CSP capacity grew a mere 1.6% in 2020 to 6.2 GW, with a
single 100 MW parabolic trough project coming online in China.
This was the lowest annual market growth in over a decade, the
result of increasing cost competition from solar PV, the expiry of
CSP incentive programmes and a range of operational issues at
existing facilities.
More than 1 GW of CSP projects was under construction in the
United Arab Emirates, China, Chile and India during the year. The
majority of this capacity is based on parabolic trough technology
and is being built in parallel with thermal energy storage (TES).
At year’s end, an estimated 21 gigawatt-hours of thermal energy
storage was operating in conjunction with CSP plants across five
continents. Global TES capacity, installed mainly alongside CSP,
is almost double that of utility-scale battery storage.
During the 2010s, CSP costs fell nearly 50%, the largest decline
for all renewable energy technologies, with the exception of solar
PV. In many cases, CSP plants are being retrofitted with TES or
co-located with solar PV capacity to lower costs and increase
capacity values.
Solar PV
had another
record year,
while only a single
CSP project came
online in 2020.
22
SOL AR THERMAL HEATING
An estimated 25.2 gigawatts-thermal (GWth) of new solar
thermal capacity was added in 2020, increasing the global
total 5% to around 501 GWth.
China again led in new solar thermal installations, followed by
Turkey, India, Brazil and the United States. Most large solar
thermal markets were constrained by COVID-19-related
challenges, and in some cases commercial clients postponed
investment decisions. However, the reduction was smaller than
expected due to stabilising factors such as ongoing business
in the construction sector and higher demand from residential
owners, many of whom spent more time at home and invested in
infrastructure improvements.
The year was bright for solar district heating in China and
Germany, thanks to policy support for green heating technologies.
The global solar district heating market also diversified into
new markets in Europe (Croatia, Kosovo and Serbia) and Asia
(Mongolia). In addition, central solar hot water systems for large
residential and commercial buildings sold well in China, Brazil
and Turkey. By year’s end, at least 471 solar district heating or
central hot water systems (at least 350 kilowatts-thermal) were
operating worldwide, totalling 1.8 GWth of capacity.
Hybrid, or solar PV-thermal (PV-T), collectors became more
popular in several countries. In total, 36 manufacturers
worldwide reported PV-T capacity of at least 60.5 megawatts-
thermal (MWth) (connected to 24 MW-electric), up sharply from
46.6 MWth in 2019.
More collector manufacturers and project developers began
offering solar industrial heat (SHIP) solutions to factories
worldwide. At least 74 SHIP systems, totalling 92 MWth, started
operation globally in 2020, raising the number of facilities
in operation 9% to around 891 SHIP plants. Although many
technology suppliers reported delays in installation and
construction, some megawatt-scale plants were successfully
commissioned during the year, including Europe’s largest
(10.5 MWth), used to heat agricultural greenhouses.
WIND POWER
The wind power market achieved a record-breaking 93 GW
of new installations, bringing total capacity onshore and
offshore to nearly 743 GW.
China and the United States led the growth in wind power with
record years, driven by pending policy changes at the end of
2020 in both countries. Several other countries also reached
installation records, while the rest of the world installed about
the same amount as in 2019. Wind power accounted for a
substantial share of electricity generation in several countries in
2020, including Denmark (over 58%), Uruguay (40.4%), Ireland
(38%) and the United Kingdom (24.2%).
Nearly 6.1 GW of capacity was connected offshore for a global
total of 35.3 GW. Interest in offshore wind power is increasing –
including among corporations looking to sign power purchase
agreements (PPAs) – due to the large scale of generation, high
capacity factors, fairly uniform generation profiles and falling costs.
The wind industry continued to face perennial challenges
that were exacerbated by the pandemic. Despite selling more
turbines, even top manufacturers suffered losses for the year,
closed factories and laid off workers as the highly competitive
market, together with pandemic-related costs and delays,
squeezed profit margins further.
In some markets, governments responded by extending policy
deadlines, and new policy commitments helped stimulate record
investments. For the first time, global capital expenditures
committed to offshore wind power during the year surpassed
investments in offshore oil and gas.
To diversify in key markets, turbine manufacturers and project
developers continued expanding into new sectors, even as new
actors – including oil majors – moved further into the wind
sector. Manufacturers focused on technology innovation to
continuously reduce costs and achieve an ever lower levelised
cost of energy. In addition, they expanded their work with other
researchers to increase wind turbine sustainability during
production and at the end of useful life.
23
RENEWABLES 2021 GLOBAL STATUS REPORT
04 DISTRIBUTED RENEWABLES
FOR ENERGY ACCESS (DREA)
Distributed renewables have continued to enable energy
access, reaching electricity generation shares as high as
10% in some countries.
By the end of 2019, 90% of the global population had gained
access to electricity, although one-third (2.6 billion people) still
lack access to clean cooking, relying on mostly traditional use
of biomass. Renewables-based electric power systems and
clean cooking solutions have played an increasingly important
role in improving energy access rates, especially in rural and
remote areas where such access remains low. Stand-alone solar
systems and renewables-based mini-grids are often the most
cost-effective way of electrifying off-grid areas in the developing
world, providing power for households and productive uses.
Options that help reduce the health and environmental impacts
of the traditional use of biomass include improved biomass
stoves and fuels, biogas, ethanol, solar cookers and, increasingly,
renewables-based electric cooking.
After several years of strong growth, the market for renewables-
based energy access systems was negatively impacted by the
COVID-19 pandemic. Global sales of off-grid solar systems fell
22% in 2020, with the greatest regional decline in South Asia
(51%), while sales in East Africa, the largest market, dipped 10%.
Despite the drop in sales, financing for off-grid solar companies
increased slightly by 1%. While equity funding fell significantly,
debt and grant funding increased.
Although many planned renewables-based mini-grid projects
were delayed due to the pandemic, new solar mini-grids
were commissioned in several countries specifically to power
healthcare facilities as an emergency response to the crisis. By
late 2020, new financing deals were signed for several larger
mini-grid developments across Africa.
The clean cooking sector has seen less funding and private
sector involvement than the electricity access sector. However,
funding for the 25 largest clean cooking companies increased
68% in 2019, to USD 70 million. In 2020, several new large-scale
funding initiatives were announced for clean cooking in Africa,
where the clean cooking deficit remains the largest. Policy
makers in several countries also have focused on clean cooking,
setting new targets and developing financial support packages.
05 INVESTMENT FLOWS
Global investment in renewable energy capacity increased
2% in 2020, resisting the COVID-19-induced economic
crisis.
Global new investment in renewable power and fuels (not
including hydropower projects larger than 50 MW) totalled
USD 303.5 billion in 2020. Developing and emerging economies
surpassed developed countries in renewable energy capacity
investment for the sixth year running, reaching USD 153.4 billion
(a smaller margin than in previous years). Investments for the year
rose 13% in developed countries and fell 7% in developing and
emerging countries.
Investment in renewables continued to focus on wind and solar
power, with solar representing nearly half of global renewable
energy investment in 2020, at USD 148.6 billion (up 12%).
Investments fell in all renewable technologies except solar power,
with wind power falling 6% to USD 142.7 billion (47% of the total).
The remaining technologies continued their downward trend,
with investment in small hydropower falling to USD 0.9 billion,
geothermal to USD 0.7 billion and biofuels to USD 0.6 billion.
COVID-19 economic recovery packages included significant
spending to stimulate further investment in renewables. Around
7% of the USD 732.5 billion total announced by 31 governments
to support all types of energy was allocated directly to policies
favouring the production or consumption of renewables. However,
renewable energy investments outlined in recovery packages
were still only around one-sixth the level of investments allocated
to fossil fuels.
Energy projects represented nearly 60% of all climate finance
in 2017 and 2018, averaging USD 337 billion. Climate finance
flows from developed to developing countries reached
USD 78.9 billion in 2018, of which USD 12.5 billion was allocated
to projects targeting energy generation from renewable sources.
Multilateral climate funds and multilateral development banks
play an important role in providing direct support to developing
countries, while climate finance instruments, such as green
bonds, hit record levels for a second consecutive year, up 1.1% in
2020 to USD 269.5 billion.
The divestment movement continued its upward trend in 2020,
with more than 1,300 institutional investors and institutions worth
nearly USD 15 trillion committing to divesting partially or fully
from fossil fuel-related assets. Investors increasingly have aligned
their portfolios with the emission reduction goals of the Paris
Agreement. However, investment in fossil fuel-related companies
also has grown, and it is difficult to establish a direct link between
divesting from fossil fuels and investing in renewables.
24
06 ENERGY SYSTEMS INTEGRATION
AND ENABLING TECHNOLOGIES
Wind and solar reached record levels in the electricity mix in
2020, while sales of heat pumps, electric vehicles and energy
storage grew strongly despite the COVID-19 pandemic.
In the power sector, the installed capacity and penetration of
variable renewable electricity sources – mainly solar PV and wind
power – have grown rapidly in many countries. Several power
systems reached record-high shares of instantaneous VRE in
2020 due to lower costs of these renewable technologies and
to the effects of COVID-19 containment measures on electricity
markets.
The wider digitalisation of transmission and distribution grids
continued, as did growth in “behind-the-meter” systems. In
addition, electricity markets were adapted during 2020 to allow
for the participation of ancillary services from wind, solar and
battery storage. Flexibility services were procured increasingly
from VRE power plants, flexible sources of demand and virtual
power plants.
Grid infrastructure constraints have become a significant
bottleneck for the integration of renewables in several locations.
Large transmission projects also have faced regulatory hurdles.
Despite this, major projects were advanced in 2020, driven by
demand for grid capacity from VRE generators.
In contrast to the power sector, shares of renewables in global
transport and heating systems remained low in 2020. Integration
of renewable energy into road-based transport was advanced
mainly through vehicle electrification, while heat pumps offer
untapped potential to enable the use of renewables in the heating
and cooling sector. Along with energy storage, the enabling
technologies of heat pumps and EVs support the integration of
renewables and contribute to greater flexibility in power systems.
Sales of all three technologies increased in 2020, despite the
onset of the COVID-19 pandemic.
In 2020, heat pump uptake
slowed in the Asia-Pacific
region, while it continued
to increase in Nor th
America and Europe. The
heat pump industry was
characterised by company
acquisitions , techno –
logical developments in
refrigerants that have low
global warming potential,
and the emergence of
new solutions integrating heat pumps with other energy devices.
While global car sales decreased in 2020, sales of electric cars
(including both battery electric vehicles and plug-in hybrids)
resisted the COVID-19-induced downturn with nearly 3 million
units sold, up 41% from 2019. The share of electric cars in new car
sales worldwide reached 4.6% in 2020, surpassing the 2019 record
of 2.7%. Meanwhile, around one-third of the two- and three-
wheelers sold were electric, nearly all of them in China. Notable
activity in the EV industry during the year included significant
reductions in battery costs and automakers’ announcements that
they would shift, partially or fully, to electric production.
The global market for energy storage of all types reached
191.1 GW in 2020. Mechanical storage in the form of pumped
hydropower accounted for the vast majority of this capacity,
followed by roughly 14.2 GW of electro-mechanical and electro-
chemical storage, and around 2.9 GW of thermal energy storage.
The energy storage industry saw significant cost reductions,
innovation in battery technologies and increased collaboration in
the production of renewable hydrogen.
At least nine countries
generated
more than 20%
of their electricity from
solar PV and wind in 2020.
25
RENEWABLES 2021 GLOBAL STATUS REPORT
07 ENERGY EFFICIENCY, RENEWABLES
AND DECARBONISATION
Integrating renewable energy deployment and energy
efficiency measures remains crucial for decarbonising end-
use sectors and the energy system as a whole.
Renewable energy and energy efficiency have long been known
to provide multiple benefits to society, such as lowering energy
costs, improving air quality and public health, and boosting jobs
and economic growth. Increasingly, renewables and efficiency are
viewed as crucial to reduce carbon emissions. Energy production
and use account for more than two-thirds of global greenhouse
gas emissions. Together, renewables and energy efficiency have
made significant contributions to limiting the rise in CO2 emissions.
Trends in carbon intensity – measured as energy-based CO2
emissions per unit of gross domestic product (GDP) – help to
better understand the full impact of both energy efficiency
and renewables on the transition to more efficient and cleaner
energy production and use. Unlike overall emissions, the carbon
intensity of GDP reflects technical or structural improvements in
various sectors.
Between 2013 and 2018, global energy-related CO2 emissions
grew 1.9%, to nearly 38 gigatonnes. The increase occurred during
a period of economic growth – global GDP grew 23% during the
five-year period – but was slowed by improvements in the overall
carbon intensity of GDP. These improvements were due in part
to increased renewable electricity production and, to a greater
extent, to improved energy efficiency; this occurred despite an
overall decline in energy efficiency improvements that began
in 2015 and that was reinforced by the COVID-19 crisis and low
energy prices.
Some measures that apply to end-use sectors – such as
building energy codes and the deployment of distributed
renewables, heat pumps, and technologies for electrification
– impact carbon intensity as they can have both an energy
efficiency and a renewable energy component. Other energy
efficiency measures can play a role in each sector, including
digitalisation in the buildings and industry sectors, and vehicle
fuels and emission standards in the transport sector. In 2020,
the COVID-19 pandemic impacted the energy efficiency of all
end-use sectors.
Together, renewables and
energy efficiency have made
significant contributions to
limiting the
rise in CO2
emissions.
26
08 FEATURE: BUSINESS DEMAND FOR RENEWABLES
Businesses are increasing their uptake of renewable
energy across power, heating and cooling, and transport
needs. Company membership in business coalitions
promoting renewable energy procurement surged across
all sectors.
Several factors incentivise business demand for renewables.
Government policy continues to play a key role, but company-
level factors also are becoming prominent. Environmental and
ethical considerations encourage companies to adopt renewable
energy as part of their broader sustainability or emission
reduction goals. Renewables also are increasingly associated
with lower costs and a variety of risk mitigation opportunities,
thereby driving business demand. Surging membership in
coalitions, such as RE100 and EV100, that promote business
demand for renewables is also driving corporate uptake.
Businesses source their electricity from renewables in multiple
ways, including by generating it themselves (either on- or off-
site); procuring it from utilities through direct billing; purchasing
environmental attribute certificates from energy suppliers; and
signing long-term power purchase agreements with producers.
Despite a challenging business year, the new renewable energy
capacity that businesses sourced through PPAs increased 18%
in 2020, across nearly all regions. North America accounted
for the majority of the new capacity procured, and Amazon
was the leading corporate power purchaser. Policies to enable
cross-border PPAs were under development in Europe. In the
Asia-Pacific region, ongoing challenges to corporate sourcing
included regulatory and market barriers and limited or no
availability of corporate sourcing mechanisms.
Corporations meet their needs for low-temperature thermal
energy through renewables-based electrification, renewable
gases, procurement of renewable district heat, and the direct use
of geothermal heat, solar thermal heat and modern bioenergy. By
the end of 2020, nearly 900 solar thermal systems were supplying
industrial process heat, with new projects concentrated in China,
Mexico and Germany. In most cases, corporations produce and
consume on-site the energy they need for heating and cooling,
rather than sourcing it from elsewhere.
Corporations in energy-intensive industrial sectors – such as
iron and steel, cement, and chemicals production – use smaller
shares of renewables to meet their energy needs. Still, interest in
renewable energy procurement in these sectors has grown, and
business coalitions emerged on both the demand and supply
sides in 2020.
Businesses source renewable energy for their transport
needs mainly from biofuels, renewables-based electricity, and
renewable hydrogen across the road, rail, maritime and aviation
sectors. Electrification of fleet vehicles has become increasingly
popular, especially among companies operating in the more
than 300 zero-emission zones in cities worldwide. However,
the COVID-19 pandemic contributed to a 20% drop in sales
and investment in hydrogen-powered transport in 2020, as the
demand for hydrogen fuel cell buses fell.
Declining costs have made biofuels an increasingly viable option
for corporate procurement in maritime shipping, although their
use in this sector is marginal. Interest in renewable hydrogen
and ammonia also increased in the maritime transport sector.
In 2020, several aviation companies committed to sourcing
more-sustainable aviation fuels, while others showed interest in
developing electric and hydrogen aircraft.
27
City Developments Limited has mapped a pathway to reach its goal of net zero carbon emissions by 2030,
including investing heavily in energy efficiency and targeting 100% renewable energy.
01
i See Glossary.
01
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he renewable energy story during a crisis year was one
of resilience and adaptation, yet significant challenges
remain. During the year, restrictions on movement and
goods as well as the introduction of COVID-19 recovery packages
all had an impact on the production and use of renewable energy.
Despite suffering during the onset of the pandemic, renewable
energy saw a record increase of new power capacity in 2020
globally and was the only source of electricity generation
to experience a net increase in total capacity. Investment in
renewable power capacity increased (albeit slightly) for the third
consecutive year, and corporations continued to break records
for sourcing renewable electricity. More countries are turning
towards electrification of heat with renewables, and although
production of transport biofuels decreased, sales of electric
vehicles (EVs) expanded as did the linking of EVs to renewable
power (to a lesser extent). A wave of commitments to action on
the climate crisis included a carbon-neutrali target by China, while
the United States re-joined the Paris Agreement in early 2021.
At the same time, obstacles that have slowed progress in the
renewables sector in past years persisted during 2020. For the
first time ever, the number of countries with renewable energy
support policies did not increase from the previous year. While
renewable energy targets are in place in nearly all countries,
many countries were not on track to achieve their 2020 targets in
multiple sectors, and many had not yet set new targets as their
2020 targets came to term. Moreover, in COVID-19 recovery
packages, investment in fossil fuels was six times greater than
for renewable energy.
T
Despite the impacts of the COVID-19
pandemic, renewable energy set a record
in new power capacity in 2020 and was
the only source of electricity generation to
register a net increase in total capacity.
Renewables continued to meet low shares of
final energy demand in the buildings, industry
and transport sectors, where policy support
remains crucial to spurring uptake but is
insufficient.
For the first time, the number of countries
with renewable energy support policies
did not increase from the previous year.
While renewable energy targets are in place
in nearly all countries, many countries were
not on track to achieve their 2020 targets
in multiple sectors, and many had not yet set
new targets as their 2020 targets expired.
With the atmospheric concentration of CO2
rising to record levels even as emissions have
fallen, it has become increasingly clear that a
structural shift is needed to reach long-
term climate and development goals.
K E Y FA C T S
01
29
i Established in 2016, OPEC+ includes the 14 OPEC members as well as 10 additional oil and gas producing countries.
ii The REN21 Global Status Report (GSR) refers to clean and/or efficient cook stoves or fuels as per the methodology of the Multi-Tier Framework.
RENEWABLES 2021 GLOBAL STATUS REPORT
RENEWABLES IN 2020
As governments worldwide instituted lockdowns in 2020 to slow
the spread of COVID-19 and to respond to the resulting global
health crisis, economies ground to a halt and energy demand
plummeted. Overall, primary energy demand worldwide fell
around 4% during the year, resulting in a 5.8% drop in global
energy-related carbon dioxide (CO2) emissions – the largest
percentage decrease since World War II.1
Renewable energy reached its highest recorded share in the
global electricity mix in 2020 – an estimated 29% – due in large
part to low operating costs and preferential access to electricity
networks during periods of low electricity demand.2 Data for
countries representing more than one-third of global electricity
demand showed that every month of full lockdown during the
pandemic reduced electricity demand 20% on average, or more
than 1.5% on an annual basis.3
In the meantime, more than 256 gigawatts (GW) of renewable
power capacity was added globally during the year, surpassing
the previous record by nearly 30%.4 (p See Table 1.) While the
renewables sector proved to be notably robust during this
period, the fossil fuel industry largely struggled – especially the
global coal and oil industries – due to decreased demand as
well as difficulties for the oil industry in reaching production
agreements within the Organization of the Petroleum Exporting
Countries (OPEC)+ alliancei.5
Costs of producing electricity from wind and solar energy
have dropped significantly in recent years. In 2020, the global
weighted average levelised cost of electricity from utility-scale
solar photovoltaics (PV) declined 85% since 2010, while onshore
wind power costs fell 56% during the same period. (p See
Sidebar 6 in Market and Industry chapter.) These declines mean
that for most of the world’s population, electricity production
from new renewables is more cost effective than from new coal-
fired power plants.6 In a growing number of regions, including
parts of China, the European Union (EU), India and the United
States, it has already become cheaper to build new wind or
solar PV plants than to operate existing coal-fired power plants.7
Renewables also are outcompeting new natural gas-fired
power plants on cost in many locations, and are the cheapest
sources of new electricity generation in countries across all
major continents.8
In contrast to previous years, which had seen some growth, the
share of renewables in the transport sector remained constant.9
Although biofuels have continued to dominate the renewable
energy contribution in transport, the global EV stock has grown
significantly, increasing opportunities to integrate renewables
in road transport.10 The global market share of EVs remains low
overall, however.11
The uptake of modern renewables for heating and cooling
progressed at a slow pace. Consumption of renewable heat
suffered during the pandemic, and electrification of heating
in buildings (and to some extent in industry) attracted policy-
maker attention.12 However, the uptake of renewables in both
heating and transport remains constrained by insufficient policy
support and enforcement and by slow developments in new
technologies (such as advanced biofuels).13
Distributed renewables for energy access (DREA) systems
proved invaluable in many rural and remote communities during
the early phases of the pandemic, notably in Africa, powering
health facilities and other essential services through solar PV
mini-grids.14 However, measures to contain the virus hindered
companies, delayed projects and held back end-customers
from purchasing new systems.15 Sales of solar lanterns, in
particular, fell 30% in 2020 compared to 2019 even though they
rebounded in the second half of the year.16
The global population without access to electricity continued
to shrink, although 771 million people (10% of the world’s
population) still lacked electricity access in 2019 (latest data
available), nearly 75% of them in sub-Saharan Africa.17 However,
estimates for 2020 suggest that the pandemic led to reversals
in this trend for the first time since 2013: in Africa, 2% fewer
people (13 million people) had access to electricity in 2020.18
Meanwhile, the global population lacking access to clean
cookingii increased slightly in 2019 to around 2.6 billion people,
with few signs of progress.19 In addition, the pandemic further
worsened the inequities of lack of energy access, as populations
without access were more heavily affected during the year.20
30
i Including upstream/downstream oil, gas and coal supply.
ii “Clean” energy in this case includes renewable energy, energy efficiency, active transport (e.g., walking and cycling) and electric vehicles, but also may include
hydrogen that is produced from fossil fuels.
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Although analysts widely expected the economic blow in 2020 to
decrease renewable energy investment as much as 10%, the
opposite ended up being true.21 Due to a combination of factors
including policy support, low interest rates, fluctuating oil and gas
prices, and longer-term investor perspectives, global investment
in new renewable energy capacity (excluding large hydropower
projects) increased 2% from the previous year, reaching
USD 303.5 billion.22 In 2020, global investment in new renewable
power and fuel capacity was estimated to be more than twice
the investment in coal, gas and nuclear power generating plants
combined.23 However, considering all types of energy investmenti,
investment in fossil fuels far outweighed that of renewables.24
At least two countries withdrew support for fossil fuel
exploration. Denmark will cease all new oil and gas exploration as
part of a larger plan to stop extracting fossil fuels entirely (overseas
and domestic) by 2050.25 The United Kingdom announced
its intentions to end support for oil, gas and coal projects
overseas “as soon as possible”.26 Japan also was considering
withdrawing support for overseas exploration.27 Multilateral
development banks dedicated more than USD 13 billion
to “cleanii” energy, but at the same time they committed over
USD 3 billion to fossil fuels.28 By early 2021, numerous private
banks, pension funds and insurers also had committed to ending
or seriously restricting support for fossil fuels.29
Businesses continued to purchase more and more renewable
electricity. Corporate sourcing of renewable power set a record
in 2020, increasing 18% and reaching more than 23 GW of power
purchase agreements (PPAs) signed during the year.30 Most of
the installed capacity was solar PV, followed by wind power.31
By early 2021, more than 300 leading global corporations had
joined the RE100 initiative – committing to using 100% renewable
electricity – up from 167 corporations a year before.32 EV100 and
EP100 both saw growth in membership in 2020, while SteelZero
was launched in December.33
Companies also are meeting their heating, cooling and
transport needs with renewable energy, although these
activities are at a much smaller scale. (p See Feature chapter.)
In some manufacturing industries, such as pulp and paper
and food processing, firms supply relatively high shares of
their heat demand with renewables (mostly bioenergy), while
those in energy-intensive industries, such as steelmaking,
are exploring activities to decarbonise their energy use with
renewable hydrogen.34 (p See Box 1.) By early 2021, at least
2,360 companies had committed to net zero targets, a more
than four-fold increase since 2019.35
The ongoing shift among major energy companies to invest in
renewable energy highlights both the cost-competitiveness and
public appeal of renewables, in addition to political and investor
pressure. The world’s largest oil and gas companies continued
to invest in the renewable energy sector in 2020 (as well as to
acquire companies already active in the sector) and to invest in
technologies such as electric mobility and energy storage as
well as hydrogen production and distribution (although often
not renewable hydrogen).36 Even so, major fossil fuel companies
still invested heavily in oil and gas extraction projects, and only
a minor share of their overall investments goes to the renewable
energy sector, with some companies expected to miss their own
“green energy” investment targets.37 (p See Sidebar 1.)
BOX 1. Renewable Hydrogen in the GSR
In 2020, policy, industry and civil society attention to the
use of renewable hydrogen to reduce demand for fossil
fuels grew rapidly around the world. REN21’s Renewables
Global Status Report (GSR) treats (renewable) hydrogen as
an energy storage technology that is capable of converting
primary renewables into useful forms of energy in key sectors,
including certain industrial processes, maritime shipping and
aviation. As such, readers will find information on renewable
hydrogen distributed throughout the report, most prominently
in the Policy Landscape chapter (Sidebar 5 and Table 5)
and in the Energy Systems Integration and Enabling
Technologies chapter (pages 213 and 215).
31
i In 2019, 77 countries joined the Climate Ambition Alliance with an aspirational commitment to net zero carbon emissions by 2050; by early 2021, the country
total reached 121, although not all commitments have been backed by domestic action. The increased ambition and awareness among governments and companies
alike also is being reflected by international organisations, notably the International Energy Agency, which in early 2021 recommended under its new net zero scenario
no further investment in new fossil fuel supply projects and no further final investment decisions for new “unabated coal plants”. See endnote 42 for this chapter.
Share of renewables in TFEC (%)
50
40
30
20
10
0
Share of
renewable energy
in TFEC in 2019
Target for
renewables in TFEC
for year-end 2020
No target for 2020
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RENEWABLES 2021 GLOBAL STATUS REPORT
Beyond cost competitiveness and public appeal, awareness
of the multiple co-benefits of renewables increased during the
year, including improved public health through reduced pollution,
increased reliability and resilience, access to modern energy
services and job creation.38 (p See Sidebar 2.)
Awareness also increased surrounding equality and inclusiveness
in the energy sector, and the strong business case was reaffirmed
for increasing gender equality and cultural and ethnic diversity
in companies.39 An increasing number of companies joined the
Equal by 30 campaign, aiming for more gender equality in the
“clean energy” sector, specifically through equal opportunities,
pay and leadership.40 By early 2021, the campaign counted at
least six countries among its signatories (Canada, Finland, Japan,
the Netherlands, Sweden and the United Kingdom).41
Overall, commitments towards climate action greatly
increased during 2020. At least 21 countries and the EU
committed to greenhouse gas emission reduction targets during
the yeari – covering around 48% of global emissions – including
at least 9 countries committing to net zero emission targets and
9 committing to carbon-neutral targets in numerous significant
markets, such as China, the EU, the Republic of Korea and
Japan.42 (p See Table 4 in Policy Landscape chapter.) By the end
of 2020, around 800 cities had committed to net zero emissions –
up sharply from the 100 cities with such commitments by the end
of 2019.43 (p See Box 2.)
STRUCTURAL SHIF T NECESSARY
TO REACH CLIMATE AND
DEVELOPMENT GOALS
Even as global emissions decreased in 2020, the concentration
of CO2 in the atmosphere continued to rise to record levels,
highlighting that a structural shift is necessary to reach long-
term climate targets.44 This was vividly demonstrated at year’s end
when it became clear that, despite the lockdowns and drop in
economic activity, particularly early in 2020, there was no real lasting
dent in global emissions as some estimates had anticipated.45
Already by year’s end, while most countries continued to grapple
with the pandemic, CO2 emissions had strongly rebounded
from their earlier lows, rising in December to levels that were 2%
higher than a year prior.46
Despite more interest in net zero targets in 2020, these targets do
not necessarily cover all greenhouse gases or all sectors, nor do they
necessarily lead to greater attention to renewables or to success in
meeting renewable energy targets. Only five of the world’s largest
member economies in the Group of Twenty (G20) – the EU-27,
France, Germany, Italy and the United Kingdom – had set 2020
targets to achieve a certain share of renewables in final energy use.47
Of them, several were clearly not on track to achieve these targets
by year’s end.48 (p See Figure 1.)
FIGURE 1.
Renewable Energy Shares and Targets, G20 Countries, 2019 and 2020
Note: TFEC = Total final energy consumption. Data for Russian Federation and Saudi Arabia are for 2018 and 2017 respectively.
Source: See endnote 48 for this chapter.
32
i At the time of publication, global data for TFEC and the contribution of energy sources to meet energy demand were available for the year 2018; values for
2019 are estimates.
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FIGURE 2 .
Estimated Renewable Share of Total Final Energy Consumption, 2009 and 2019
ONGOING CHALLENGES TOWARDS A
RENEWABLES-BASED WORLD
The developments during 2020 highlighted some of the key ongoing
challenges impeding the widespread adoption of renewable
energy. They include the slow increase of renewables in total final
energy consumption (TFEC), the need for more innovation in some
sectors, the need for infrastructure development and increased
affordability in some markets, the lack of sufficient policy support
and enforcement, and persistent support for fossil fuels.
The share of renewables in TFEC has increased only moderately
due to:
rising global energy demand;
continuing consumption of and investment in new fossil fuels,
resulting in fossil fuels meeting most of the increasing demand, and
declining traditional use of biomass, which although a positive
development due to sustainability and health concerns
(p see Box 3) has meant that as people shift towards modern
sources of energy, much of this is via fossil fuels.49
As of 2019i, modern renewable energy (excluding the traditional
use of biomass) accounted for an estimated 11.2% of TFEC, up
from 8.7% a decade earlier.50 (p See Figure 2.) The largest portion
was renewable electricity (6.0% of TFEC), followed by renewable
heat (4.2%) and transport biofuels (1.0%).51
80.3 %
Fossil fuels
80.2 %
Fossil fuels
11.0 % Others
8.7 %
11.2 %
11.2 %
8.7 % Others
Modern
renewables
Modern
renewables
2019
Exajoules (EJ)
The
share of
fossil fuels in
final energy demand
barely changed over
one decade.
400
300
200
100
0
20192009
Wind/solar/
biomass/
geothermal/
ocean power
Biofuels for
transport
4.2% 3.6% 2.4% 1.0 %
Biomass/solar/
geothermal heat
Hydropower
80.3 %
Fossil fuels
80.2 %
Fossil fuels
11.0 % Others
8.7 %
11.2 %
11.2 %
8.7 % Others
Modern
renewables
Modern
renewables
2019
Exajoules (EJ)
The
share of
fossil fuels in
final energy demand
barely changed over
one decade.
400
300
200
100
0
20192009
Hydropower
3.6%
4.2%
2.4% 1.0%Wind/solar/biomass/
geothermal/ocean power
Biomass/solar/
geothermal heat
Hydropower
Biofuels for
transport
Note: Totals may not add up due to rounding. This figure shows a
comparison between two years across a 10-year span. The result of the
economic recession in 2008 may have temporarily lowered the share of
fossil fuels in total final energy consumption in 2009. The share in 2008
was 80.7%.
Source: Based on IEA data. See endnote 50 for this chapter.
33
RENEWABLES 2021 GLOBAL STATUS REPORT
BOX 2. Renewable Energy in Cities
REN21’s Renewables in Cities Global Status Report is an
annual stock-taking of the global transition to renewable
energy at the city level. City governments around the
world have taken action to accelerate the global uptake of
renewables, driven by air pollution concerns, public pressure
and the need to create clean, liveable, climate-resilient and
equitable communities.
Cities are home to 55% of the global population and growing,
and they account (directly or indirectly) for more than 80% of
global GDP. Urban energy use also has grown significantly in
recent decades due to global population growth, urbanisation
and urban economic activity. By 2018, cities accounted
for around three-quarters of global final energy use, and
cities release a similar share of global energy-related CO2
emissions. This makes cities high-impact areas for climate
action, including for decarbonising the energy system and
accelerating renewable energy investments, which help
cities achieve their own objectives as well as global goals.
Urban commitments to directly support renewables are
increasing. By the end of 2020, more than 1 billion people –
25% of the world’s urban population – lived in a city that had
a renewable energy target and/or policy (for a total of over
1,300 cities), and during the year around 260 cities set new
targets or passed new policies. This includes more than 830
cities in 72 countries that had adopted targets for renewables,
with more than 600 cities setting targets for 100% renewable
energy (with varying target dates).
Commitments to decrease greenhouse gas emissions also
can result indirectly in greater use of renewables citywide. By
2020, more than 10,500 cities had adopted targets to reduce
their greenhouse gas emissions, and around 800 cities had
committed to net zero emissions, with the number of such
net zero targets increasing roughly eight-fold from 2019. To
achieve these targets, city governments have been leading
by example, scaling up on-site renewable energy generation
(mostly solar PV) and/or procurement for public buildings
and municipal fleets.
Achieving urban renewable energy targets depends not
only on political commitment and municipal investment
in renewables, but also on the city’s ability to enable the
uptake of renewables city-wide, by other actors. Contrary
to the slow pace at the national level, momentum has been
growing for city-level policies that move beyond the power
sector to support renewables in heating and cooling, the
transport sector, and integrated policy approaches. These
include both direct and indirect support policies, municipal
codes and mandates for new buildings, incentives for
retrofitting existing buildings, and bans and restrictions on
fossil fuel use for both the buildings and transport sectors.
p See Renewables in Cities 2021 Global Status Report, along
with the report’s city case studies and cities data pack at
https://www.ren21.net/cities.
Source: See endnote 43 for this chapter.
34
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The share of renewable
energy has increased
only moderately each
year despite tremendous
growth in some
renewable energy sectors.
Total demand for modern
renewables grew strongly
(15.1 exajoules, EJ) during
the 10-year period 2009-
2019, rising around 4.4%
annually.52 Total final
energy consumption grew 60.9 EJ, or around 1.8% annually.53
Thus, renewable energy increased at more than twice the rate
of TFEC, accounting for 25% of the total increase in energy
demand.54
However, this means that other energy sources (mainly fossil
fuels, which grew 1.7% annually) accounted for 75% of the total
increase in energy demand during this period, highlighting
the challenge that renewables faced in gaining greater TFEC
shares.55 (p See Figure 3.) This slow progress points to the
complementary and fundamental roles of energy conservation,
energy efficiency and renewables in reducing the contributions
of fossil fuels in meeting global energy needs and reducing
emissions.
Efficiency and conservation reduce overall demand for (additional)
energy to achieve the same energy services, making it easier for
renewables to attain a larger share of the total. However, energy
efficiency also faced challenges in 2020. The rate of energy
intensity improvements had been declining since 2015, and in
2020 the global crisis coupled with low energy prices resulted
in only an estimated 0.8% improvement in energy intensity – half
the rate of the previous two years.56
BOX 3. Sustainability in the GSR
Much of the support for renewables to-date has focused
on the social and economic acceptance of the energy
transition, including the roles of political leadership,
financial measures and market confidence. Accelerating
the scale-up of renewables also means fostering public
acceptance of renewable energy systems and investigating
the key challenges to acceptance that they are facing. The
sustainability of renewable energy technologies, infrastructure
and supply chains is a key emerging issue. While there is no
one definition of sustainability within the renewable energy
context, this concept is usually determined by environmental,
social and economic dimensions.
Even though the development of renewable energy is
understood as essential for tackling climate change, the
recent and planned expansion of renewables has raised
notable sustainability concerns. Some of these issues have
a longer history, such as considerations around the impacts
that hydropower reservoirs and dams have on ecosystems
and host communities and, in recent years, the debate
on the role of bioenergy, especially in the context of the
unsustainable use of biomass. More recently, as solar and
wind power projects have become more numerous, issues
around their long-term sustainability have come into the
spotlighti. In addition, the resource requirements and lifecycle
emissions of renewable energy technologies have received
increasing attention.
Critically examining the environmental, social and economic
impacts of renewables along the value chain, using a
comprehensive approach and having an informed and
transparent debate is necessary to address perceived
tensions and challenges in shifting to a renewable-based
energy system. Future editions of the GSR will address the
topic more holistically, as will additional projects from REN21.
i See, for example, L. Bennun et al., Mitigating Biodiversity Impacts
Associated with Solar and Wind Energy Development (Gland,
Switzerland: IUCN, 2021), https://portals.iucn.org/library/sites/
library/files/documents/2021-004-En .
Source: See endnote 49 for this chapter.
Renewable energy
accounted for
only
one-quarter
of the total increase in
energy demand between
2009 and 2019.
35
https://portals.iucn.org/library/sites/library/files/documents/2021-004-En
https://portals.iucn.org/library/sites/library/files/documents/2021-004-En
i Electrical applications account for a higher portion of primary energy consumption. See Glossary for definitions.
ii Applications of thermal energy include space and water heating, space cooling, refrigeration, drying and industrial process heat, and any use of energy other than
electricity that is used for motive power in any application other than transport. In other words, thermal demand refers to all end-uses of energy that cannot be
classified as electricity demand or transport.
iii However, policy support increased at the local level, where city governments have continued to take action to accelerate the global uptake of renewable energy
to create clean, livable and equitable cities and have had a particular impact in the uptake of renewables in buildings and transport. Overall, more than 1 billion
people lived in a city with a renewable energy target and/or policy in 2020. (p See Box 2.)
RENEWABLES 2021 GLOBAL STATUS REPORT
As in past years, the highest share of renewable energy is in electrical
applications (excluding electricity for heating, cooling and transport),
such as lighting and appliances.57 However, these end-uses account
for only 17% of TFECi.58 Energy use for transport represents some
32% of TFEC, and has the lowest share of renewables (3.4%).59 The
remaining thermalii energy uses, which include space and water
heating, space cooling and industrial process heat, accounted for
more than half (51%) of TFEC; of this, some 10.2% was supplied
by renewables.60 Increasing the renewable share in transport and
thermal end-uses is necessary to reach a higher share of renewable
energy in overall TFEC.61 (p See Figure 4.)
Although costs for most renewable energy technologies have
fallen (some precipitously, such as for solar PV and onshore wind
power), innovation is still needed to enable the widespread
adoption of renewables in harder-to-decarbonise sectors, such as
energy-intensive industrial processes and long-haul transport.62
The integration of variable renewable energy sources (such as solar
and wind) into existing power systems could be further enabled by
expanded and modernised grid infrastructure, further cost declines
in energy storage, and advances in new business models and
market design that allow electricity supply to flexibly meet demand.63
In addition, affordability in some markets can be hampered by
various elements, such as higher labour costs, permitting costs, land
constraints, availability of renewable resources, lack of favourable
policy frameworks and infrastructure issues.64
Another key reason for the low penetration of renewables is the
persistent lack of supporting policies and policy enforcement,
particularly in the transport and heating and cooling sectors.
Targets for renewables are not only more numerous but also more
ambitious for the power sector. While renewable energy targets are
in place in nearly all countries, many countries were not on track
to achieve their 2020 targets in multiple sectors, and many had
not yet set new targets as their 2020 targets were coming to term.
Targets also were more often achieved and set for the power
sector than for heating and cooling or transport. (p See Figure 11
in Policy Landscape chapter.) However, many jurisdictions
announced emission reduction targets during the year, which
could support increasing the renewable share in these sectors
where the targets are economy-wide.65 Also, many countries have
submitted more ambitious climate pledges across sectors for
2030 through their updated Nationally Determined Contributions
(NDCs) towards reducing emissions under the Paris Agreement.66
In contrast to previous years, the number of countries with
renewable energy support policies did not increase in 2020iii.67
The number of countries with mandates for renewable heat also
did not grow, and policy examples for renewable energy support
in industry remained scarce. No new countries added regulatory
incentives or mandates for renewables in transport, although
some countries that already had mandates added new ones or
strengthened existing ones. Only three countries had a policy
directly linking renewables and EVs by year’s end, with Japan
newly joining Austria with a similar incentive for charging EVs
with renewable electricity, alongside Germany with its policy
supporting renewable-based charging infrastructure.68 Policies
supporting renewable hydrogen also remained rare. (p See
Table 5 in Policy Landscape chapter.)
FIGURE 3.
Estimated Growth in Modern Renewables as Share of Total Final Energy Consumption Between 2009 and 2019
Source: Based on IEA data. See endnote 55 for this chapter.
75%
Fossil fuels,
nuclear,
traditional
biomass
25%
Modern
renewables
Worldwide the growth in total
final energy demand continued.
Only one quarter of the increase
was covered by renewable energy.
TFEC (Exajoules)
2009 2019
400
300
200
100
0
320
381
36
i For example, in the Czech Republic and in Germany.
ii “Build back better” was a term adopted by the international community in the Sendai Framework for Disaster Risk Reduction 2015-2030.
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In addition, fossil fuel subsidies remain a persistent challenge
for renewable energy. Despite calls by world leaders, leading
economists, international organisations and non-governmental
organisations for governments to use COVID-19 recovery efforts
to advance the phase-out of fossil fuel subsidies, this support
remained in the hundreds of billions of dollars (nearly USD 500
billion as of 2019), far above the support for renewables.69 In
many countries, investment in new fossil fuel production and
related infrastructure continued. Although some countries were
phasing out coal, others invested in new coal-fired power plants,
both domestically and abroad. Similar to the previous year, in
2020 many coal-fired plants announced closures in Europe and
the United States, where almost no new plants had been planned
for a few years and decommissioning has been accelerating,
although some new plants began operating during the yeari.70
Most of the still-operating, new and planned coal plants were
located in developing and emerging Asia.71
During the first half of 2020, global net coal power capacity fell
for the first time in history, as decommissioning outpaced new
installations.72 However, by year’s end a steep increase in new
coal capacity in China offset global retirements, resulting in the
first annual increase in global coal capacity since 2015.73 In line
with past years, public finance from China funded by far the largest
amount of coal capacity in other countries, followed by funding
from Japan, the Republic of Korea, France, Germany and India,
nearly all of which was directed towards developing and emerging
countries.74 Funding from private banks for fossil fuel projects also
has increased annually since the signing of the Paris Agreement
in 2015, totalling USD 2.7 trillion between 2016 and 2019.75
Despite international calls to “build back better”ii from the
COVID-19 crisis, the majority of energy-related recovery funds
were either directly or indirectly in support of fossil fuels.76
(p See Figure 49 in Investment chapter.) Governments around
the world announced at least USD 732.5 billion in energy-
related stimulus during 2020, and some stimulus packages
included incentives for renewables; however, as of April 2021 only
around USD 264 billion (36%) of the total amount provided by
governments globally was for renewables, whereas more than
USD 309 billion was allocated to fossil fuels, although the shares
of funds for “clean” energy versus fossil fuels varied by region
and country.77 In some cases, coal was explicitly supported in
recovery packages, such as in Poland, which seeks to maintain
coal operations until 2049.78
The following sections discuss key developments in renewable
energy in the sectors of buildings, industry and transport, followed
by a discussion on renewable power capacity and renewable
electricity generation.
FIGURE 4.
Renewable Energy in Total Final Energy Consumption, by Final Energy Use, 2018
Note: Data should not be compared with previous years because of revisions due to improved or adjusted methodology.
Source: Based on IEA data. See endnote 61 for this chapter.
Thermal 51%
10.2%
Renewable
energy
27.1%
Renewable
3.4%
Renewable
energy energy
Transport 32% Power 17%
2.1%
Renewable electricity
Renewable
electricity
0.3%
Renewable electricity
3.1%
0.8%5.7%
Biofuels
7.0%
Modern bioenergy
1.1%
Solar thermal and
geothermal heat
Non-renewable
electricity
Non-renewable
electricity
37
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 1. Oil and Gas Suppliers and the Renewable Energy Transition
The year 2020 was challenging for the oil and gas industry.
Demand disruption due to the COVID-19 crisis and an oil price
war between OPEC and the Russian Federation combined to
create oversupply and plunging prices. Conventional oil and gas
suppliers increasingly are feeling the impetus to participate in
the renewable energy transition in order to remain competitive,
and due to pressure from energy users and investors.
In many parts of the world, public sentiment is rapidly
turning against fossil fuels. Public and private investors
alike are pulling money out of fossil fuel companies, with
institutional investors worth nearly USD 15 trillion committed
to divestment as of early 2021. (p See Investment chapter.)
While the transition away from fossil fuels is most visible
in the power sector, it has been much slower in harder-to-
decarbonise sectors such as industrial heat and heavy-duty
transport, where oil and gas are more heavily embedded.
Major oil and gas companies have used a variety of strategies
to try to position themselves as key players in the energy
transition. Many have sought to signal a shift in priorities
through their communications and public relations activities,
including rebranding efforts. BP spearheaded the trend when it
rebranded itself as “Beyond Petroleum” from “British Petroleum”
in 2001. A host of other companies followed suit: GDF (Gaz de
France) Suez became ENGIE in 2015, Danish Oil and Natural
Gas (DONG Energy) became Ørsted in 2017, Statoil became
Equinor in 2018, Gas Natural Fenosa became Naturgy in 2018,
and Total became TotalEnergies in 2021. In a similar vein, the
chief executive officer of Royal Dutch Shell communicated to
investors in 2018 that the company is no longer an oil and gas
company, but rather an “energy transition company”.
While Ørsted has gone further than name change, transitioning
from an oil and gas company to a large player in renewable
power (predominantly offshore wind), others are still at early
stages in their transitions. By the end of 2020, European majors
BP, Eni, Equinor, Repsol, Shell and Total had all announced net
zero emission targets for 2050, albeit with vast differences
in coverage and ambition. While BP, Eni and Equinor have
committed to absolute reductions in emissions, Repsol,
Shell and Total aim to cut their emission intensities instead,
making it possible for them to meet their targets without
having to actually cut fossil fuel production. Reflecting these
differences, BP announced in 2020 that it aims to slash oil and
gas production 40%i by 2030 from 2019 levels, while Shell
revealed in early 2021 that it had committed far more to oil and
gas exploration and production than to renewables. However,
in May 2021, Shell was ordered by a Dutch court to reduce
carbon dioxide emissions (including emissions arising from the
use of its products) 45% by 2030, relative to 2019 levels.
Each of these companies also has intermediate targets to
invest in renewables or to expand their own renewable energy
(mostly power) capacities. BP aims for 50 GW by 2030, Total
plans to install 35 GW of renewable power capacity by 2025,
Eni and Repsol are both targeting 15 GW by 2030, Equinor is
targeting 12-16 GW by 2035 and Shell has an annual investment
target of USD 2-3 billion in renewable energy and hydrogen
(although not necessarily produced from renewables). Some
companies – such as Repsol, Shell and Total – also link
executive remuneration to emission reduction measures. On
the other hand, US-based oil and gas giants Chevron and
ExxonMobil do not have any renewable energy targets, and the
emissions intensity reduction targets they do have are short-
term and less ambitiousii. The difference in their approaches
reflects the divergent policy priorities and shareholder interests
in the United States and Europe so far, although these trends
may be changing. In May 2021, 61% of Chevron shareholders
voted to cut Scope 3 emissions – emissions arising from the
use of the company’s products – and ExxonMobil lost two
board seats to a climate activist hedge fund.
Oil and gas companies can help advance the energy
transition by reallocating their significant capital to address
the investment gap facing the renewable energy sector.
However, some companies still hesitate to diversify much
into renewable energy and remain more inclined to protect
their core businesses. Chevron, ExxonMobil and Shell, for
example, have started sourcing renewable electricity to
power their oil and gas operations by signing long-term PPAs
with renewable energy companies, a move that lowers their
emission intensities but may not greatly impact their absolute
emissions. Chevron and ExxonMobil also are mostly allocating
their energy transition funds (roughly 3-4% of their total capital
expenditures) to research and development of technologies
like carbon capture and storage, nuclear fusion reactors, EV
charging infrastructure, battery storage and advanced biofuels.
At the same time, other oil and gas majors have invested in
renewables either by acquiring stakes in renewable energy
companies or by diversifying their core businesses towards
renewables. For example, in 2011 Total purchased a 60%
38
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majority stake in US solar company SunPower in a
USD 1.4 billion deal. In 2017, BP acquired a 43% stake in
European solar developer Lightsource to create Lightsource
BP, and later increased its stake to 50% in 2019. In 2018, Shell
acquired 44% of US solar power firm Silicon Ranch and made
an equity investment of USD 20 million in India’s distributed
renewable utility company Husk Power Systems.
In terms of installed renewable energy capacity, Total and BP
led in 2020 with 3 GW and 2 GW respectively, followed by
Repsol at 1.3 GW, Shell at 0.9 GW, Equinor at 0.5 GW and Eni
at 0.2 GW. Companies such as BP, Chevron, Equinor, Total and
Unocal have begun making forays into the geothermal energy
and offshore wind power sectors, which are readily accessible
by oil and gas majors and present organic growth opportunities.
Despite changing headwinds, many forces motivate oil and
gas companies to continue with business as usual. As of
2019, these companies had collectively invested less than
1% of their total capital expenditure in activities outside their
core business areasiii, with the leading companies spending
on average around 5% on projects outside core oil and gas
supply. (p See Figure 5.) Companies like BP and Shell maintain
membership in industry associations that lobby against climate
action. Moreover, provisions of international trade pacts like
the Energy Charter Treatyiv protect the fossil fuel industry
at the expense of the renewable energy sector, and global
post-COVID recovery packages have tended to favour fossil
fuel industries over renewables. (p See Sidebar 3 in Policy
Landscape chapter.)
FIGURE 5.
Spending on Renewable Energy versus Total Capital Expenditure, Selected Oil and Gas Companies, 2020
Note: Oil and gas companies do not explicitly report on renewable energy spending in their financial statements. Eni was the only company that
provided this number for 2020. Equinor, Chevron, BP and ExxonMobil conflate renewable spending with environmental or low-carbon spending in
general. Total and Shell conflate renewable spending with spending on power generation, including fossil-based generation.
Source: See endnote 37 for this chapter.
Total capital expenditure
Capital expenditure
on renewable energy
Capital expenditure
on renewable energy
and power
(including fossil-based
generation)
Capital expenditure
on low-carbon solutions
Capital expenditure (billion USD) 5 10 15 20
0.80.8
0.90.9
8.98.9
9.89.8
0.40.4
5.75.7
0.10.1
14.114.1
17.817.8
21.421.4
1.11.1
0.50.5
15.515.5
1.81.8
0
Eni
Equinor
Chevron
BP
Shell
ExxonMobil
Total
Eni was
the only oil and gas
company that reported
renewable energy
spending data
for 2020
i BP’s commitment does not, however, include production from Rosneft, the Russian oil and gas company of which it holds a major share. This means that
nearly 30% of BP’s carbon emissions (Rosneft’s share of emissions in 2019) would remain unaffected by its net zero ambition. See endnote 37 for this chapter.
ii Chevron has a 40% emissions intensity reduction target in oil production and 26% in gas production by 2028 (relative to the 2016 baseline), while
ExxonMobil has a 15-20% upstream emissions intensity reduction target by 2025.
iii Activities outside core business areas may include any ventures outside exploration and production for oil and gas companies, with the exact definition
differing across companies. Renewable energy projects are likely to form a small proportion of such activities, however the exact proportion is unknown
due to lack of disaggregated reporting by oil and gas majors.
iv The Energy Charter Treaty is a multilateral agreement for energy co-operation, enforced under international law since 1998. One of its provisions protects
foreign investments from policy changes in host countries, and effectively allows fossil fuel companies to sue national governments for climate action and
seek compensation when their interests are threatened. Talks on reforming the treaty are ongoing. For details, see sources in endnote 37 for this chapter.
39
RENEWABLES 2021 GLOBAL STATUS REPORT
2019 2020
INVESTMENT
New investment (annual) in renewable power and fuels1 billion USD 298.4 303.5
POWER
Renewable power capacity (including hydropower) GW 2,581 2,838
Renewable power capacity (not including hydropower) GW 1,430 1,668
Hydropower capacity2 GW 1,150 1,170
Solar PV capacity
3 GW 621 760
Wind power capacity GW 650 743
Bio-power capacity GW 137 145
Geothermal power capacity GW 14.0 14.1
Concentrating solar thermal power (CSP) capacity GW 6.1 6.2
Ocean power capacity GW 0.5 0.5
HEAT
Modern bio-heat demand (estimated)
4 EJ 13.7 13.9
Solar hot water demand (estimated)
5 EJ 1.5 1.5
Geothermal direct-use heat demand (estimated)
6 PJ 421 462
TRANSPORT
Ethanol production (annual) billion litres 115 105
FAME biodiesel production (annual) billion litres 41 39
HVO biodiesel production (annual) billion litres 6.5 7.5
POLICIES7
Countries with renewable energy targets # 172 165
Countries with renewable energy policies # 161 161
Countries with renewable heating and cooling targets # 49 19
Countries with renewable transport targets # 46 35
Countries with renewable electricity targets # 166 137
Countries with heat regulatory policies # 22 22
Countries with biofuel blend mandates8 # 65 65
Countries with feed-in policies (existing) # 83 83
Countries with feed-in policies (cumulative)9 # 113 113
Countries with tendering (held during the year) # 41 33
Countries with tendering (cumulative)9 # 111 116
1 Data are from BloombergNEF and include investment in new capacity of all biomass, geothermal and wind power projects of more than 1 MW; all hydropower
projects of between 1 and 50 MW; all solar power projects, with those less than 1 MW estimated separately; all ocean power projects; and all biofuel projects
with an annual production capacity of 1 million litres or more. Total investment values include estimates for undisclosed deals as well as company investment
(venture capital, corporate and government research and development, private equity and public market new equity).
2 The GSR strives to exclude pure pumped storage capacity from hydropower capacity data.
3 Solar PV data are provided in direct current (DC). See Methodological Notes for more information.
4 Includes bio-heat supplied by district energy networks and excludes the traditional use of biomass. See Reference Table R1 in the GSR 2021 Data Pack and related
endnote for more information.
5 Includes glazed (flat-plate and vacuum tube) and unglazed collectors only. The number for 2020 is a preliminary estimate.
6 The estimate of annual growth in output is based on a survey report published in early 2020. The annual growth estimate for 2020 is based on the annualised
growth rate in the five-year period since 2014. See Geothermal section of Market and Industry chapter.
7 A country is counted a single time if it has at least one national or state/provincial target or policy. See Table 6 and Reference Tables R3-R11 in the GSR 2021
Data Pack.
8 Biofuel policies include policies listed both under the biofuel obligation/mandate column in Table 6 and in Reference Table R8 in the GSR 2021 Data Pack.
9 Data reflect all countries where the policy has been used at any time up through the year of focus at the national or state/provincial level.
See Reference Tables R10 and R11 in the GSR 2021 Data Pack.
Note: All values are rounded to whole numbers except for numbers <15, biofuels and investment, which are rounded to one decimal point.
FAME = fatty acid methyl esters; HVO = hydrotreated vegetable oil.
TABLE 1.
Renewable Energy Indicators 2020
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1 2 3 4 5
Solar PV capacity China United States Vietnam Japan Germany
Wind power capacity China United States Brazil Netherlands Spain or Germany
Hydropower capacity China Turkey Mexico India Angola
Geothermal power capacity Turkey United States Japan – –
Concentrating solar thermal
power (CSP) capacity China – – – –
Solar water heating capacity China Turkey India Brazil United States
Ethanol production United States Brazil China Canada India
Biodiesel production Indonesia Brazil United States Germany France
1 2 3 4 5
POWER
Renewable power capacity
(including hydropower) China United States Brazil India Germany
Renewable power capacity
(not including hydropower) China United States Germany India Japan
Renewable power capacity per
capita (not including hydropower)1 Iceland Denmark Sweden Germany Australia
Bio-power capacity China Brazil United States Germany India
Geothermal power capacity United States Indonesia Philippines Turkey New Zealand
Hydropower capacity2 China Brazil Canada United States Russian Federation
Solar PV capacity China United States Japan Germany India
Concentrating solar thermal
power (CSP) capacity Spain United States China Morocco South Africa
Wind power capacity China United States Germany India Spain
HEAT
Modern bio-heat demand in
buildings United States Germany France Italy Sweden
Modern bio-heat demand
in industry Brazil India United States Finland Sweden
Solar water heating collector
capacity2 China Turkey India Brazil United States
Geothermal heat output
3 China Turkey Iceland Japan New Zealand
1 Per capita renewable power capacity (not including hydropower) ranking based on data gathered from various sources for more than 70 countries and on 2019
population data from the World Bank.
2 Solar water heating collector ranking for total capacity is for year-end 2020 and is based on capacity of water (glazed and unglazed) collectors only. Data from
International Energy Agency Solar Heating and Cooling Programme.
3 Not including heat pumps.
Note: Most rankings are based on absolute amounts of investment, power generation capacity or output, or biofuels production; if done on a basis of per capita,
national GDP or other, the rankings would be different for many categories (as seen with per capita rankings for renewable power not including hydropower and
solar water heating collector capacity).
Annual Investment / Net Capacity Additions / Production in 2020
Technologies ordered based on total capacity additions in 2020.
Total Power Capacity or Demand / Output as of End-2020
TABLE 2.
Top Five Countries 2020
41
i “Buildings” in the GSR refers to the activities and energy used in building operation and maintenance, and does not include manufacturing, transport or use
of building materials, or energy use in construction activities.
ii Due to data availability and publication dates for comprehensive datasets, the most recent data available for energy consumption are in the year 2018.
Throughout this section, estimates are made for the year 2019.
iii Includes electricity for heating and cooling. The GSR considers all electricity used for heating and cooling to contribute to the final heating and cooling de-
mand in each end-use sector, rather than to the respective final electricity demand. In order to determine total electricity consumption, demand of
electrical end-uses and electricity for heating and cooling should be summed. See Methodological Note.
iv The traditional use of biomass for heat involves burning woody biomass or charcoal, as well as dung and other agricultural residues, in simple and inefficient
devices to provide energy for residential cooking and heating in developing and emerging economies. Modern bioenergy is any production and use of
bioenergy that is not classified as “traditional use of biomass”.
RENEWABLES 2021 GLOBAL STATUS REPORT
BUILDINGS
Buildings historically have accounted for around 33% of final
energy use, a share that was relatively stable in the decade
leading up to 2020.79 Renewable energy meets a growing share
of final energy demand in buildings, although it remains less than
15% and has risen slowly overall.80 Increases in renewable energy
consumption are most noticeable in electricity use, whereas
heating with renewables is rising more slowly.81 Bioenergy
remains the global front-runner in supplying renewable heat to
buildings, while the use of renewable electricity to meet heating
loads (i.e., electrification) is rising rapidly and already covers the
full renewable contribution to cooling demand.82
The COVID-19 pandemic impacted energy use in the buildingsi
sector – at their peak in April 2020, partial or full stay-at-home
orders were active in countries responsible for around 55% of
global primary energy demand.83 As a result of these restrictions,
millions of people began working from home. This shifted energy
use, particularly electricity demand, away from industrial activity,
transport and commercial buildings and towards residential
buildings.84 The global impact on energy demand in 2020 was not
known at the time of publication; however, first estimates suggest
that remote work could have contributed to a net reduction in
building energy consumption in 2020.85
The sector is a significant contributor to global energy-related
CO2 emissions.86 Prior to the pandemic, this share was 28%, with
significant regional variations, and was increasing steadily, driven
mainly by growth in indirect emissions from electricity generation
and from production of heat consumed in buildings.87
Population and building floor area are typical indicators that
have propelled past trends in global building energy use.88 In
the decade leading to 2020, growth in both indicators exceeded
any reductions in demand resulting from energy efficiency
measures, leading to around a 1% annual increase in building
energy consumption.89 However, growth in both energy demand
and CO2 emissions was lower than the rise in population and
building floor area, underlining a gradual decoupling and overall
improvement in the energy and carbon intensity of building
operations.90 Increased use of renewables was responsible for an
estimated 15% of this improvement across all sectors.91
Renewables are the fastest growing energy source for buildings,
rising 4.1% annually on average between 2009 and 2019ii.92
Despite this growth, renewables met only an estimated 14.3%
of total energy demand in buildings in 2019, up from 10.5% in
2009.93 Energy use in buildings can be split into two basic
needs. Thermal energyiii needs – including space heating and
cooling, water heating and cooking – account for around 77%
of global final energy demand in buildings.94 The remaining 23%
is electrical end-uses, which comprise lighting, appliances and
other uses unrelated to heating or cooling.95
Already, most of the world’s cooling demand is supplied by
electricity.96 Meanwhile, the demand for cooling has continued to
grow rapidly in emerging countries, notably in Sub-Saharan Africa
and in Southeast Asia.97 However, the world’s average cooling
load is met mainly by less-efficient models of air conditioner
compared to the most efficient technology available.98
Electricity also meets a rising proportion of the world’s heat
demand in buildings, having increased from around 9.6% in
2009 to 11.7% in 2019.99 As the share of renewable electricity in
the global power system continues to grow, electrification has
increasingly emerged as the preferred route to decarbonise
heating systems in buildings.100
Total energy demand for heating and cooling grew at around
the same rate as building energy use (1% per year) between 2009
and 2019.101 It was outpaced by the growth of renewable heating
and cooling in buildings over the same period (around 6%).102
Chief among the factors for this increase was the use of renewable
electricity for heating (and cooling), while modern bioenergyiv
use has stayed relatively stable.103 However, the renewable
energy share of heating demand grew from only around 8% to
nearly 11% over the same decade, underscoring the importance
of energy efficiency in enabling higher shares of renewables.104
(p See Figure 6.)
42
i As of 2019, these included Iceland, Sweden, Latvia, Finland and Estonia. See endnote 106.
ii When accounting for bioenergy delivered by district heating networks, the share rises to around 5%.
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Although the global renewable heating and cooling share
in buildings remains low, some countries and regions have
achieved relatively higher shares. In the EU, a global leader in
this area, renewable energy accounted for more than 21% of
total heating and cooling needs (including industrial process
heat) in 2018 (latest data available).105 Certain Baltic and Nordic
countriesi supply more than 50% of their building heat demand
with renewables.106
Demand for cooling is the most rapidly growing energy end-
use in buildings.107 Sales of cooling devices are growing fastest
in developing and emerging countries.108 As most cooling is
supplied by electric devices, the contribution of renewables to
meeting this demand depends largely on the prevailing electricity
fuel mix; however, significant regional variations exist.109
The global mix of renewable energy technologies supplying heat
to buildings is gradually shifting. Modern bioenergy has long
delivered the largest amount of renewable heat to buildings,
responsible for around half of all renewable heat consumption.110
Bioheat typically is produced in wood-burning furnaces or
combusted and delivered via district energy networks.111 In 2019,
bioheat met around 4.6% of total heat demand in buildingsii.112
Its role is shrinking, however, as solar thermal heat, geothermal
heat and renewable electricity for heat are expanding and
gaining shares.113
Solar thermal and geothermal energy together contributed
some 2.2% of heat demand in buildings in 2019, up from 0.8%
in 2009.114 Globally, demand for new solar thermal systems
contracted slightly in 2020, and the impact of existing policy had a
greater effect than the general impact of the pandemic, notably in
China (the global leader).115 China was similarly the world’s largest
and fastest-growing market for direct consumption of geothermal
heat in buildings, growing 21% annually during 2015-2020, while
the runners-up (Turkey, Iceland and Japan) grew 3-5%.116 Overall,
consumption of solar and geothermal heat sources has grown
more rapidly (each up around 11% per year) than bioenergy use in
recent years, although starting from a small base.117
After bioenergy, the use of renewable electricity for heat
provided the second largest renewable energy contribution to
building heat demand at around 3.2% in 2019, up from 2.0% in
2009.118 Over this period, electricity contributed more than one-
third of the overall demand growth for renewable building heat
– the most of any renewable energy source.119 However, most of
the increase was due to the growing share of renewables in the
global electricity supply, rather than to rising electrification of
heating in buildings.120 In total, the global share of all electricity
use in final energy consumption of buildings grew from 28% in
2009 to an estimated 32% in 2019, an increase in global share
even as final energy consumption rose.121
FIGURE 6.
Renewable Energy Contribution to Heating in Buildings, by Technology, 2009 and 2019
Note: Energy demand is reported in exajoules (EJ). Includes space heating, space cooling, water heating and cooking. Renewable district heat is virtually all
supplied by bioenergy. Totals may not add up due to rounding.
Source: Based on IEA data. See endnote 104 for this chapter.
20192009
4.2 EJ 1.7 EJ
0.5 EJ
3.0 EJ
1.5 EJ
Modern
bioenergy
4.3 EJ
Modern
bioenergy
7.8%
Share of renewables in
building heat demand
10.4%
Share of renewables in
building heat demand
Renewable electricity
for heat
Geothermal
heat
Renewable district heat
Solar thermal heat
0.2 EJ 0.6 EJ
0.2 EJ 0.4 EJ
43
i These statistics often include waste heat as a “renewable” source of district heat.
ii The six countries are, in descending order, Iceland, Norway, Sweden, Lithuania, Denmark and France.
iii Gaseous fuels refer to liquefied petroleum gas (LPG), natural gas and biogas, with LPG comprising the majority. Although not all renewable, these fuels – in
addition to electricity and improved biomass – combined with their related stoves are considered “clean cooking” facilities as per the guidelines of the World
Health Organization (WHO) for indoor air quality linked to household fuel combustion. See WHO, WHO Guidelines for Indoor Air Quality: Household Fuel
Combustion (Geneva: 2014), https://www.who.int/airpollution/guidelines/household-fuel-combustion/en.
RENEWABLES 2021 GLOBAL STATUS REPORT
Renewable electricity supplies heat to buildings in various ways,
notably through electric radiators or highly efficient electric heat
pumps. Major global markets for electric heat pumps in China,
Japan, Europe and the United States grew in 2020, continuing
a multi-year acceleration.122 Government policy related to heat
pumps also is expanding, with several countries setting targets
for installations of the technology while also pledging to increase
their renewable power capacities.123
Total electrification of heating is garnering increasing policy attention
as well. In 2020, electrification of heat was prominently pursued in
the United States, continuing a trend from 2019.124 US states such
as Colorado, Maine, Michigan, Nevada and New Jersey released
plans to address climate change that targeted “all-electric” buildings,
mandated heat pump installations and/or cited electric heating as
a way to achieve their climate goals.125 In Australia, the Australian
Capital Territory committed to supporting numerous all-electric
residential and business developments, some of which included the
choice to participate in community solar projects.126
During the year, attention grew on the use of hydrogen for
heating buildings. Communities in Canada and the United
Kingdom announced pilot projects to blend hydrogen with fossil
gas in gas distribution networks to provide heat to buildings.127 As
part of its Hydrogen Strategy, the EU is conducting pilot projects
to analyse the potential to replace fossil gas boilers with hydrogen
boilers.128 At the same time, numerous studies from research
organisations and think tanks found that using hydrogen for home
heating could be less energy efficient and more cost intensive
than electrification, most notably with electric heat pumps.129
Moreover, in early 2021 a coalition spanning businesses and civil
society organisations sent a letter to the European Commission
asking it to prioritise renewables and energy efficiency over
hydrogen for building heat.130
District energy networks can efficiently meet urban heating
and cooling needs; however, these systems currently account for
just 6.7% of heat demand in buildings.131 Moreover, the low global
share of renewable energy in these networks (5.6%) means that
only 0.4% of the world’s heat demand in buildings was met by
renewables in district networks in 2018.132 Nevertheless, some
European countries have achieved relatively high shares of
renewables in the district heat supply (more than 50%i in at least
six countries in recent yearsii).133 In 2020, solar thermal systems
for district heating were brought online in China, Denmark and
Germany, and these markets have continued to grow.134
The use of traditional biomass for cooking – predominantly in
open fires or inefficient indoor stoves – leads to significant health
problems, particularly in developing and emerging economies.135
In these countries, the use of gaseous fuelsiii reached 37% of the
population in 2019 (compared to 35% for the traditional use of
biomass).136 At the same time, the share of electricity for cooking
rose to 10% in 2019; due to its use mostly in urban areas, the
use of renewable electricity for cooking is dependent on the
overall renewable share
in national power grids.137
Use of solar energy for
cooking is also rising:
by early 2021, more
than 14 million people
had benefited from the
4 million solar cookers
that had been distributed
around the world.138
Electricity is the fastest
growing energy source in buildings, with demand up 2.2% annually
between 2009 and 2019.139 Renewable electricity is delivered to
buildings both from centralised plants by the electricity grid, and
by distributed systems, depending on the location.140 Although
the penetration of distributed systems is growing, the global
contribution of renewables to electricity demand in buildings is
largely dependent on the prevailing local electricity mix in the
grid.141 In 2020, the renewable share of electricity production
was around 29%, up from 20% in 2010.142 (p See Power section
in this chapter.)
Distributed renewables also provide electricity access to
growing shares of the population in developing and emerging
economies.143 As of mid-2020, more than 100 million people had
gained access to basic residential electricity services through the
use of solar lighting and solar home systems alone.144 In addition,
as of March 2020, 87% of operational mini-grids were providing
renewables-based electricity access, with solar PV as the fastest
growing technology for mini-grids.145
Policy attention to stimulate renewable energy uptake in
buildings is lacking on a global scale, particularly related to
heating end-uses.146 New or updated financial incentives in 2020
were introduced only in Europe, and included the Netherlands’
incentive scheme that was expanded to include renewable heat
and the United Kingdom’s extension of its funding programme
to retrofit buildings with renewables-based heating systems.147
At the city level, policy trends for buildings include energy codes
that mandate the use of renewables for heating (or electricity).148
Such codes typically apply to new buildings, while renewables
for existing buildings often are encouraged through financial and
fiscal incentives.149
An enabling policy measure becoming increasingly prevalent is
bans and restrictions on some types of fossil fuels in new and
existing buildings. Examples of this trend are present in more than
50 cities in 10 countries (and at least 7 national governments).150
Numerous cities in Asia, North America (especially the US state
of California), Europe and Oceania have introduced policies to
phase out the use of fossil fuels for space and water heating in
new and/or existing buildings.151 Policies subsidising the use of
fossil fuels for heating continue to exist and clash with those that
encourage the uptake of renewables.152
Policies
subsidising the
use of fossil fuels
for heating continue
to clash with those that
encourage the uptake of
renewables.
44
https://www.who.int/airpollution/guidelines/household-fuel-combustion/en
i Various definitions have emerged of buildings that achieve high levels of energy efficiency and meet remaining energy demand with either on- or off-site
renewable energy. See endnote 156 for this chapter.
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Efforts to restrict use of fossil fuels (mostly fossil gas) for heating
have met heavy resistance from the incumbent industry in many
regions, notably in the United Kingdom, the EU and the United
States.153 In the United States, fossil gas companies and industry
associations launched public relations campaigns and spent
millions of dollars in 2020 attempting to sway public opinion
against electrification.154 In the state of California, a consumer
protection agency recommended that the largest US fossil gas
utility pay USD 255 million in fines after misusing public funds to
oppose local fossil gas bans.155
The emergence of targets towards achieving net zero emissions,
as well as rising interest in net and nearly zero energy
buildingsi, also are spurring increased use of renewables in
buildings.156 In late 2020, 18 new signatories signed the Net Zero
Carbon Buildings Commitment to bring the total to 6 states and
regions, 28 cities, and 98 businesses and organisations that
had agreed to achieve net zero emissions in their operations
by 2030.157 Beginning in 2021, the EU’s Energy Performance in
Buildings Directive mandated that all new public buildings in the
region be “nearly zero energy buildings”.
In addition to improving the performance of new buildings,
addressing the existing building stock is expected to be
an important step towards meeting climate targets. The EU’s
Renovation Wave strategy, announced in 2020, aims to support
the decarbonisation of heating and cooling by strengthening
regulations, providing incentives for private financing and
introducing minimum energy performance standards, among
other objectives.158 Mandatory building performance standards
were introduced and strengthened in the United States in
2020 and early 2021.159 By the end of 2020, 67 countries had
mandatory or voluntary building energy codes at the national
level, although no new requirements for renewables in building
energy codes were introduced during the year.160
INDUSTRY
Industrial energy use accounts for around 34% of total final
energy consumption, growing at an annual rate of around 1%.161
In certain energy-intensive sub-sectors such as chemicals and
non-ferrous metals processing, the annual growth in energy
demand nears 4%.162 Around three-quarters of the energy used
in industry is for direct thermal or mechanical end-uses that
involve combustion, as well as the use of electricity to meet
thermal energy needs.163 Overall, these processes include the
generation of industrial process steam as well as drying and
refrigeration by use of thermally driven chillers. The remaining
share is for electrical end-uses, including the operation of
machinery and lighting.164 Direct energy-related industrial CO2
emissions (excluding agriculture and land use) comprise around
24% of the global total.165
The COVID-19 pandemic and related economic slowdown led
to curtailed demand for industrial output worldwide and to a
temporary reduction in industrial energy demand in 2020.166
As a result, global industrial bioenergy consumption fell 4%
for the year.167 Measures to promote the uptake of renewables
in industries received limited attention in stimulus packages
implemented in response to the pandemic. Some countries –
notably Australia, Chile, Germany, the Netherlands, Norway and
the United Kingdom – announced renewable hydrogen strategies
or investment plans to support efforts in harder-to-decarbonise
sectors including heavy industry. (p See Sidebar 5 and Table 5
in Policy Landscape chapter). By the end of 2020, only 32
countries had at least one renewable heating and cooling
policy for industry, all of them in the form of economic incentives
such as subsidies, grants, tax credits and loan schemes.
(p See Reference Table R9 in GSR 2021 Data Pack.)
45
RENEWABLES 2021 GLOBAL STATUS REPORT
The industrial sector relies heavily on fossil fuels, with renewables
accounting for only around 14.8% of total industrial energy
demand.168 Around 90% of the renewable heat in the sector is
supplied by bioenergy (mainly biomass), and mostly in industries
where biomass waste and residues are produced on-site, such
as pulp and paper, food, forestry and wood products.169 Uptake of
bioenergy also is rising in the cement industry due to increasing
use of municipal waste in China and the EU.170 Bioenergy use
for industrial heating is concentrated in countries with large
bio-based industries, such as Brazil, China, India and the United
States.171 In 2019, Brazil was the world’s largest user of bioenergy
for industrial heat, with an estimated 1.6 EJ, followed by India
(1.4 EJ) and the United States (1.3 EJ).172
Renewable electricity accounts for the second largest share (10%)
of renewable industrial heat, although it represented only 1% of
the total industrial heat consumption in 2019.173 It is used mainly
for processes such as drying, refrigeration, and packaging and
hardening for metal production.174 Solar thermal and geothermal
technologies also increasingly supply direct renewable heat for
low-temperature industrial applications (20 degrees Celsius (°C)
to 300°C), although they still accounted for less than 0.05% of
total final industrial energy use in 2018.175
As of 2020, 98% of the geothermal industrial process heat was
used in China, New Zealand, Iceland, the Russian Federation
and Hungary.176 Geothermal heat is used mainly in the food and
beverages, pulp and paper processing, and chemical extraction
industries.177 For solar thermal industrial heat, as of early 2020,
the leading countries in total installed capacity were Oman
(300 megawatts-thermal (MWth), Chile (25 MWth) and China
(24 MWth), while Mexico and India led in the number of
installations with 77 and 44 systems respectively.178 The mining
sector had the largest share of installed solar thermal capacity
(75%), followed by food and beverages (10%) and textiles (5.6%).179
Three key industrial sectors that have low-temperature process
heat requirements, and where renewable energy is used, are
pulp and paper, food and beverages, and mining. The pulp
and paper industry uses the highest share of renewables in
industrial process heat, with bioenergy and other renewable
fuels accounting for 30% of the sector’s total energy use.180
This industry is located mainly in North America, Europe, East
Asia and Brazil.181 In particular, renewable energy provides low-
temperature heat for chemical pulping, the predominant mode
of paper production.182 In 2020, Navigator Company (Portugal)
invested EUR 55 million (USD 68 million) in a new biomass
boiler plant at its pulp and paper complex in the city of Figueira
da Foz.183 Renewables also provide electricity for producing
paper through mechanical pulping.184 In Eastern Croatia, a
paper mill operated by sustainable packaging company DS
Smith announced in 2020 that it was shifting to renewable
electricity to power its paper-making process.185
The food and tobacco industry ranks second, with renewables
supplying more than a quarter of the energy supply for industrial
process heat.186 Here, the renewable heat is supplied by heat
pumps, solar thermal heat and electric heating.187 In Cyprus, a solar
thermal system designed for continuous operation was installed
at a Kean Juices facility as part of a demonstration project in
mid-2020.188 Renewable electrification also was a popular option
during the year. McCain Foods (Australia) began building an
8.2 MW renewable energy system at its food processing facility
in Ballarat using a combination of ground-mounted solar PV
and a co-generation anaerobic digester that uses food waste to
generate energy.189 In India, SunAlpha Energy installed 12 MW of
solar PV capacity for the food processing sector and announced
plans to exceed 30 MW at facilities across the country by 2030.190
The mining industry accounts for around 6.2% of the world’s
energy consumption and 22% of global industrial CO2
emissions.191 Electricity represents 32% of the energy consumed
by mines, presenting an opportunity for direct use of renewable
power.192 However, renewables comprise less than 10% of energy
consumption in the sector, a share that has been constant for
some five decades.193 This share is higher in Australia, a leading
region in the use of renewables in mining.194
Progress towards renewable electrification in mining also
continued in some regions in 2020, with several major mining
companies building on-site renewable power plants in
Australia, Chile, Saudi Arabia and South Africa.195 Additionally,
Around 90% of the
renewable heat in the
industry sector is
supplied by
bioenergy,
most of which comes from
biomass produced on-site.
46
i Renewable hydrogen is electrolytic hydrogen produced with renewable electricity.
ii Founding partners of the initiative include ACWA Power (Saudi Arabia), CWP Renewables (Australia), Envision (China), Iberdrola (Spain), Ørsted (Denmark), Snam
(Italy) and Yara (Norway).
iii Ammonia is predominantly used to produce fertilisers. It also is used as a refrigerant gas and for purification of water supplies, as well as in the manufacture of
household and industrial-strength cleaning products, plastics, explosives, textiles, pesticides, dyes and other chemicals. There has been growing interest in
ammonia as a transport fuel.
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Australia-based iron ore mining giant Fortescue Metals
announced plans to build over 235 GW of renewable capacity to
become a supplier of renewable power and hydrogen while also
decarbonising its own energy consumption.196
In more energy-intensive industries, renewables face limitations
in meeting the requirements for high-temperature process heat
(> 400°C). Three heavy industries in particular – chemicals,
iron and steel, and cement – require vast quantities of energy,
together accounting for 60% of industrial energy use and 70%
of industrial emissions.197 The penetration of renewables in these
heavy industries remains low, comprising less than 1% of their
combined energy demand in 2018.198 In the face of reduced
demand due to the COVID-19 crisis, both energy use and
emissions in heavy industries declined around 5% in 2020.199
Renewable hydrogeni can potentially play a key role in
decarbonising heavy industries.200 In 2020, the world’s largest
developersii of renewable hydrogen came together to form
the Green Hydrogen Catapult initiative, aiming to greatly
reduce costs to stimulate a more rapid energy transition in the
most carbon-intensive industries.201 Government support for
renewable hydrogen increased during the year, and by year’s
end at least 10 countries globally had adopted some kind of
renewable hydrogen support policy. (p See Sidebar 5 and Table 5
in Policy Landscape chapter.)
The chemicals and petrochemicals industry is the largest
industrial energy user worldwide, consuming 46.8 EJ in 2017
and producing 5% of total global energy- and process-related
CO2 emissions.202 Only 3% of the industry’s energy demand
comes from renewables.203 Energy in this industry is used as
feedstock (primarily oil, natural gas, and coal) and for providing
high-temperature process heat (close to 1,000°C).204 Renewables
could meet this energy demand in two main ways: using biomass
to replace fossil fuels as a feedstock, and using renewable
hydrogen for process heat or as a feedstock.205
Some companies already have begun using renewable hydrogen
for these purposes. In late 2020, in Western Australia, YARA and
Engine formed a partnership to develop a renewable hydrogen
project to provide feedstock for ammoniaiii production.206
Also during the year, BioMCM and four partners won an EUR
11 million (USD 13.5 million) European grant for a renewable
hydrogen project based in the Netherlands to produce renewable
methanol.207 Additionally, BioBTX, an innovative technology
that converts biomass into chemicals, secured financing to
operationalise its first commercial plant by 2023.208
The iron and steel industry consumed 32 EJ of energy in 2017
and contributed 8% of total global energy- and process-related
CO2 emissions, making it the largest emitter among heavy
industries.209 Renewables accounted for only 4% of the industry’s
energy consumption in 2017.210 Nearly three-quarters (almost 72%)
of global steel is produced via the blast furnace / basic oxygen
furnace (BF-BOF) route,
using metallurgical coal
as the chemical reducing
agent, where the potential
for renewables use is
limited.211
However, the remaining
production occurs mostly
through direct reduction
of iron ore or scrap
steel using electric arc
furnaces, where renewable penetration is possible if renewable
hydrogen is used as the reducing agent and renewables are used
to power the furnaces.212
The “green steel” concept received considerable attention from
industry players in 2020, mainly in Europe.213 Sweden’s HYBRIT
green steel venture, which aims to replace coking coal with
fossil-free electricity and hydrogen, began operations at its pilot
plant.214 LKAB, one of the partners in the HYBRIT initiative, also
became the world’s first producer of fossil-free iron ore pellets
during the year.215 Another Swedish start-up, H2 Green Steel,
drew significant investments to build the world’s largest hydrogen
electrolyser to produce green steel starting in 2024.216 Germany’s
largest steelmaker, Thyssenkrupp, announced plans to build
a direct reduced iron plant running on renewable hydrogen
by 2025.217
The cement and lime industry consumed 15.6 EJ of energy
in 2017 and accounted for 6.7% of total global energy- and
process-related CO2 emissions.218 However, the bulk of the
CO2 emissions in this industry are not energy-related but are
a by-product of the chemical process used to produce clinker,
the main constituent of cement.219 Remaining emissions come
mainly from the combustion of fossil fuels to supply process heat
for this reaction. The only feasible entry point for renewables in
this industry is through fuel switching for process energy from
coal to biomass, waste fuels, renewable hydrogen or direct
electrification.220 By 2017, renewables accounted for around 6%
of energy use in the cement and lime sector, the largest share of
renewables among heavy industries.221
Regional and global cement industry associations around the
world announced carbon neutrality targets and roadmaps
in 2020, outlining the role of renewable heat, electricity and
renewable hydrogen, notably in the Dominican Republic, Europe
and the United Kingdom.222 Additionally, the Mineral Products
Association secured a GBP 6 million (USD 8.2 million) grant from
the UK government to conduct fuel switching trials into hydrogen,
biomass and plasma technology to decarbonise cement and lime
production.223 In February 2021, Hanson UK installed a renewable
hydrogen demo unit at its cement facility in Wales to partially
replace natural gas in the kiln combustion system.224
By the end of 2020,
at least 10 countries
had adopted a
renewable
hydrogen
support policies.
47
i At the same time, the carbon intensity of transport (i.e., the CO2 emitted per vehicle-kilometre) has improved in many countries due mainly to the implementation
of fuel economy or emission standards for light-duty vehicles. (p See Transport section in Energy Efficiency chapter.)
ii Transport CO2 emissions increased 19% between 2008 and 2018, at an average annual rate of 1.8%. Emissions from SUVs alone tripled between 2010 and 2020
due to the increasing number and larger sizes relative to other passenger vehicles. The sector as a whole accounted for nearly one-quarter of global energy-
related greenhouse gas emissions in 2018 (latest available data). While emissions from transport decreased an estimated 15% in 2020 due to the pandemic, they
are expected to rebound. See endnote 240 for this chapter.
iii See Glossary.
iv This section concentrates on biofuel production, rather than use, because available production data are more consistent and up-to-date. Global production
and use are very similar, and much of the world’s biofuel is used in the countries where it is produced, although significant export/import flows do exist,
particularly for biodiesel.
v HVO is hydrotreated vegetable oil and HEFA is hydrogenated esters of fatty acids. These fuels often are described as renewable diesel, especially in North
America. See Bioenergy section in Market and Industry chapter.
RENEWABLES 2021 GLOBAL STATUS REPORT
TRANSPORT
For the transport sector, the year 2020 was marked by impacts
from COVID-19, which also had an impact on the use of
renewable energy in the sector. Transport activity and energy
demand fell sharply early in the year as lockdowns were put in
place, while sales and use of both standard and electric bikes
rose dramatically in many places as hundreds of emergency
measures were implemented to support cycling and walking
infrastructure.225 Aviation saw a 60% drop in traffic during the
year, rail demand fell by up to an estimated 30%, and maritime
trade declined an estimated 4.1%.226 Public transport demand
dropped in 2020 and remained low in many countries as of early
2021 due to fears of COVID-19 contagion from being on crowded
buses or trains, while people turned to private vehicles and
non-motorised or “active” transport (e.g., walking and cycling)
in some areas.227
While EV sales increased around 41% during 2020, global
passenger vehicle sales plummeted 14%.228 The number of
electric and plug-in hybrid passenger cars on the road surpassed
10 million in 2020, while the number of e-buses increased to
600,000, and electric two-/three-wheelers totalled around
290 million.229 Although sport utility vehicle (SUV) sales decreased,
SUVs were the only area globally across all sectors – even
beyond transport – to see their emissions increase in 2020 due
to their much higher average fuel consumption, their continued
growth in popularity and the fact that in most cases they are
not electric.230
The transport sector accounts for around 60% of global oil
demand, which dropped sharply in 2020.231 While oil demand
in transport fell an estimated 8.8% during the year, it had
nearly rebounded to pre-pandemic levels by mid-2021, and
longer-term trends have shown that the growth in energy
demand for transport has far outpaced other sectors.232
Energy use for transport accounted for around one-third (32%)
of total final energy consumption globally in 2018.233 Road
transport represented the bulk of the sector’s energy demand
(74%), followed by aviation (12%), maritime transport (9.6%) and
rail (2%).234 Transport remains the sector with the lowest share
of renewable energy: in 2018, the vast majority (95.8%) of global
transport energy needs were met by oil and petroleum products
(including 0.8% non-renewable electricity), with small shares met
by biofuels (3.1%) and renewable electricity (0.3%).235
Despite continued gains in energy efficiency, particularly in road
transport, global energy demandi in the transport sector increased
2.2% annually on average between 2008 and 2018.236 This was
due mostly to the growing number and size of vehicles on the
world’s roads (and increases in tonne-kilometres and passenger-
kilometres travelled), to a reduction in average passenger-
kilometres travelled per person for buses, and to a lesser extent
to rising air transport.237 Passenger transport activity increased
74% between 2000 and 2015, almost entirely in developing and
emerging countries, while surface freight (road and rail) activity
increased 40% during this period.238 However, while passenger
transport energy intensity fell 27%, road freight transport energy
intensity declined only 5% during these years.239
Because nearly all of the increases in energy demand in transport
have been met by fossil fuels, the result has been a general
trend of risingii greenhouse gas emissions from the transport
sector across all modes except rail, which remains the most
highly electrified sub-sector.240 Nearly three-quarters (74%) of all
transport emissions are from road vehicles, 12% from aviation,
11% from maritime shipping and 1% from rail.241
Renewables can meet energy needs in the transport sector
through the use of biofuels in pure (100%) form or blended
with conventional fuels in internal combustion engine vehicles;
biomethane in natural gas vehicles; and renewable electricity
in battery electriciii and plug-in hybrid vehicles, and converted
to renewable hydrogen through electrolysis for use in fuel cell
vehicles, or used to produce synthetic fuels and electro-fuels.242
Following a decade of steady growth, biofuels productioniv fell
5% in 2020 due to the overall decline in transport energy demand
during the year.243 Nevertheless, they remained by far the largest
contributor of renewable energy to the transport sector. Ethanol
volumes fell significantly during the year (down 8%), while
biodiesel production and use was much less affected.244 At the
same time, production of HVO and HEFA fuelsv grew sharply.245
(p See Bioenergy section in Market and Industry chapter.)
In contrast, the share of renewable electricity in the
transport sector remained stable compared to 2019.246 Greater
electrification of transport can help to dramatically reduce CO2
emissions in the sector, particularly in countries that are reaching
high renewable shares in their electricity mix.247 EVs also offer
the potential for significant final energy savings, as they are
inherently more efficient than comparable internal combustion
engine vehicles.248 Investments in charging infrastructure
can further enable the electrification of transport, with some
infrastructure relying on 100% renewable electricity.249 (p See
Systems Integration chapter.)
Some regions, particularly China, Japan and the Republic of Korea,
also saw increases in the fuel cell electric vehicle market, and in
48
i Almost all hydrogen production globally is from fossil fuels.
ii These actions seek to address broader concerns among policy makers in the transport sector at the national and sub-national levels, such as environmental and
health impacts (e.g., congestion, pollution, road safety), transport security and equity in access to mobility.
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the use of or investment in renewable hydrogeni and synthetic
fuels for transport, but these remained relatively minimal.250
(p See Box 1 and Table 5 in Policy Landscape chapter.)
Overall, the transport sector is not on track to meet global
climate targets for 2030 and 2050.251 The majority of countries
worldwide have acknowledged the transport sector’s role in
mitigating emissions by including transport in their NDCs under
the Paris Agreement.252 However, just 10% of the NDCs as of
2020 included measures for renewables-based transport.253
Many countries still lack a holistic strategy for decarbonising
transport, although cities often are well placed to take more
comprehensive action – and many are already doing so.254 Such
strategies include reducing the overall demand for transport;
transitioning to more efficient transport modes, such as
(renewables-based) public transport and rail or non-motorised/
active transport (e.g., walking and cycling); and improving vehicle
technology and fuels, such as through higher fuel efficiencies
and emission standards along with greater incorporation of
renewables. Together, these strategies – commonly referred to
as Avoid-Shift-Improveii – can greatly decrease energy demand
and associated greenhouse gas emissions in the sector and
thus allow for the renewable share in transport to increase.255
TRENDS BY TRANSPORT MODE
Road transport accounted for around 75% of global transport
energy use in 2019, with passenger transport representing about
two-thirds of this.256 Biofuels continue to comprise nearly all
(91%) of the renewable energy share in road transport energy
use.257 By the end of 2020, at least 65 countries had blending
mandates for conventional biofuels (a number unchanged since
2017), and several countries with existing mandates strengthened
them or added new targets; at least 17 countries had mandates or
incentive programmes for advanced biofuels.258
Although rarely linked directly to renewable sources, the use
of electric vehicles continued to expand during the year. EVs
became more commonplace in more countries, often as a result
of policies and targets adopted in prior years.259 Global electric
car sales remained strong despite the COVID-19 crisis, due in
part to support policies and falling costs; however, the overall
share of electricity in the transport sector remains low and has
increased little in recent years.260
Only limited examples exist of direct policy linkages between EVs
and renewable electricity. During 2020, one additional country
adopted an e-mobility policy directly linked to renewables,
bringing the total to three countries globally with such policies
(Austria, Germany and Japan).261 Nevertheless, at least 9 states/
provinces, 33 countries, and the EU had independent targets
both for EVs and for renewable power generation, which could
facilitate greater use of renewables in transport.262
Policies restricting the use of fossil fuels can help increase renewable
energy shares in the sector. By early 2021, at least 19 jurisdictions
(national and state/provincial) had committed to banning sales of
new fossil fuel vehicles or internal combustion engine vehicles in
favour of lower-emission alternatives (sometimes explicitly EVs) by
2050 or before, up from 17 jurisdictions a year before.263 At least
6 cities had adopted such bans, while at least 225 cities had
already partially restricted the circulation of fossil fuel vehicles
through the use of low-emission zones.264
Overall, the
transport
sector is not
on track
to meet global climate
targets for 2030 and 2050.
49
i This trend also continued in some new mobility service companies, including micro-mobility services such as electric sidewalk/“kick” scooters and dockless bicycles
(both electric and traditional), as well as electric moped-style scooters and ridehailing and car-sharing services. (p See Box 2 in GSR 2020 Global Overview chapter.)
ii EVs could ease the integration of variable renewable energy provided that market and policy settings ensure the effective harmonisation of battery charging
patterns and/or hydrogen production with the requirements of the electricity system.
iii Vehicle-to-grid (V2G) is a system in which EVs – whether battery electric or plug-in hybrid – communicate with the grid in order to sell demand response services
by returning electricity from the vehicles to the electric grid or by altering their rate of charging.
iv Heavy-duty vehicles are the fastest growing source of oil demand worldwide and the fastest growing emitter of CO2 emissions. Even though they account for less
than a quarter of total freight activity, they account for three-quarters of the energy demand and CO2 emissions from freight. See endnote 240 for this chapter.
v Also called renewable natural gas or RNG.
vi Also called liquefied biomethane or bio-LNG.
vii The transport of goods or people via sea routes, including inland and coastal shipping.
RENEWABLES 2021 GLOBAL STATUS REPORT
Partly in response to these and other policy developments, an
increasing number of private companies have begun increasing
the use of renewables in their fleetsi. (p See Transport section
in Feature chapter and Box 2 in GSR 2020 Policy Landscape
chapter.) An increasing number of auto manufacturers also
committed to moving away from fossil fuel-powered vehicles
during the year, including General Motors, Nissan and Ford,
while Volvo and Daimler announced a new joint venture aimed
at developing, producing and commercialising hydrogen fuel
cells for the heavy-duty vehicle industry.265
Although many challenges remain for scaling up EVs, further
electrification of road transport has the potential to ease the
integration of solar PV and wind power by providing balancing
and flexibility services to the gridii.266 Vehicle-to-grid (V2G)iii is
still relatively in its infancy, but during 2020 more companies
invested in the technology and numerous new projects
continued to be launched.267 For example, ENGIE and Fiat-
Chrysler began construction on the world’s largest V2G project
in Turin, Italy to provide 25 MW of renewable energy storage
using batteries from 700 EVs.268
Road freight consumes around half of all diesel fuel and is
responsible for 80% of the global net increase in diesel use since
2000, with the increase in road freight activity having offset any
efficiency gains.269 Fuel economy standards push manufacturers
to seek to improve fuel efficiency and facilitate the adoption of
alternative drivetrains based on low-carbon solutions, including
renewable energy.270 Although fuel economy standards apply
to 80% of light-duty vehicles globally, only five countries apply
them to heavy-duty vehicles – Canada, China, India, Japan and
the United States – covering just over half of the global road
freight market.271 Moreover, no new countries have adopted such
standards since 2017iv. In 2019, the EU adopted the first-ever CO2
emission standards for heavy-duty vehicles.272
The larger the vehicles and the longer the range, the more
challenging it is to find cost-effective alternatives to diesel.273
However, both public and private entities have supported
renewable alternatives. In 2020, the US state of California became
the first jurisdiction worldwide to require truck manufacturers to
transition from diesel trucks and vans to “near-zero-emission
vehicles”, such as electric or biomethanev vehicles.274 Finnish
state-owned gas company Gasum expanded its liquefied biogas
(LBG)vi filling station network in Finland, Sweden and Norway.275
In the private sector, Volvo Trucks (Sweden) reported seeing
increased interest in LBG during the year, while Finnish freight
firm Posti increased investment in LBG trucks.276
A few local governments
and companies are using
renewable energy in their
bus fleets. While many
cities have been using
biofuels in buses for
some time, an increasing
number are linking
renewable electricity to
e-bus charging (such as
charging the buses with
solar power), notably in
Europe, the United States and China.277 Many more cities are
running public urban rail systems on electricity, sometimes
directly linked to renewable electricity and in other cases using
biofuels.278 By the end of 2020, just two countries (France and
India) had enacted new policies and targets to advance the use
of renewables in the rail sector.279
As the most highly electrified transport sector, rail transport
accounts for around 2% of the total energy used in transport.280
Renewables contribute an estimated 11% of global rail-related
energy consumption.281 Some jurisdictions have increased the
share of renewable energy in rail transport to well above its share
in their power sectors.282 In 2020, at least two railway companies
set net zero targets: Indian Railways for 2030 and UK-based
Network Rail for 2050.283
Maritime transportvii consumes around 10% of the global energy
used in transport – with around 0.1% estimated to be renewable
– and is responsible for around 2.9% of global greenhouse gas
emissions.284 Although renewables do not feature significantly
in the maritime fuel mix, some advances occurred during 2020.
The Netherlands was the only country to advance the use
of renewable energy in shipping, announcing plans obliging
suppliers of heavy fuel oil and diesel for inland shipping to take
part in its renewable fuel scheme.285
At the international level, the International Chamber of Shipping
(the global shipping trade association) announced plans to invest
USD 5 billion in research and development related to alternative
fuels, with a goal of reducing the sector’s greenhouse gas
emissions 50% by 2050 (from 2008 levels).286 Also, stricter energy
efficiency targets and new fuel and emission standards adopted
by the International Maritime Organization in 2019 began being
implemented in 2020, and the organisation set goals with the
Global Industry Alliance to reduce emissions in the ship-port
interface.287
The overall share of
electricity in the
transport sector
remains low and has
increased little in recent
years.
50
i Representing 97.4% of global air traffic, up from 94.3% a year earlier.
ii The International Civil Aviation Organization (ICAO) considers such fuels to be a sustainable alternative when they are produced from three families of bio-feeds-
tock: the family of oils and fats, or triglicerides, the family of sugars and the family of lignocellulosic feedstock. See ICAO, “Alternative fuels: Questions and answers”,
https://www.icao.int/environmentalprotection/Pages/AltFuel-SustainableAltFuels.aspx, viewed 14 April 2021.
iii Drop-in biofuels are produced from biomass, including different types of organic waste, and have properties enabling them to replace fossil fuels directly in trans-
port systems, or to be blended at high levels with fossil fuels.
iv Using solar power for air conditioning and other services while a plane is at the airport gate.
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In addition to the use of biofuels and other renewable-based fuels
for propulsion, maritime transport has the possibility to directly
incorporate wind power (via sails) and solar energy.288 Some
fleets already have moved to 100% renewable fuels, while others
have moved to hybrid systems with energy storage (although not
always operating on renewable energy).289 In 2020, Finnish firms
began testing LBG as a shipping fuel.290 By early 2020, trials also
had begun on the use of ammonia as a shipping fuel, with the
potential to produce it using renewable electricity.291 By year’s end,
discussions had begun on using green hydrogen in ferries and
short-distance shipping.292 At a smaller scale, electric outboard
engines increasingly are being used in many markets and can
be charged directly with renewable energy; some governments,
such as Sweden, have offered incentives for electric models.293
By early 2021, at least one new port (Valenciaport, Spain) had
joined the World Ports Climate Action Program, bringing the
membership to 12 ports committed to advancing reductions in
maritime transport emissions in support of the Paris Agreement.294
In 2020, Valenciaport committed to building 8.5 MW of solar PV
at two of its ports on Spain’s coast for its own operations.295
Also during the year, Portugal and the Netherlands signed a
memorandum of understanding to connect Portugal’s renewable
hydrogen project with the Dutch Port of Rotterdam.296
Aviation accounts for around 12% of the total energy used in
transport – less than 0.1% of which is renewable – and for around
2% of global greenhouse gas emissions.297 Despite the more
than 50% decrease in carbon emissions per passenger-kilometre
between 1990 and 2019 (due to fuel efficiency improvements),
global demand for air travel increased significantly leading up
to 2020, with emissions growing more rapidly than expected.298
However, air travel plummeted with the onset of the pandemic.299
Support for and use of renewable fuels in the aviation sector
made slight progress during 2020. Belarus, Ethiopia and Qatar
submitted voluntary State Action Plans to the International
Civil Aviation Organization, bringing to 120 the total number of
member statesi supporting the production and use of “sustainable
alternative”ii aviation fuels, specifically drop-in fuelsiii.300
Meanwhile, as of early 2021, more than 315,000 commercial
flights had flown on blends of alternative fuels, up from 200,000
a year before.301 However, this is still a negligible share of the tens
of millions of flights performed each year.302 At least 9 airports
had regular distribution of blended alternative fuel, up from 8 the
year before, while at least 13 airports had batch deliveries of such
fuels.303 During 2020, as in the previous year, some companies
announced targets for their own aircraft to run on biofuels and
were developing planes made specifically to do this.304
Although interest in the electrification of aviation is increasing,
as of May 2021 only electric drones or small planes had been
developed. Some companies were planning fully electric airlines
to carry more than 120 passengers, while others have aimed
for hydrogen-powered electric planes.305 A few “solar at gate”iv
pilot projects have been developed in recent years in Cameroon,
Jamaica and Kenya, although none were added in 2020.306
Several airports announced during the year that their operations
would be partly powered by solar power, including at all airports
in Ghana, three French airports and major airports in the cities of
Edmonton (Canada), Melbourne (Australia) and New York (US).307
51
https://www.icao.int/environmentalprotection/Pages/AltFuel-SustainableAltFuels.aspx
i For consistency, the GSR endeavours to report all solar PV capacity data in direct current (DC). See endnotes and Methodological Notes for further details.
RENEWABLES 2021 GLOBAL STATUS REPORT
POWER
The renewable power sector experienced a turbulent first half of
2020 during the onset of the COVID-19 pandemic. Supply chain
disruptions, restrictions on the movement of labour and goods,
postponed or cancelled auctions, and other factors led to levels
of new additions and investment that were markedly lower than
in the same period in 2019.308 Pandemic-related restrictions led to
project developers facing significant labour shortages and delays
in the supply chain as they rushed to complete projects on time.309
However, the solar PV and wind power sectors rebounded in the
second half of 2020, and by year’s end these two technologies
each had installed a record amount of new capacity, steering
the renewable power sector to an all-time high of more than
256 GW of added capacity.310 Worldwide, total installed renewable
power capacity grew almost 10% to reach 2,839 GW.311 (p See
Figure 7 and Reference Table R1 in GSR 2021 Data Pack.)
Continuing a trend going back to 2012, most of the newly installed
power capacity in 2020 was renewable. Even as the fossil fuel and
nuclear power sectors struggled, renewables reached 83% of net
power capacity additions.312 (p See Figure 8.) As in recent years,
solar PV and wind power made up the bulk of new renewable power
additions. Around 139 GW of solar PVi was added, comprising more
than half of the renewable additions, while 93 GW of installed wind
power capacity made up some 36%.313 Almost 20 GW of hydropower
capacity was brought online, and the remaining additions were from
bio-power, with ocean, geothermal and concentrating solar thermal
power (CSP) adding only marginal net capacity.314
Once again, China led in capacity added during the year,
accounting for almost half of new installations and leading global
markets for bio-power, CSP, hydropower, solar PV and wind
power.315 With more than 116 GW added, China brought online
more capacity in 2020 than the entire world did in 2013, and it
nearly doubled its own additions of the previous year.316 Countries
FIGURE 7.
Annual Additions of Renewable Power Capacity, by Technology and Total, 2014-2020
Note: Solar PV capacity data are provided in direct current (DC). Data are not comparable against technology contributions to electricity generation.
Source: See endnote 311 for this chapter.
Additions by technology (Gigawatts)
120
60
90
30
150
Bio-power,
geothermal,
ocean power,
CSP
Hydropower
Wind power
Solar PV
201620152014 2017 2018 2019 2020
More than
256
gigawatts added
in 2020
0
52
i In 2010, China, India, Germany, Spain and the United States exceeded 10 GW of non-hydro renewable power capacity. As of 2020, Australia, Brazil, Canada,
Italy, France, Japan, the Republic of Korea, Mexico, the Netherlands, Poland, Sweden, Turkey, the United Kingdom and Vietnam also joined this list.
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outside of China added around 140 GW of capacity, up around
5% from 2019 and led by the United States (36 GW) and Vietnam
(11 GW).317 China also remained the global leader in cumulative
renewable energy capacity (908 GW) at year’s end, followed by
the United States (313 GW), Brazil (150 GW), India (142 GW) and
Germany (132 GW).318 (p See Table 2.)
By the end of 2020, at least 34 countries had more than 10 GW
of renewable power capacity in operation, up from 20 countries
in 2010.319 The shift is even more impressive when excluding
hydropower, as markets for both solar PV and wind power have
grown dramatically in recent years. At least 19 countries had
more than 10 GW of non-hydropower renewable capacity at the
end of 2020, up from 5 countriesi in 2010.320
The top countries for non-hydro renewable power capacity per
person were unchanged from previous years: Iceland, Denmark,
Sweden, Germany and Australia.321 (p See Reference Table R2
in GSR 2021 Data Pack.)
Driven by government policy and low costs, major markets for
leading renewable energy technologies withstood the worst
effects of the economic shocks in 2020. During the second half of the
year, activity accelerated dramatically as developers sought to make
up for delays and to take advantage of expiring incentives in Vietnam
and the United States as well as expiring subsidies in China, which led
to an installation rush (particularly for solar PV and wind power but also
for hydropower).322 In solar PV markets, rapid growth in rooftop solar
projects compensated for a smaller increase in the utility-scale market,
while growth in the wind power sector rose sharply in the second half
of the year, driven mainly by onshore wind installations in China.323
The global offshore market was stagnant compared to 2019.324
The global market for hydropower, still the leading technology in
renewable electricity generation, grew significantly (24%) in 2020
due to the commissioning of several large projects in China.325
CSP and geothermal power markets both declined during the
year, with only a handful of countries accounting for most of the
FIGURE 8.
Shares of Net Annual Additions in Power Generating Capacity, 2010-2020
Source: See endnote 312 for this chapter.
0%
50%
100%
Share in Additions to Global Power Capacity
Non-renewable share
Renewable share
20102010 2011 2013 2015 20172012 2014 2016 20192018 2020
83%
renewables in
net additions
53
RENEWABLES 2021 GLOBAL STATUS REPORT
new installations.326 Ocean power was still disadvantaged by a
lack of policy support and of sufficient technological innovation to
reduce costs significantly; however, the EU passed a new target
for 1 GW of ocean power by 2030 and 40 GW by 2050.327
Auctions and tenders for renewable power have become
one of the most common market support mechanisms for new
projects.328 In the first half of 2020, 13 countries awarded nearly
50 GW in new capacity, breaking a record for auctioned capacity.329
The total number of countries that held renewable power auctions
decreased during the year (from 41 to at least 33), but several new
countries held auctions for the first time.330 In some markets, the
shift to auctions also has reduced the diversity of participants,
notably the involvement of community energy groups.331
Alongside significant and ongoing cost reductions in solar PV
and wind power, the growth of auctions has created a highly
competitive bidding environment that has placed strong
downward pressure on price levels for renewable power projects.
In 2020, developers around the world continued to submit bids
for tenders at record-low prices for utility-scale solar PV and wind
power.332 However, low bid prices in tendering processes do not
necessarily reflect overall costs, as prices depend on resource
availability, local labour and land prices and costs of financing,
while tendering conditions might include the provision of grid
connection to developers, among other incentives.333
The amount of renewable electricity from power purchase
agreements has grown substantially in recent years, with a record
23.7 GW sourced from corporate PPAs in 2020.334 The United
States remained the world’s leading market for corporate PPAs
despite declining 16%,
while the record additions
were driven by a combined
tripling in Europe, the
Middle East and Africa.335
US companies that
successfully closed PPAs
in the United States have
shown growing interest in
expanding their efforts to
Europe.336
In early 2020, global electricity demand dropped sharply
in the wake of the COVID-19 pandemic.337 However, demand
rebounded by year’s end, resulting overall in a slight decline of
around 2%, the first annual decline since the global economic
crisis of 2008/2009.338 Production of electricity from renewables
was favoured under these low-demand circumstances due to
its inherent low operating costs, as well as the dispatch rules in
many countries that prioritise renewable electricity.339
Each year for the past decade, renewables have met a higher
share of global electricity demand than in the previous year.340
This trend accelerated in 2020 amid the lower demand and
favourable conditions for renewable power. For the second
consecutive year, electricity production from fossil fuels was
estimated to decline, driven mainly by a 2% decrease in coal
power generation.341 Overall, renewables generated an estimated
29.0% of global electricity in 2020, up from 27.3% in 2019.342
(p See Figure 9.)
FIGURE 9.
Global Electricity Production by Source, and Share of Renewables, 2010-2020
Source: Ember. See endnote 342 for this chapter.
Electricity Production (TWh) Share of renewable electricity (%)
0 0 %
5,000
10,000
15,000
20,000
25,000
30,000
25 %
50 %
2016201520142013201220112010 2017 2018 2019 2020
Fossil fuels
Nuclear power
Hydropower
Non-hydro renewables
Share of
renewable electricity
Renewables generated
an estimated
29% of global
electricity
in 2020.
54
i Grid services include the ability to provide operating reserve, voltage support and black start capabilities. (p See Systems Integration chapter.)
ii Also known as PV-T, or photovoltaic-thermal collectors, these systems convert solar radiation into both electrical and thermal energy.
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The progress in renewable energy, and the decline in fossil fuels
(especially coal), has been especially pronounced in certain
countries and regions. Wind power, hydropower, solar power
and bioenergy became the EU-27’s main source of electricity
in 2020, growing from 30% of generation in 2015 to 38%.343
Electricity generation from these renewable sources grew 23%
as production from coal power fell by half over this period.344
Similarly, in the United Kingdom, renewables grew to a 42%
share of generation to become the main source of electricity in
2020, beating out fossil gas and coal at a combined 41%.345
In the United States, renewable energy reached nearly 20%
of net electricity generation by year’s end, with solar and wind
energy accounting for more than half of this; meanwhile, coal’s
share fell from around 24% in 2019 to less than 20% in 2020.346
More than 19% of Australia’s electricity came from wind and
solar energy in 2020, and, overall, renewable energy represented
nearly 28% of the country’s generation, up from 24% in 2019.347
In China, electricity from hydropower, solar energy and wind
energy provided more than 27% of production, up from around
26% in 2019.348
The share of electricity generated by variable renewable
electricity (wind power and solar PV) continued to rise in
several countries around the world. While variable renewables
contributed more than 9% of global electricity in 2020, in some
countries they met much higher shares of production, including
in Denmark (63%), Uruguay (43%), Ireland (38%), Germany
(33%), Greece (32%), Spain (28%), the United Kingdom (28%),
Portugal (27%) and Australia (20%).349
The cost-effective integration of variable renewable electricity
has spurred industry players and governments to make efforts
to increase the flexibility of their energy technologies and
systems. Some countries expanded or modernised transmission
infrastructure specifically to adapt their systems to rising shares
of variable renewables.350 Manufacturers of wind turbines and
solar PV modules are working to make their technologies more
flexible so that they provide servicesi to the grid, as well as
better facilitate their own integration into the energy system.351
Governments have introduced policies to support demand
flexibility measures such as time-of-use pricing, incentive
payments and penalties to influence the electricity use of
consumers.352
Hybrid systems, consisting of at least two renewable energy
technologies and/or energy storage, are able to provide
flexibility to the grid as well as to decrease costs and deliver
technical benefits (including higher capacity factors) due
to co-localisation.353 In 2020 and early 2021, hybrid projects
combining solar PV, wind and/or energy storage were
announced or commissioned in many countries, including India
where a massive 30 GW solar-wind project began construction
in Gujarat.354 Markets for hybrid solar thermal collectorsii
grew in China, France, Germany, Ghana and the Netherlands
during 2020.355
In 2020,
wind power
and solar PV
generated more than
20% of electricity in
nine countries.
55
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 2. Impacts of COVID-19 on Renewable Energy-Related Jobs in 2020
A variety of factors shape employment trends in the renewable
energy sector. They include costs and investments as well
as labour, industry and trade policies. The intensity of labour
changes as technologies mature, as the scale and complexity
of operations grow and as automation takes hold. Gender
disparities also persist in the sector, with women accounting for
less than one-third of the overall renewable energy workforce
in 2018. In addition to these factors, the COVID 19 pandemic
had unprecedented impacts on renewable energy-related
employment in 2020.
Although renewables fared better than expected compared with
conventional energy sources (in terms of new capacity additions),
the sector faced uncertainties and disruptions during the year.
Lockdowns and other restrictions on movement put pressure
on supply chains and constrained economic activity. In many
countries, project delays early in 2020 were followed by surges
of activity by year’s end, reflecting cycles of rising and falling
COVID-19 infections. The year-end surge was driven in part by
developers rushing to meet permitting deadlines (some of which
were extended in response to pandemic delays) or reacting
to impending changes in policies, such as expiring tax credits,
subsidy phase-outs or cuts in feed-in tariff rates. In a sense, the
pandemic amplified the business cycle fluctuations typically seen
in the sector.
As a result, employment in renewables fluctuated considerably
over the year. Depending on labour market policies and industry
practices in different countries, workers were furloughed, had
their work hours reduced or were laid off (and, in some cases,
rehired later). The ability of governments, companies and
industries to cope with disruptions by switching to remote
working arrangements or to comply with social distancing
requirements in the workplace differed enormously.
COVID-19’s impacts on employment also varied by renewable
energy technology, end-use sector and value chain segment.
(p See Table 3.) Disruptions in the supply of inputs and raw
materials were common. For example, the supply of balsa, a key
component of wind turbine blades, was affected by the lockdown
in Ecuador, which supplies 95% of the wood globally. As a result,
production was shifted to other countries (including Papua
New Guinea), and other materials (such as PET plastic) were
substituted – resulting in job losses in Ecuador.
TABLE 3.
COVID-19’s Impacts on Employment in Segments of the Renewable Energy Supply Chain
Source: IRENA. See endnote 38 for this chapter.
56
Value chain segment Magnitude of impact Comments
Distributed renewables for
energy access Very high
Demand affected by reduced incomes and by social
distancing requirements.
Transport and logistics High (medium term) Greatly affected by temporary parts shortages, social distancing measures, quarantines and border controls.
Construction and installation High
Strongly affected by lockdowns and delays, limits on the
numbers of workers allowed on-site and social distancing
requirements. Less impact in the second half of 2020.
Biofuels High
Drop in demand due to the decline in transport volumes
and to cheaper fossil-based diesel, but this was moderated
in some countries by increases in blending mandates.
Manufacturing and procurement High (short term) Heavy effects on factory workers, technicians and engineers due to temporary factory closures.
Operations and maintenance Low to medium
Travel to some project sites affected by border closures
and quarantine rules; however, energy generation is an
essential service and the physical space available at wind
and solar farms often allows for social distancing.
Project planning Low Many jobs can be performed remotely.
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Experience also diverged widely across countries, affecting local
employment trends. Some countries (such as China) witnessed
substantial growth in new renewable power capacity additions
in 2020, while in other countries (such as India), renewables
stagnated. However, new installations did not always translate
into job growth. For example, the United States added record
amounts of solar energy in 2020, but one survey found that
US employment in the sector dropped 6.7% during the year, to
around 231,500 workers. This could be due to a decline in labour
intensity, given that large utility-scale projects accounted for
three-quarters of new installations, as well as to fewer in-person
sales, which shifted to online marketing to comply with social
distancing requirements. By mid-2020, the US solar industry
had lost as many jobs as it had added in the past five years, due
primarily to a shift away from door-to-door sales.
Meanwhile, energy use in the transport sector collapsed in
early 2020. This affected biofuel demand in two ways: directly
through reduced demand for fuels and indirectly due to falling
crude oil prices, which made biofuels less competitive. During
the year, employment rose in biodiesel while it fell in ethanol.
In Brazil, the world’s largest biofuels employer, the increase
in the blending mandate drove biodiesel production up:
jobs in this sector climbed from 294,900 in 2019 to 323,800
in 2020. In contrast, jobs in ethanol have continued to fall as
increasing mechanisation reduces the need for manual labour
in feedstock operations, declining from an estimated 574,400
in 2018 to an estimated 547,300 in 2019.
In Indonesia, another major biodiesel producer, employment
remained virtually unchanged in 2020 at around 475,000
jobs. Although COVID-19 restrictions reduced overall diesel
fuel consumption, the government raised the biodiesel
blending mandate from 20% to 30%, substantially increasing
domestic biodiesel consumption and, thus, supporting
employment. However, the country’s exports collapsed as
a result of unfavourable prices compared to conventional
diesel and countervailing duties imposed by the European
Union in 2019.
In the off-grid power sector, COVID-19 slowed the pace of
new capacity additions and electricity access considerably in
many countries in 2020. This was especially true for sales of
off-grid solar lighting products. The finances of off-grid solar
companies were constrained due to reduced equity funding,
while reductions in income restricted households’ abilities
to afford cash purchases. (p See Distributed Renewables
chapter.) Consequently, employment in the sector suffered.
Jobs plummeted from an estimated 339,000 in 2019 to just
187,500 in 2020. COVID-19 also heavily impacted women’s
employment and livelihoods in the off-grid sector, since women
are more often employed in small businesses and segments
of the informal economy that already faced challenges to
energy access.
Source: IRENA. See endnote 38 for this chapter.
57
Since 2020, the BMW Group has used 100% renewable energy sources for its operations
globally. It also aims to increase electric vehicle sales to one-fifth of all sales by 2023.
02
02
overnment policies continue to play a crucial role
in accelerating the adoption and deployment of
renewable energy technologies, particularly in sectors
other than power generation. Policies also continue to be critical
for achieving renewable energy cost reductions and innovation.1
By the end of 2020, nearly all countries worldwide had in place
renewable energy support policies, although with varying
degrees of ambition.2 (p See Figure 10 and Table 6.) In addition,
renewable energy deployment continued to expand outside
of government policies in the form of corporate commitments
to renewables and utility-led activities. This was driven by
market-based factors such as corporate action on climate
change and the declining costs of renewable electricity.3
(p See Feature chapter.)
POLICY
LANDSCAPE
Despite the COVID-19 crisis, policy
support for renewables remained
strong throughout 2020.
Many countries were not on track to
achieve their 2020 targets, and many
had not yet set new targets for future years.
Policy related to heating and cooling
in buildings and industry remained
scarcer than policies directed at electricity
generation and transport.
EV policies became increasingly popular
in 2020, but most continued to lack a
direct link to renewable electricity.
Many jurisdictions with high shares
of variable renewable electricity
implemented policy to ensure successful
integration.
2020 saw important climate change
policy commitments in some major
markets.
K E Y FA C T S
02
G
59
i See www.ren21.net/gsr-2021.
0
30
60
90
120
150
Number of Countries
2018 20202016201420122010
145
countries
Power regulatory
incentives/
mandates
Heating and cooling
regulatory
incentives/
mandates
22
countries
65
countries
Transport regulatory
incentives/
mandates
RENEWABLES 2021 GLOBAL STATUS REPORT
The year 2020 was critical for assessing progress on renewable
energy targets. Worldwide, 165 countries had in place targets to
increase uptake of renewables in various sectors by year’s end.4
Most of these targets were for the power sector, followed by
targets for total final energy consumption, heating and cooling,
and transport. However, success in actually being on track to
meet the 2020 targets varied widely: overall, some 80 targets
were achieved, while the majority (134) were not yet achieved
according to the latest data available (ranging from 2017 to 2020).
While some countries were close to achieving their targets,
others were far from being on track. Moreover, as countries’
2020 targets were coming to term at the end of the year, as
many as 30 countries had not yet set new targets for future
years (compared to 67 that had). Many of the achieved targets
were for power, heating and cooling, and total final energy
consumption, while very few were in the transport sector.
(p See Figure 11 and Reference Tables R3-R8 in GSR 2021
Data Packi.)
Note: Figure does not show all policy types in use. In many cases countries have enacted additional fiscal incentives or public finance mechanisms to support
renewable energy. A country is considered to have a policy (and is counted a single time) when it has at least one national or state/provincial-level policy in place.
Power policies include feed-in tariffs (FITs) / feed-in premiums, tendering, net metering and renewable portfolio standards. Heating and cooling policies include
solar heat obligations, technology-neutral renewable heat obligations and renewable heat FITs. Transport policies include biodiesel obligations/mandates,
ethanol obligations/mandates and non-blend mandates. For more information, see Table 6 in this chapter and Reference Tables R8-R10 in GSR2021 Data Pack.
Source: REN21 Policy Database.
FIGURE 10.
Number of Countries with Renewable Energy Regulatory Policies, 2010–2020
60
http://www.ren21.net/gsr-2021
i See www.ren21.net/cities.
0102030 30405060Number of countries
Power
Transport
Heating
and Cooling
Total Final
Energy
Consumption
10 20 6040 50
The majority of
countries’ 2020
targets were
not yet
achieved
No later target exists
Targets already achieved Targets not yet achieved
PO
LI
CY
L
AN
DS
CA
PE
02
Note: Figure includes only countries with targets in these sectors that are for a specific share from renewable sources by a specific year, and does not include
countries with other types of targets in these sectors.
Source: REN21 Policy Database. See Reference Tables R3-6 in GSR 2021 Data Pack.
FIGURE 11.
Status of Countries in Meeting Their 2020 Renewable Energy Targets and Setting New Ones
Continuing a trend of the past decade – and despite the
COVID-19 crisis – policy support for renewables generally
remained strong throughout 2020. In some countries, economic
recovery policies and funding packages related to the pandemic
included explicit support for renewables, although, overall, far
more support was allocated to fossil fuels.5 (p See Sidebars 3
and 4.) While the global health and economic disruptions
affected the suite of renewable energy policies implemented
during the year, such measures also evolved in response to
greater action on climate change, the falling costs of renewables,
evolving grid and system integration demands, and the changing
needs and realities of different jurisdictions.
In jurisdictions with high shares of installed renewable energy,
decision makers typically focused policy development on
ensuring that support for renewables was cost effective, and
on the technical and market integration of renewables. (p See
Systems Integration section in this chapter.) In less-mature
renewable energy markets and in some developing and emerging
economies, policy efforts prioritised outcomes such as boosting
renewable energy capacity and generation to meet demand,
promoting energy security and providing increased access to
energy.6 (p See Distributed Renewables chapter.)
Policies to advance the production and use of renewables can
be targeted at any and all end-use sectors, including buildings,
industry, transport and electricity generation. Most renewable
energy policy in 2020 continued to focus on a single sector,
although at least five countries unveiled comprehensive climate
change policies that included support for renewables across
multiple sectors. Trade policy also continued to have an impact
on the production, exchange and development of renewable
energy products, as well as on the demand for renewables within
specific countries.7 (p See Box 4.)
A significant amount of renewable energy policy making
continued to occur at the municipal level. However, this chapter
covers mainly policy enacted at the regional, national and state/
provincial levels of governance. Municipal policy is discussed in
detail in the REN21 Renewables in Cities Global Status Reporti.
61
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 3. Renewable Energy in COVID-19 Stimulus Packages
In response to the COVID-19 crisis, governments around
the world announced more than USD 12 trillion in financial
stimulus, including at least USD 732.5 billion in energy-
related support. Although some stimulus packages included
incentives for renewables, as of April 2021 this comprised
only around USD 264 billion of the total amount provided by
governments globally, compared to more than USD 309 billion
in fossil fuel stimulus. (p See Figure 49 in Investment chapter.)
Direct support for coal included India’s USD 6.75 billion coal
infrastructure support package and the Republic of Korea’s
USD 2.5 billion bailout of Doosan Heavy Industries, a coal
plant manufacturer. Direct support for oil and gas included
USD 4.4 billion in loans and loan guarantees to a Canadian
pipeline and GBP 1.3 billion (USD 1.7 billion) in low-interest
loans to oil and gas companies in the United Kingdom.
Nevertheless, examples of “green recovery” efforts did emerge.
At a regional level, around 30% of the European Union’s (EU)
EUR 750 billion (USD 921 billion) COVID-19 stimulus package
was dedicated to “clean recovery” and renewables, including
renewable electricity generation, energy retrofits of buildings,
renewable heat, renewable hydrogen and electric vehicles
(EVs)i. China, India and the Republic of Korea also committed
to renewable energy investments, although those countries
also supported coal in their recovery plans. Colombia’s plan
included raising COP 16 billion (USD 4.6 million) to accelerate
27 renewable energy and related transmission projects.
In the power sector, governments provided around
USD 95 billion in response to COVID-19. This was largely to
ensure the continuation of services and to reduce consumers’
bill burdens rather than to incentivise renewablesii, although
several countries provided funds for new renewable power
capacity. Israel’s recovery plan included a commitment
of ILS 6.5 billion (USD 2 billion) to build 2 gigawatts (GW)
of new solar PV capacity. Nigeria’s stimulus plan allocated
around USD 620 million for a programme to install solar PV
home systems for 5 million households. In the United States,
the USD 900 billion relief package included extensions of
the production and investment tax credits for solar PV and
onshore wind power, a new tax credit for offshore wind
power, USD 1.7 billion for low-income homeowners to
install renewable energy, and USD 4 billion in research and
development (R&D) funding for solar power, wind power,
hydropower and geothermal energy.
In the buildings and industry sectors, the largest share
of energy-related stimulus aid was aimed at spurring
investments in renewable heat in buildings and raising the
energy efficiency of existing buildings. France’s COVID-19
stimulus package included EUR 7 billion (USD 8.6 billion) to
support building renovations – including those encouraging
renewable heat – as part of a wider target to renovate the
country’s entire building stock by 2050.
In the transport sector, aviation was the largest stimulus
recipient, but only three countries – Austria, France and
Sweden – included “green” conditions for aviation stimulusiii.
At least four countries provided COVID-19 relief for electric
transport and hydrogen for transport, although not necessarily
linked to renewable energy. The Republic of Korea’s recovery
package included KRW 2.6 trillion (USD 2.4 billion) in support of
EVs and hydrogen cars. France’s plan allocated EUR 11 billion
(USD 13.5 billion) for EVs, including support for charging
stations. Germany’s stimulus package included EUR 5.9 billion
(USD 7.3 billion) in subsidies for EVs and charging infrastructure
as well as EUR 7 billion (USD 8.6 billion) for renewable
hydrogen for decarbonising heavy transport and industry. Part
of Spain’s EUR 3.8 billion (USD 4.6 billion) aid package for the
auto industry included measures to electrify public transport, a
target to increase the number of EV charging points to 50,000
by 2023 and 800,000 by 2040, funding for EV charging and
subsidies for purchasing low-emission cars.
i Member States are expected to invest funds in the seven priority areas
of: clean energy technologies; energy-efficient building renovations;
sustainable transport; broadband roll-out; digitalisation of public ad-
ministration; cloud computing capacities; and mainstreaming digital
skills into education systems. In line with the European Green Deal, EU
countries have agreed to explicitly include clean energy transitions at
the heart of their economic recovery.
ii Excluding the EU plan for economic recovery, new renewable electricity
plants, mostly wind and solar PV, received only around
USD 10 billion from announced stimulus packages.
iii Austria required Austrian Airlines to abolish air routes that can be rea-
ched by train in far fewer than three hours and to commit to additional
emission reduction goals, France’s USD 7.7 billion support for Air France
required 50% emission reduction and a minimum of 2% renewable fuel
by 2030, and Sweden imposed conditions of 25% emission reduction by
2025 on Scandinavian Airlines.
Source: See endnote 5 for this chapter.
62
i Nationally Determined Contributions (NDCs) describe efforts by each country to reduce greenhouse gas emissions and adapt to the impacts of climate
change. Article 4 of the Paris Agreement requires each Party to prepare, communicate and maintain successive NDCs that it intends to achieve. By the end
of 2020, countries with an initial NDC covering the period to 2025 were required to produce an NDC that extends to 2030, and those that already contained a
2030 target were required to update their NDCs. In 2020, 44 countries plus the EU met this deadline.
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BOX 4. Trade Policy, Local Content Requirements and Renewables
In 2020, several jurisdictions unveiled policies to stimulate the
local production of renewable energy equipment. In Africa,
Mali exempted equipment such as solar panels, wind turbine
blades and pump turbines from paying value-added tax (VAT).
Burkina Faso launched a Solar Cluster initiative to establish
a domestic solar PV industry by offering long-term financial
backing for solar PV projects and providing networking and
training opportunities for the country’s solar industry. Uganda’s
revised draft National Energy Policy committed to formulating
innovative financing mechanisms for geothermal and solar
PV through different financial interventions, including income
tax deductions, exemptions from VAT and customs tax, and
accelerated depreciation tax incentives.
India put forward an expedited manufacturing plan to
incentivise domestic solar cell manufacturing capacity and
planned to impose new tariffs of 40% on imports of solar
modules and 25% on solar cells starting in April 2022. The
Indian government also approved a “production-linked
incentive” plan to enhance the country’s manufacturing
capabilities and exports, including domestic high-efficiency solar
PV module manufacturing and advanced chemistry cell batteries.
Turkey’s new regulations for solar panel imports (which
require calculating the import duty on solar modules per
kilogram rather than by square metre) are perceived to favour
Turkish manufacturers of solar PV panels, as high-efficiency
modules generally are heavier than they were a few years
ago. Saudi Arabia announced a plan to increase local content
in domestic renewable energy industry chains.
Other jurisdictions eased import requirements for renewable
energy equipment in 2020. The Brazilian government
introduced a measure to remove a 12% levy for some solar
equipment (modules, inverters and trackers). The government
of Bangladesh added EUR 200 million (USD 246 million) during
the year to its Green Transformation Fund, which offers loans
for the import of “environmentally friendly” products and energy
efficiency components from Europe. In Senegal, to accelerate
the electrification of rural areas, the government exempted
equipmenti for the production of solar PV power from the VAT.
i The exempted products include solar panels, inverters, solar thermal
collectors, batteries, solar lamp kits, solar water heaters and charge
regulators. Packages comprising a battery, solar panel, and a lantern
or a solar panel, a water pump and controller also are included among
the VAT-exempted products.
Source: See endnote 7 for this chapter.
RENEWABLE ENERGY AND
CLIMATE CHANGE POLICY
Policies enacted to help mitigate climate change can directly or
indirectly stimulate renewable energy deployment by mandating
a reduction or elimination of greenhouse gas emissions, phasing
out or banning the use of fossil fuels and/or increasing the costs
of energy from fossil fuels relative to renewables. Climate change
policies that indirectly support renewables include targets to
reduce greenhouse gas emissions, the development of and
participation in carbon pricing and emission trading programmes,
and fossil fuel bans or phase-outs. In some cases, climate change
policies also are designed to directly stimulate the deployment of
renewables.
CLIMATE POLICIES THAT INDIRECTLY SUPPORT RENEWABLES
Although the COVID-19 crisis was the central political focus
of 2020, commitments to climate change mitigation also were
prominent during the year. Overall, 2020 was an important
milestone for climate change policy, with many countries’
greenhouse gas targets for the year expiring, countries setting
new targets, and numerous countries committing to carbon
neutrality. For example, signatories to the Paris Agreement were
supposed to submit updated (or new) Nationally Determined
Contributions (NDCs)i towards reducing emissions by the end of
2020, and at least 40 countries plus the EU met this deadline.8
Numerous countries worldwide also implemented additional
climate change policies during 2020, including setting
greenhouse gas emission targets, adopting carbon pricing or
emission trading programmes, and announcing fossil fuel bans
or phase-outs. (p See Figure 12.)
63
i “Net zero” refers to achieving a net balance between greenhouse gas emissions produced and those removed from the atmosphere. In contrast, a gross zero
target would reduce emissions from all sources to zero. In a net zero scenario, emissions are “allowed” as long as they are offset by removals. Reaching net zero
emissions may be linked to activities such as carbon offsetting and carbon capture and storage and thus does not necessarily include the use of renewables.
“Carbon-neutral” means having a balance between emissions of carbon and the absorption of carbon from the atmosphere (by way of carbon sinks).
RENEWABLES 2021 GLOBAL STATUS REPORT
Greenhouse gas emission targets mandate a reduction in
overall emissions and can include net zero and “carbon-neutral”
targetsi. During 2020, new emission reduction commitments
were spread across nearly all continents, covering around 47%
of total global emissions.9 (p See Table 4.) Some of the most
significant carbon neutrality pledges occurred in Asia, with
China aiming to become carbon neutral by 2060, Japan by
2050 and the Republic of Korea by 2050 (including a pledge to
replace coal with renewables).10
Note: Carbon pricing policies include emission trading systems and carbon taxes. Net zero emissions targets shown are binding and include those that are
in law or policy documents, as well as those that have already been achieved. Fossil fuel ban data include both targeted and existing bans across the power,
transport and heating sectors. Jurisdictions marked with a flag have some type of fossil fuel ban in one or more sector. See GSR 2021 Data Pack for details.
Not all cities with policies are shown; see REN21 Renewables in Cities 2021 Global Status Report for more comprehensive city policies.
Source: Based on World Bank, Energy Climate Intelligence Unit, IEA Global Electric Vehicle Outlook and REN21 Policy Database. See Reference Tables R4,
R6 and R9 in GSR 2021 Data Pack. See endnote 8 for this chapter.
FIGURE 12 .
Countries with Selected Climate Change Policies, Early 2021
California
Washington
ConnecticutConnecticut
New HampshireNew Hampshire
VermontVermont
MarylandMaryland
VirginiaVirginia
MaineMaine
DelawareDelaware
New YorkNew York
New JerseyNew Jersey
State/provincial policy only
Existing fossil fuel ban in 1+ sectors
Targeted fossil fuel ban in 1+ sectors
Net zero emissions target
Both net zero emissions target
and carbon pricing policy
Carbon pricing policy
Carbon
pricing initiatives
covered only around
22% of global
greenhouse gas
emissions by
early 2021.
64
Net zero emission targets
Country/region 2019 CO2 emissions (kilotonnes)
2019 CO2 emissions
(% of world total) Target year Legal status
EU-27 2,939,069 7.73% 2050 Proposed
Austria 72,363 0.19% 20401 In law/policy document
Canada 584,846 1.54% 2050 Proposed
Hungary 53,183 0.14% 2050 In law/policy document
Jamaica 7,442 0.02% 2050 Pledge
Lao PDR 6,783 0.02% 2050 Pledge
Maldives 913 <0.001% 20302 Pledge
Mauritius 4,332 0.01% 2070 Pledge
Nepal 15,019 0.04% 2050 NDC
United Kingdom 364,906 0.96% 20503 In law/policy document
The Vatican N/A N/A 2050 Pledge
Carbon-neutral targets
Country/region 2019 CO2 emissions (kilotonnes)
2019 CO2 emissions
(% of world total) Target year Legal status
Argentina 199,414 0.52% 2050 NDC
Barbados 3,827 0.01% 2030 In law/policy document4
China 11,535,200 30.34% 2060 Pledge
Japan 1,153,717 3.03% 2050 Pledge
Kazakhstan 277,365 0.73% 20605 Pledge
Korea, Republic of 651,870 1.71% 2050 NDC
Malawi 1,616 <0.001% 2050 Pledge
Nauru N/A N/A 2050 Pledge
Slovenia 15,365 0.04% 2050 National plan/strategy
South Africa 494,862 1.30% 20506 National plan/strategy
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TABLE 4.
New Net Zero Emission and Carbon-Neutral Targets Set by Countries/Regions in 2020
Notes: Net zero emissions can refer to all greenhouse gas emissions or only carbon emissions,
and involves emissions declining to zero. Carbon neutral refers to the balancing of carbon
emissions caused by an entity with funding an equivalent amount of carbon savings elsewhere.
Although carbon neutrality is sometimes considered to be a synonym for net zero carbon
emissions, carbon neutrality can be achieved at the domestic level by using offsets from other
jurisdictions, whereas net zero does not necessarily include this feature. Some of these countries
– along with Colombia, Kenya and Peru – also adopted other targets less than carbon-neutral/
net zero (see GSR 2021 Data Pack for full dataset).
1 Austria's target is for "climate neutrality".
2 Target to be reached with adequate international support and assistance.
3 Adopted in 2019.
4 Published in 2019.
5 Target could be advanced if the country raises USD 10 billion annually from other nations to
help finance the transition.
6 South Africa's target is a net zero carbon emissions target.
N/A = data not available
Source: See GSR 2021 Data Pack.
New emission reduction
commitments during 2020
covered around
47%
of total global emissions.
65
i A zero-emission vehicle, or ZEV, is a vehicle that does not produce any direct tailpipe emissions. ZEVs may have a conventional internal combustion engine
but also must be able to operate without using it. ZEVs include battery electric vehicles, hydrogen fuel cell vehicles and plug-in hybrid electric vehicles.
ii Cities include the Australian Capital Territory (Canberra) (ZEVs by 2021); London (100% zero-emission transport by 2050); Los Angeles (100% ZEVs by 2050);
New York City (100% ZEVs by 2050); San Francisco (electrify all private forms of transport); and Toronto (all transport in the city to be low carbon).
iii Exceptions will be made for some natural gas-fired power plants.
RENEWABLES 2021 GLOBAL STATUS REPORT
Carbon pricing and emission trading programmes have the
potential to indirectly increase the deployment of renewables by
increasing the relative cost of energy from fossil fuels. By the end
of 2020, at least 64 national and state/provincial governments
(up from 57 in 2019) had adopted or committed to carbon
pricing policies through either direct taxation or a cap-and-trade
programme.11 During the year, Montenegro introduced a cap-
and-trade system for major greenhouse gas emitters, and in
Mexico a pilot emission trading programme began operating as
part of a process to establish a more complete trading system.12
New Zealand strengthened its emission trading programme by
placing a finite cap on the total emission permits that will be
issued under the programme.13
Bans and phase-outs of fossil fuels are other indirect climate
change policies that can stimulate the uptake of renewables in
different (or multiple) end-use sectors. In 2020, the most common
type of fossil fuel ban enacted at the national and state/provincial
levels was on coal. Since coal typically is used for electricity
generation, coal bans can indirectly stimulate generation from
renewables. (k See Reference Table R6 in GSR 2021 Data Pack.)
In Europe, both Austria and Sweden closed their last coal-fired
power plants in 2020 as part of phase-out plans.14 Although
Germany’s scheme to phase out hard coal was already under
way, the government implemented the Coal Phase-Out Act
during the year, which lays out a strategy to gradually reduce the
use of coal-powered energy by 2038.15
In Asia, Japan committed to accelerating the closure of roughly
two-thirds of its older, lower-efficiency coal-fired power
plants by around 2030, and made pledges to further promote
renewables.16 The government of the Philippines announced a
moratorium on all applications for new coal-fired power plants,
and Pakistan announced an end to the construction of new coal
plants (although plants under construction were expected to be
completed).17
In the buildings sector, bans or support for phasing out fossil
fuels for heating (such as heating oil and fossil natural gas) may
indirectly stimulate the use of renewables for space and water
heating. Many of these bans occur at the municipal level. (k
See Reference Table R4 and Reference Table R9 in GSR 2021
Data Pack, and Renewables in Cities Global Status Report.) At the
national level, Germany’s new Buildings Energy Act places limits
on the installation of oil heating systems beginning in 2026.18
The government of Finland included in its 2020 budget
EUR 45 million (USD 55 million) in grants to phase out oil
heating in both residential and municipal buildings.19 The United
Kingdom announced a ban on gas fuels for heating in all new
homes, although no deadline was provided.20 Slovenia’s National
Energy and Climate Plan included a commitment to ban the sale
and installation of new heating oil boilers after 2022.21
In the transport sector,
bans on fossil fuels
for road transport can
incentivise biofuels-
based transport as well
as electric vehicles, which
could facilitate greater use
of renewable electricity
in the sector. Bans on
internal combustion
engine vehicles (or
targets for 100% EVs)
similarly incentivise EVs. (k See Reference Table R8 in GSR
2021 Data Pack.) During 2020, as part of its new “green growth”
strategy, the government of Japan announced that it would take
actions to eliminate petrol vehicles in the next 15 years (although
no target was set).22 Scotland’s updated Climate Change Plan
includes a commitment to phase out sales of new petrol and
diesel cars and vans by 2030.23
At the state level, California (US) is requiring all new passenger
vehicles (cars and trucks) sold in the state to be zero emissioni
by 2035, while all medium- and heavy-duty vehicles sold must
be zero emission by 2045 – the first such policy in the world
targeting trucks and vans.24 Massachusetts (US) announced a
ban on the sale of new petrol vehicles by 2035.25 (p See Transport
section in this chapter for more details.)
Many cities also have adopted policies that either ban or heavily
restrict the use of fossil fuels for road transportii, as well as
policies that incentivise non-motorised travel. In addition to
vehicle bans and EV targets, cities increasingly have used low-
emission zones (LEZs) to restrict certain types of vehicles from
entering city centres.26 In 2020, governments placed a strong
emphasis on walking and cycling infrastructure, as “pop-up”
bike lanes were added during pandemic-related lockdowns
and allocations were made for cycling infrastructure funding,
subsidies and other incentives.27 (p See Transport section
in Global Overview chapter, and Renewables in Cities Global
Status Report.)
At least two countries withdrew support for fossil fuel
exploration in 2020. Denmark announced that it will end all new
domestic oil and gas exploration by 2050.28 The United Kingdom
announced an end to all public financing for international fossil
fuel projects, including support for oil, most fossil-based natural
gasiii and coal exploration and other operations starting in
2021.29 However, this announcement does not include the UK’s
domestic oil and gas exploration.30 Some countries also have
begun engaging in so-called “subsidy swaps” that shift public
funding away from fossil fuels to more sustainable alternatives.31
(p See Sidebar 4.)
Bans and
phase-outs
of fossil fuels grew in
popularity during 2020,
particularly for coal.
66
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SIDEBAR 4. “Subsidy Swaps” as a Means to Shift Financial Support Towards Renewables
Across the energy sector, technologies that enjoy access to
grants, tax breaks and other forms of government support
have a clear market advantage over those that do not. Direct
subsidies to the oil, gas and coal industries amounted to more
than USD 478 billion globally in 2019, and both direct and
indirecti subsidies for fossil fuel production have continued to
grow, increasing an estimated 38% or more that year. In the
lead-up to the fifth anniversary of the Paris Agreement, in
December 2020 a group of 10 governmentsii spanning nearly
all continents released a joint statement calling on world
leaders to phase out fossil fuel subsidies.
Some fossil fuel subsidy schemes are designed to offset the
falling margins and loss of competitiveness that fossil fuels
have experienced in the face of ever-lower renewable energy
costs. These subsidies have impeded the rapid transition to
renewables that is necessary to achieve global climate and
development goals. However, in recent years momentum has
grown behind the idea of accelerating the transition through
so-called subsidy swaps that shift public funding away from
fossil fuels, which are increasingly seen as detrimental to both
public health and the environment. (p See Feature chapter in
GSR 2020.)
Subsidy swaps generally involve elements of the following:
• reducing and removing fossil fuel subsidies and/or
increasingly taxing fossil fuels;
• generating a greater share of tax revenues from environmental
taxation (e.g., carbon pricing policies);
• reallocating a share of savings and tax revenues to renewable
energy, energy efficiency and related infrastructure;
• mitigating negative social impacts through allocations
targeted at specific population groupsiii; and
• ensuring that all reallocations of funds are broadly supportive
of an energy transition.
Many of these measures are reflected in the wider trends in
power generation capacity in recent years. Since 2015, net
installations of renewable capacity have outpaced those of
both fossil fuel and nuclear power capacity combined. (p See
Global Overview chapter.)
Although most subsidies tend to be captured by the rich,
efforts to reform fuel subsidies that support lower-income
groups (such as subsidised heating oil) can sometimes be
controversial. Rises in fuel prices could end up being regressive
(having a greater impact on those with lower incomes) and risk
reducing people’s ability to meet basic energy needs. Through
the design of adequate complementary measures, however,
fossil fuel subsidies can be removed without limiting energy
access. For example, a subsidy swap from kerosene to solar
lighting can benefit poorer households while also lowering
emissions, reducing reliance on fossil fuels and improving
health through cleaner air.
India’s subsidy policy has broadly followed the logic of a subsidy
swap. One analysis found that the country’s subsidies for all
energy types fell from USD 35 billion in 2014 to USD 26 billion
in 2019. Over this period, the energy subsidies that remained
were increasingly allocated towards "clean energy" and
transport. India has been able to lower subsidies for kerosene,
a key fuel for poor households, in part by better targeting the
beneficiaries of support for alternative fuels, in combination
with expanding electrification and clean cooking. Although the
Indian government has set a target for 450 GW of renewable
energy capacity by 2030, fossil fuel subsidies in the country are
still greater than financial support for renewables.
During 2020, some government responses to the COVID-19
crisis became a testing ground for the subsidy swap approach.
Recovery packages have the potential to greatly shape future
energy systems, as subsidies and bailouts could either derail
or accelerate the energy transition. International organisations
have called for using post-pandemic recovery packages as an
opportunity to phase out fossil fuel subsidies, although so far
very few governments have acted on this advice. Most new
and amended energy policies introduced in 2020 sent a mixed
signal: while there was a great deal of support for renewables
in some recovery packages, many governments chose to
further prop up fossil fuels. (p See Sidebar 3 in this chapter.)
i Direct subsidies involve actual payment of funds to individuals and/or industries, while indirect subsidies do not involve actual cash outlays but encom-
pass other financial benefits such as price reductions.
ii Costa Rica, Denmark, Ethiopia, Finland, New Zealand, Norway, Sweden, Switzerland, the United Kingdom and Uruguay.
iii For example, targeted allocations could include “lifeline” tariffs for those identified as lacking basic energy access, grants for renewable energy systems for
those not connected to the grid, or reducing income taxes for low-income earners funded by reforming fossil fuel subsidies. See International Institute for
Sustainable Development, Getting on Target: Accelerating Energy Access Through Fossil Fuel Subsidy Reform (Winnipeg, Canada: 2018), https://www.iisd.
org/system/files/publications/getting-target-accelerating-energy-access .
Source: IISD. See endnote 31 for this chapter.
67
https://www.iisd.org/system/files/publications/getting-target-accelerating-energy-access
https://www.iisd.org/system/files/publications/getting-target-accelerating-energy-access
i EU Member States had to submit by 1 January 2020 their first long-term strategies covering specific sector plans, including electricity, industry, transport,
heating/cooling and buildings, agriculture, waste and land use, and land-use change and forestry.
ii See Glossary.
RENEWABLES 2021 GLOBAL STATUS REPORT
CLIMATE PL ANS THAT DIRECTLY SUPPORT RENEWABLES
While most climate change policies do not include renewable
energy support directly, in some cases, climate change policies
are designed to directly stimulate the deployment of renewables.
During 2020, at least six governments at the regional, national
and/or provincial or state levels adopted comprehensive,
cross-sectoral climate policies that included direct support for
renewables, in addition to elements of one or more of the indirect
support policies mentioned previously.
For example, the EU’s 2020 commitment to reduce greenhouse
gas emissions 55% by 2030 included earmarking EUR 1 trillion
(USD 1.2 trillion) in funding for the European Green New Deal.32
This strategy aims to transform Europe into a climate-neutral
continent by 2050 by undertaking actions across all parts of the
economy, including investing in renewable electricity generation,
renewables in buildings and electrification of transport (which
would facilitate increased renewable electricity in the sector)i.33
At the country level, France and the United Kingdom also
committed to various renewable energy policies as part of
comprehensive climate change plans. France’s new national
energy plan (Programmation pluriannuelle de l’énergie) includes
targets for renewable generation capacity for 2023 and 2028, a
target for renewable hydrogenii to comprise 10% of the industrial
hydrogen mix by 2023 (and 20-40% by 2028), targets for energy
efficiency in buildings, and targets of 660,000 EVs by 2023 (and
3 million by 2028) and 100,000 public EV charging stations
by 2023.34
The United Kingdom’s “10 point plan” for a green industrial
revolution allocates around GBP 12 billion (USD 16 billion) in
government investments to decarbonise the country.35 It includes
an offshore wind power target of 40 GW by 2030 (up from the
10 GW installed currently) in addition to providing GBP 1.3 billion
(USD 1.8 billion) for EV charging infrastructure, grants for zero- or
ultra-low-emission vehicles, funding for cutting emissions from
aviation and maritime activities, funding for energy efficiency for
homes and public buildings, and a new target to install 600,000
heat pumps in homes and public buildings.36 In addition, the plan
calls for phasing out sales of new petrol and diesel cars and vans
by 2030 (moved up from the previous target year of 2035).37
In Asia, the Republic of Korea’s Green New Deal outlines plans
for the country to reach its 2050 target for carbon-neutrality.38
They include introducing a carbon tax, expanding solar PV and
wind power capacity to 42.7 GW by 2025 (up from 12.7 GW in
2019), installing solar PV on 225,000 public buildings, targeting
1.13 million EVs and 200,000 hydrogen-powered vehicles by
2025, providing funding for 45,000 EV recharging stations and
450 hydrogen refuelling units, and installing 4,000 public EV
charging stations and 65 hydrogen charging stations by 2035.39
In Africa, Zimbabwe launched new renewable energy and
biofuels policies to guide investments in renewables as a way to
achieve the country’s target of a 33% reduction in greenhouse
gas emissions (compared to business as usual) by 2030.40 The
National Renewable Energy Policy includes a target of 1.1 GW
of installed renewable electricity capacity by 2025 (or 16.5%
of the country’s total electricity supply) and 2.1 GW by 2030,
along with tax breaks for renewable generation facilities and a
requirement for all new buildings to host solar PV systems.41 The
Biofuels Policy commits to an ethanol blending mandate of up
to 20% by 2030 and the introduction of biodiesel blending of
up to 2% by 2030.42
In North America, Canada released a climate plan that includes
a commitment to increase the carbon tax from CAD 50
(USD 39) per tonne in 2022 to CAD 170 (USD 133) per tonne
by 2030, as well as CAD 15 billion (USD 11.7 billion) in funding
for buildings, industry and transport.43 The Canadian province
of Quebec adopted a CAD 6.7 billion (USD 5.2 billion) climate
change plan that includes a target to reduce emissions 37.5%
below 1990 levels by 2030, a target of carbon neutrality by 2050,
a ban on sales of new petrol passenger vehicles (cars, sport
utility vehicles, vans and pick-up trucks for personal use) by
2035, targets for EVs and biofuels in transport, and funding for
renewable heating and cooling in buildings.44
During 2020,
only 6
governments
adopted comprehensive,
cross-sectoral climate
policies that included direct
support for renewables.
68
i Renewable gases include biogas, biomethane, renewable natural gas and renewable hydrogen produced from renewable electricity (electrolysis).
Because renewable gases can replace fossil gas, they can leverage existing gas networks.
ii Mainly through the use of wood and pellet stoves and boilers and in district heating networks.
iii The electrification of heating is only renewable to the extent that the electricity used is generated from renewable sources.
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HEATING AND COOLING
IN BUILDINGS
The buildings sector – including both commercial and residential
buildings – is a significant energy end use and contributor to global
greenhouse gas emissions.45 Energy is consumed in buildings
for climate control (space heating and cooling), water heating,
cooking, lighting, and the powering of appliances and electronics.
A variety of policies exist at the national and provincial/state
levels related to direct and indirect heating and cooling with
renewables, including thermal renewable energy (geothermal,
solar thermal), biomass-based energy and renewable electricity
(which can be used to power heating and cooling appliances
such as heat pumps) (p see Power section in this chapter).
Heating and cooling demand in buildings accounts for around
25% of total final energy consumption, and although most of this
consumption is currently met by fossil fuels, there is significant
potential for greater use of renewables.46 Bioenergy (including
renewable gasesi) is the largest renewable source of heating and
cooling in buildingsii today, but other sources include geothermal
and solar thermal energy, as well as renewable electricityiii.47
Despite the vast potential of renewables, policies designed to
advance their use in heating and cooling remain less common
than those in the power or transport sectors.
Policy makers can advance the production and use of renewable
energy to heat and cool buildings through legislated targets,
financial incentives, mandates (including building energy codes),
policies that support the electrification of heating and cooling,
and policies that support renewable district heating. Policies
that indirectly encourage renewable heating and cooling include
fossil fuel bans or phase-outs, fuel taxes and net zero emission
standards for buildings. (p See Renewable Energy and Climate
Change Policies section in this chapter.)
In 2020, as in previous years, policy developments in heating
and cooling for buildings remained scarcer than policies
directed at electricity generation and transport. Although some
developments occurred (including financial incentives, energy
efficiency and electrification of heating and cooling), by year’s
end only 19 countries had committed to renewable heating
and/or cooling targets for buildings (down from 49 countries
in 2019, due to 2020 targets coming to term without being
replaced by later targets), whereas 137 countries had renewable
power targets.48 Meanwhile, only 10 countries had renewable
heat support policies covering all sectors (residential, industrial,
commercial and public facilities) by the end of the year. (p See
Figure 13, and Reference Tables R4, R6 and R9 in GSR 2021 Data
Pack.) Interest in cooling has increased with the rising demand for
cooling, particularly in developing countries, but this has not yet
translated into more policies and targets for renewable cooling.49
Financial incentives for buildings – including grants, rebates,
tax incentives and loan programmes – were the most commonly
used measures to encourage renewable heating and cooling in
buildings during 2020. (k See Reference Table R9 in GSR 2021
Data Pack.) All of the new developments occurred in Europe.
For example, Italy raised the tax-deductible “eco-bonus” benefit
for building insulation and replacement of heating and cooling
systems in apartment buildings and family homes (from 50% to
110%) and extended the benefit to the end of 2022.50 Lithuania
provided EUR 14 million (USD 17 million) to reimburse building
owners who convert old, inefficient boilers to more energy-
efficient installations that use renewable heat sources (including
biofuel boilers and heat pumps).51
The Netherlands’ subsidy programme scheme for renewables
(Renewable Energy Production Incentive Scheme, SDE++),
which compensates for the difference between the cost of
the technologies and the market value of the product, was
broadened to include renewable heat (such as geothermal,
biomass and solar thermal systems).52 Scotland provided
GBP 1 million (USD 1.4 million) for projects using “low-carbon”
heat and/or renewable electricity solutions for buildings, and
the United Kingdom extended its Domestic Renewable Heat
Incentive Scheme to 31 March 2022.53 Portugal launched a new
EUR 4.5 million (USD 5.5 million) energy efficiency programme
that provides incentives for decarbonisation and energy efficiency
in buildings, including to retrofit them with renewables.54
Mandatory building energy codes that require the
deployment of renewable energy systems can play a key role
in the uptake of renewable heating and cooling, particularly
in new construction and retrofits.55 Even when renewables
are not explicitly required in building energy codes, these
codes can have a positive effect on the energy demand of
buildings because they typically require energy efficiency
improvements.56 By the end of 2020, 67 countries had in place
mandatory or voluntary building energy codes (down from
73 in 2019).57 At least 40 countries have mandatory codes for
both residential and non-residential buildings.58
69
RENEWABLES 2021 GLOBAL STATUS REPORT
FIGURE 13.
Sectoral Coverage of National Renewable Heating and Cooling Financial and Regulatory Policies, as of End-2020
Note: Sectors include residential, industrial, commercial and public facilities. Policy types used for map shading
include investment subsidies/grants, rebates, tax credits, tax deductions, loans and feed-in tariffs. Renewable
energy mandates are the obligation to meet a certain renewable standard for heat, such as the use of a specified
technology. Other support policies include fossil fuel bans, support for phasing out fossil fuels, CO2 pricing
for heat and support for R&D. Figure does not show policies at the local level; for local level data, see REN21
Renewables in Cities Global Status Report, www.ren21.net/cities.
Source: REN21 Policy Database. See Reference Table R9 in GSR 2021 Data Pack.
Only
10 countries
had renewable heat
support policies covering
all sectors as of end-2020.
While not all of the codes included renewable energy
requirements, at least 2 new renewable energy requirements
were added to building energy codes in 2020 (in contrast to
2019 when no such requirements were added), only at the sub-
national level. A requirement adopted in 2018 for all new homes
in California to be equipped with solar panels came into effect
in 2020, while the state of Washington announced additional
energy credit options for builders incorporating solar power.59
Conversely, some jurisdictions added restrictions for renewable
energy in their building codes, such as Minnesota, which prohibits
placing solar panels within 0.9 metres of a roof edge as a safety
precaution – a measure that is estimated to shrink the available
space for solar PV by at least 20%.60
Electrification of heating and cooling can increase the
penetration of renewables in the buildings sector if the
electricity used is generated from renewable sources. Globally,
electrification of heating and cooling is increasing, with around
11% of global electricity generation used by electric heaters,
boilers and heat pumps for buildings.61 In 2020, policy makers
gave greater attention to policies targeting the electrification
of heating and cooling in buildings. Denmark provided tax
incentives for the use of renewable electricity to heat buildings
(while also raising taxes on fossil fuels for heating) and allocated
DKK 2.3 billion (USD 0.38 billion) for the replacement of oil and
natural gas boilers with renewable heat.62
At a sub-national level, British Columbia (Canada), which
generated nearly 95% of its electricity from renewables in 2020,
temporarily doubled rebates for residential heat pumps.63 In the
United States, California provided USD 45 million for electric heat
pump water heaters, and New Mexico reinstated a USD 6,000
tax credit for households and businesses to install solar PV
panels or solar thermal systems to heat water.64 The Australian
Number of
sectors covered
Other support policy
Renewable energy mandate
3 sectors
1 sector
2 sectors
Zero sectors or no data
4 sectors
70
http://www.ren21.net/cities
i Up to a maximum of GBP 5,000 (USD 6,788) per household, or up to GBP 10,000 (USD 13,577) for low-income homeowners.
ii See Glossary.
iii In some cases, hydrogen also can be used as a feedstock for chemical processes.
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Capital Territory committed AUD 500 million (USD 383 million)
to build a hospital powered entirely with renewables, including a
100% renewable electric heating and cooling system.65
Renewable district heating can provide an entry point
for renewables to reach end-users. In 2020, the European
Commission approved a EUR 150 million (USD 184 million)
programme to support the conversion of district heating systems
in Romania from fossil fuels to renewables.66 Poland launched
a programme offering owners of district heating networks
co-financing in the form of grants and loans to add renewable
energy or waste heat to their systems.67
Policies targeting energy efficiency often are cost-effective
options for decreasing the thermal demand of buildings.68 In 2020,
the EU launched a “renovation wave” that aims to reduce building
emissions 60% by 2030 by doubling the yearly rate of energy-
related building renovations.69 The renovation wave includes
an acknowledgement of the contribution of on-site renewables
to achieve higher energy efficiency requirements.70 Another
European initiative, set to begin in 2022, is intended to facilitate
collaboration between experts and entrepreneurs on buildings,
including energy efficiency.71 In the United Kingdom, England’s
new Green Homes Grant scheme provides homeowners the
opportunity to receive a government subsidy for two-thirds of the
cost of energy efficiency improvementsi.72
Israel’s new national energy efficiency plan includes funding
to make buildings more energy efficient over the next 10 years,
including by ensuring that imported electrical products are more
energy efficient, integrating energy ratings into new buildings and
requiring contractors to publish energy efficiency ratings when
they sell.73 At a sub-national level, the US state of Washington
implemented a Property Assessed Clean Energy (PACE)ii loan
programme to finance energy efficiency and renewable energy
retrofits for existing and new buildings.74
INDUSTRY
In addition to using electricity, some industrial processes utilise
thermal energy (heat) to meet various needs. Like buildings,
thermal energy demand (both direct thermal energy and
electricity for heat) in industrial processes accounts for around
25% of global final energy consumption.75 This demand can
be met directly by thermal energy from renewables (including
biomass, solar thermal and geothermal energy) or indirectly
from renewable electricity, for example via heat pumps (provided
that the electricity used is generated from renewable sources).
Renewable hydrogen also can be used to meet certain energy
demands in industryiii.76 (p See Sidebar 5 and Table 5.) Currently,
bioenergy accounts for nearly all of the renewable heat use in
industry (almost 90% in 2019).77
Renewable energy solutions to provide low-temperature heat
for industrial uses are widely available. However, for industries
that require high-temperature heat, such as steel and cement,
renewable technologies have not yet reached scale to be
competitive with fossil fuels. Thus, government support through
policy, targets, and research, development and demonstration
(RD&D) remains important. Nevertheless, by the end of 2020,
only 32 countries had some form of renewable heating and
cooling policy for industry (unchanged from 2019). (k See
Reference Table R9 in GSR 2021 Data Pack.)
The most common form of policy support during 2020 was
financial incentives. For example, the United Kingdom offered
GBP 139 million (USD 189 million) to support industry efforts to
cut greenhouse gas emissions, including switching from fossil-
based gas to renewable hydrogen for fuel-heavy industry.78 The
Netherlands offered a subsidy for companies in the industrial
sector to generate renewable electricity, heat and gas for their
own use.79 Denmark allocated DKK 2.5 billion (USD 413 million)
in subsidies for 10 years for electrification and energy
efficiency improvements in industry, as well as DKK 2.9 billion
(USD 479 million) for biogas and other renewable gases for those
parts of industry where renewable electricity cannot be utilised
directly.80 Although not specific to industry, Scotland announced
interest-free loans of GBP 1,000 to GBP 100,000 (USD 1,358 to
USD 135,772) for small and medium-sized enterprises to install
renewables for heating (including biomass boilers, solar thermal
technologies and electric heat pumps).81
In the agricultural sector, most policy during the year was aimed
at improving irrigation systems. Jamaica committed to powering
all irrigation systems operated by the National Irrigation
Commission solely with solar PV within two years.82 Egypt
announced plans to invest EGP 184 million (USD 11.6 million) to
modernise several irrigation systems, including equipping them
with solar PV to improve electricity supply.83 Canada, as part of
its new climate plan, committed to investing CAD 166 million
(USD 130 million) to support its agriculture sector to develop
“clean technologies” (including renewables).84
Number of
sectors covered
Other support policy
Renewable energy mandate
3 sectors
1 sector
2 sectors
Zero sectors or no data
4 sectors
71
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 5. Policy Support for Renewable Hydrogen
Renewable hydrogen is an energy carrier produced through
renewables-driven electrolysis or gasification using renewable
feedstocks. Hydrogen can either be combusted directly for
use in heat or transport, or used to generate electricity via fuel
cells. Apart from its potential to be stored and converted to
electricity when needed, hydrogen provides an opportunity
to increase the penetration of renewables beyond the power
sector, mainly in industry and transport but also in buildings.
(p See Systems Integration chapter.) In 2020, nearly all hydrogen
produced and used worldwide continued to be manufactured
with natural gas for use as an industrial feedstock.
A number of governments made policy announcements during
the year in support of hydrogen, although not all of these
committed to pursuing renewable hydrogeni. However, several
notable policy developments related to renewable hydrogen
occurred, particularly in Europe and Australia (as in 2019) but
also in Latin America.
In Europe, the EU introduced a new hydrogen strategy,
including a goal of 6 GW of electrolyser capacity powered
by renewable electricity by 2024 and 40 GW of renewable
hydrogen electrolyser capacity by 2030ii. Germany launched
its own hydrogen strategy, including plans to increase
hydrogen production capacity to 5 GW by 2030 and 10 GW by
2040 using surplus electricity from renewable energy sources.
Germany also committed to investing up to EUR 7 billion
(USD 8.6 billion) to promote renewable hydrogen production
and use.
The United Kingdom announced GBP 28 million (USD 38
million) in funding for five hydrogen production projects, one
focused on using offshore wind power to generate renewable
hydrogen. Norway allocated NOK 3.6 billion (USD 420 million)
to support the move from “grey” hydrogen (produced from
fossil fuels) to “blue” hydrogen (fossil fuels with carbon capture
and storage) and finally to “green” hydrogen (renewable
hydrogen). Spain unveiled a plan to boost renewable hydrogen
production and set a target of 300-600 MW of capacity by
2024 and 4 GW by 2030. Scotland announced GBP 100 million
(USD 136 million) for new electrolysers and set a target for
25 GW of renewable hydrogen by 2050.
In Australia, the government committed AUD 70 million
(USD 54 million) to support the deployment of at least two
new renewable hydrogen projects and established a new
AUD 300 million (USD 230 million) fund to invest in the
country’s renewable hydrogen industry. At a state level,
Tasmania announced a Renewable Hydrogen Action Plan
and AUD 50 million (USD 38 million) for renewable hydrogen;
the Northern Territory unveiled a strategy to become a hub
for renewable hydrogen technology research, production and
manufacturing; and Queensland announced AUD 10 million
(USD 7.7 million) over four years (in addition to the original
AUD 15 million (USD 12 million) Hydrogen Development Fund)
to support the renewable hydrogen industry.
In Latin America, Chile unveiled a national green hydrogen
strategy that aims to develop the country into a global producer
and exporter by 2040. The strategy consists of a commitment
to develop regulation for the use and production of renewable
hydrogen, to analyse global best practices related to renewable
hydrogen, and to convene government and the private sector
to develop a roadmap and action plan by 2025 that will identify
cofinancing opportunities with the private sector. Chile’s
strategy also updates the country’s NDC by setting out a target
for renewable hydrogen to reduce greenhouse gas emissions
18-27% by replacing fossil fuels.
i For example, Canada and France developed national hydrogen strategies
but did not commit to the development of renewable hydrogen specifically.
ii By 2030, the EU wants 40 GW of electrolysers installed within its
borders and another 40 GW in place in nearby countries that can
export to the EU. The EU’s strategy does not shut out “blue hydrogen”
(fossil-based hydrogen with carbon capture and storage) as a means of
phasing in hydrogen while the cost of renewable hydrogen decreases.
Source: See endnote 76 for this chapter.
72
Jurisdiction Target Policy/Programme
European
Union
6 GW electrolyser capacity and
1 million tonnes production
by 2024; 40 GW and 10 million
tonnes by 2030
Hydrogen Strategy provides framework to establish European Clean Hydrogen
Alliance, including an investment agenda and support for scaling up value chain.
The strategy targets production as well as end-use in industry.
Australia Renewable Hydrogen Deployment Funding Round will provide AUD 70 million
(USD 54 million) to support at least two projects. Advancing Hydrogen Fund of
AUD 300 million (USD 230 million) supports new projects nationwide.
New South
Wales
Electricity Investment Bill includes AUD 50 million (USD 38 million) over
10 years to develop renewable hydrogen sector. Parts of NSW will be designated
renewable energy zones.
Northern
Territory
Renewable Hydrogen Strategy outlines a plan for development of local
industry, resource management infrastructure, fostering demand for exports and
domestic applications, support for innovation and regulation to guide industry.
South
Australia
AUD 17 million (USD 13 million) in grants and AUD 25 million (USD 19 million) in
loans provided to four projects. Hydrogen Action Plan outlines plan to facilitate
investments in infrastructure; establish regulatory framework; and support trade,
supply capabilities, innovation, workforce development and energy system integration.
Tasmania Production to start by 2022 Renewable Hydrogen Industry Development Funding Program allocates
AUD 50 million (USD 38 million) to support industry development, including
financial assistance for renewable electricity supply and concessional loans.
Victoria Hydrogen Investment Program supports development of industry through
market testing, policy development and targeted investment programme.
Western
Australia
Up to 10% blend in gas pipelines
and networks by 2030
Renewable Hydrogen Strategy and Roadmap include funding for grants to
study production for export, use in mining operations, blending with natural gas
and use as transport fuel.
Queensland Hydrogen Strategy includes the AUD 15 million (USD 11 million) Hydrogen
Industry Development Fund, providing funding for investors developing
projects to increase supply of renewable hydrogen.
Canada
Quebec Hydro-Quebec's (public utility) Strategic Plan 2020-24 supports R&D for
production using hydroelectricity.
Chile 5 GW electrolyser capacity and
200 kilotonnes of production
by 2025; 25 GW by 2030
Up to USD 50 million to help finance pilot projects that may not be initially
competitive while operating at a small scale. A task force will help with provision
of permits and development of pilot programmes.
France1 6.5 GW electrolyser capacity;
20-40% renewable by 2030; 10%
renewable in industry by 2023
EUR 2 billion (USD 2.5 billion) from its coronavirus recovery plan by 2022 for
pilot and regional projects, and EUR 7 billion (USD 8.6 billion) for development
of industry by 2030.
Germany 5 GW electrolyser capacity and
14 TWh production per year
by 2030; 10 GW and 28 TWh
production per year by 2035-2040
National Hydrogen Strategy includes EUR 310 million (USD 380 million)
by 2023 for research and innovation; EUR 9 billion (USD 11 billion) to stimulate
use in transport, industry, heating and other applications; and EUR 7 billion
(USD 8.6 billion) to increase capacity.
Netherlands 0.5 GW electrolyser capacity
by 2025; 3 to 4 GW by 2030
SDE++ (Stimulation of Sustainable Energy Transition) subsidy scheme
extended to include renewable hydrogen production.
Northern
Netherlands
6 GW electrolyser capacity
by 2024; 40 GW by 2030
Norway A portion of NOK 3.6 billion (USD 380 million) green restructuring package to
support renewable hydrogen projects.
Portugal 10% to 15% in natural gas
networks; 2 GW to 2.5 GW
electrolyser capacity; 50 to 100
fuelling stations by 2030
EUR 7 billion (USD 8.6 billion) investment in renewable hydrogen by 2030.
Spain 4 GW electrolyser capacity
and 25% in industry by 2030
EUR 1.5 billion (USD 1.8 billion) support for the period 2021-2023.
United
Kingdom
5 GW electrolyser capacity
by 2030
GBP 12 billion (USD 15 billion) plan to heat homes with renewable hydrogen.
Hydrogen Supply programme allocates a portion of GBP 28 million
(USD 36.5 million) for two projects.
United States USD 64 million for 18 projects.
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TABLE 5.
Targets and Policies for Renewable Hydrogen, 2020
Note: This table includes details only on renewable hydrogen targets and policies. For additional details, see GSR 2021 Data Pack.
1 France's targets are for "decarbonised" hydrogen, which may include hydrogen produced by nuclear energy.
Source: See GSR 2021 Data Pack at www.ren21.net/gsr-2021.
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RENEWABLES 2021 GLOBAL STATUS REPORT
TRANSPORT
Globally, the transport sector has the lowest share of renewable
energy and accounts for around one-quarter of global energy-
related greenhouse gas emissions.85 Although renewable
energy policies in the sector have been expanding, most
policies continue to focus on road transport, with few directly
supporting renewables in rail, aviation and shipping. As of the
end of 2020, the share of renewables in the transport sector was
3.7%, unchanged from the year before. (p See Global Overview
chapter.) This section covers renewable energy transport
policies enacted at the national and provincial/state levels.
(k See Reference Table R8 in GSR 2021 Data Pack.)
ROAD TRANSPORT
Polices to incentivise renewables in road transport include
policies directly supporting biofuels and the use of renewable
electricity in electric vehicles, as well as some climate change
policies, such as fossil fuel bans, carbon pricing and requirements
for "zero-emission" vehicles. (p For climate policies that support
renewables, see Renewable Energy and Climate Change Policy
section in this chapter.)
Biofuels in Road Transport
In 2020, biofuels continued to make the largest contribution
of renewable energy to the road transport sector. Policies
supporting the production or use of biofuels include biofuel
blending targets, biofuel blending mandates, support for
advanced biofuels, financial incentives, public procurement
programmes, and support for biofuel production, fuelling and
blending infrastructure.
At least three new biofuel blending targets were announced in
2020. The United States set a target for biofuels to make up 15%
of US transport fuels by 2030 and 30% by 2050.86 Zimbabwe
launched a national biofuels policy, which includes targets for
ethanol blending of up to 20% and for biodiesel blending of up
to 2% by 2030.87 Paraguay established a law requiring biodiesel
blending of 4% in 2021 and 5% in 2022, up from 3% in 2020.88
Biofuel blending mandates remained the most widely used
policies for ensuring renewable content in road transport.
Overall, 65 countries had blending mandates as of the end of
2020 (unchanged since 2017). (p See Figure 14 and Reference
Table R8 in GSR 2021 Data Pack.) While no new countries added
biofuel blending mandates during 2020, some that already had
a policy either added new mandates or targets or strengthened
existing ones.
At least 28 countries revised their existing mandates during
the year. Early in 2020, Brazil increased its minimum biodiesel
blend from 11% to 12% (although, as a result of the COVID-19
crisis, the country later temporarily reduced it to 10%).89 Belgium
increased its biofuel blending mandate from 8.5% to 9.55%,
while Cyprus raised its mandate from 5% to 7.3%.90 Indonesia
increased its biofuel blending mandate to 30%, up from 20%.91
At the sub-national level, Ontario (Canada) raised its petrol
blending mandate from 5% to 10%.92
FIGURE 14.
National and Sub-National Renewable Transport Mandates, End-2020
Note: Shading shows countries and states/provinces with mandates for either biodiesel, ethanol or both.
Source: REN21 Policy Database. See Reference Table R8 in GSR 2021 Data Pack.
National biofuel blend
mandate, 10% or above
National biofuel blend
mandate, below 10%
Sub-national biofuel
blend mandate only
No policy
Countries with existing
advanced biofuel mandates
74
i The Free Zone guarantees the maintenance of the legal conditions of the project for 30 years and contributes to the competitiveness of the project.
ii In this section, EVs are defined as battery electric vehicles and plug-in hybrids.
iii Austria, Germany and Japan
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By the end of 2020, 11 countries (and the EU) had targets in
place for advanced biofuels (up from 10 countries in 2019),
and 17 countries had mandates in place for advanced biofuels.
(k See Reference Table R8 in GSR 2021 Data Pack.) Only one
new country, Latvia, adopted an advanced biofuels target in
2020: the country’s national energy and climate plan (NECP)
included a target of 3.5% advanced biofuels and biogas in
the transport sector’s final energy consumption by 2030.93
Financial incentives supporting the production and use of
biofuels are less common than blending mandates but were
extended in some countries. Sweden extended its tax exemption
for liquid biofuels to the end of 2021, and Iowa (US) extended a
fuel tax incentive for diesel sold in the state containing at least 11%
biodiesel.94 Thailand announced plans to revoke the seven-year
time frame for ending biofuel subsidies and to instead maintain
the subsidies until sometime between 2022 and 2026.95
Some jurisdictions implemented public procurement
programmes to support biofuels. At the national level, the
Finnish postal service committed to using renewable diesel to fuel
its light delivery fleet.96 Additional public procurement initiatives
related to transport took place at the local level, although more
often for EVs than for biofuels. (p See Renewables in Cities 2021
Global Status Report.)
Some jurisdictions promote biofuels for road transport by
supporting biofuel production and infrastructure. In 2020,
Paraguay’s government granted “Free Zone”i treatment for
an advanced biofuels plant to produce renewable diesel and
renewable aviation kerosene.97 Brazil’s RenovaBio programme
became fully operational in 2020, with decarbonisation credits
being sold in the nation’s stock exchange.98
The United Kingdom announced funding for four plants
producing advanced biofuels.99 The United States committed
up to USD 75 million over five years for research on sustainable
bioenergy crops, and up to USD 100 million for ethanol and
biodiesel transport fuelling and biodiesel distribution facilities.100
At a sub-national level, Iowa committed USD 3 million to its
biofuel infrastructure programme for 2021.101
Electric Vehicles
Electric vehicleii policies became increasingly popular in 2020.
Although these are not renewable energy policies by themselves,
EVs can increase the penetration of renewables in transport to
the extent that the electricity used to charge them is generated
from renewable sources. Policies to support EVs include
targets, financial incentives, public procurement, funding for
charging infrastructure, free parking and preferred access for
EVs. Financial incentives and support for EV charging were the
most common forms of EV policy implemented during 2020.
(k See Reference Table R8 in GSR 2021 Data Pack.)
As in 2019, most of the EV policies implemented in 2020 lacked
a direct link to renewable electricity, although the number of
policies that do have a direct link increased from two countries to
threeiii by year’s end. Japan announced plans to increase subsidies
for EVs under the condition that the vehicles are charged with
renewable electricity – a policy type that previously was found only
in Austria.102 Additional support linking EVs to renewable electricity
occurred through state-owned and -operated transport companies.
India’s West Bengal Transport Corporation committed to using
solar PV electricity to recharge its EVs.103 In the United States, the
Delaware Transit Corporation provided USD 3.1 million to install
solar PV at its operations facility to help power electric buses.104
In jurisdictions with high shares of grid-connected renewable
electricity, EV policies and targets can indirectly support renewable
energy use in the transport sector even if not directly linked in the
same policy, as long as the jurisdiction is simultaneously targeting
increasing shares of renewable electricity.
By the end of 2020, at least 52 national or state/provincial jurisdictions
had targets for EVs, up from 38 in 2019, although not always
also targeting high renewable electricity shares.105 (p See Figure 15,
and Reference Tables R8 and R6 in GSR 2021 Data Pack.) At least
19 jurisdictions had targets for full bans on sales of internal
combustion engine vehicles (or for 100% sales of EVs), including
two adopted during 2020. (p See Renewable Energy and Climate
Change Policy section in this chapter.) At least 31 other jurisdictions
had lower targets for EVs, including 6 adopted during 2020.
Pakistan launched a plan to bring 500,000 electric motorcycles
and rickshaws and more than 100,000 electric cars, buses and
trucks into its transport system by 2025, with a target of 30% of all
vehicles running on electricity by 2030.106 Denmark committed to
a target of at least 775,000 electric or hybrid cars by 2030.107
National biofuel blend
mandate, 10% or above
National biofuel blend
mandate, below 10%
Sub-national biofuel
blend mandate only
No policy
Countries with existing
advanced biofuel mandates
By the end of 2020,
only 11 countries had
targets in place for
advanced
biofuels.
75
Level of national
renewable power
share targeted for
jurisdictions with
EV targets
1-10 %
11-20 %
21-30 %
31-40 %
41-50 %
51-60 %
61-70 %
71-80 %
81-90 %
91-100 %
Hainan Province Hainan Province
Balearic IslandsBalearic Islands
100% electric vehicle target or targeted ban
on internal combustion engine vehicles
Sub-national renewable
power target
RENEWABLES 2021 GLOBAL STATUS REPORT
FIGURE 15.
Targets for Renewable Power and Electric Vehicles, as of End-2020
Note: Renewable power targets include only targets for a specific share of electricity generation by a future year. Where a jurisdiction has multiple targets, the
highest target is shown. Nepal and Quebec show actual renewable power shares; both jurisdictions along with Iceland and Norway have already achieved
nearly 100% renewable power. Electric vehicle targets vary; for details, see Reference Tables R6 and R8 in GSR 2021 Data Pack.
Source: REN21 Policy Database. See Reference Tables R6 and R8 in GSR 2021 Data Pack.
Only
8 countries
with targeted bans on
internal combustion
engine vehicles have
100% renewable power
targets.
In 2020, several countries introduced financial incentives
for EVs as part of their COVID-19 recovery packages. (p See
Sidebar 3.) Among new financial incentives for EVs that were
unrelated to COVID-19, Poland introduced purchase subsidies
for electric cars, vans and taxis.108
Several governments announced plans for public procurement
of EVs. In Australia, the state government of New South Wales
tripled its public fleet procurement targets for hybrids and EVs
to around 900 new hybrid or EVs annually, with around 300 of
these vehicles being all-electric.109 The US state of New York
committed to providing USD 16.4 million for its public transport
authorities to procure electric buses.110
In 2020, at least 7 governments implemented policies to
support EV charging. In the United States, California provided
USD 233 million to install public EV charging stations, and
Hawaii passed a law to provide grants for adding and upgrading
charging infrastructure.111
Some jurisdictions developed an integrated set of policies
to promote EV adoption. As part of its 10-year climate plan,
Greece pledged EUR 100 million (USD 123 million) for purchase
subsidies for EVs (including electric taxis and motorbikes) and
for the installation of public EV charging stations across the
country, as well as tax deductions for EV charging.112 El Salvador
enacted a new law establishing preferential tax treatment for
electric and hybrid vehicles and ensuring dedicated EV parking
spaces in public (and some private) lots.113 At the sub-national
level, New Jersey (US) passed a law aimed at electrifying the
state’s transport sector, which included a target for 85% of
vehicles sold to be electric by 2040, financial incentives of up to
USD 5,000 for EV purchases and a commitment to install 1,400
public EV chargers.114
76
i Countries with existing biofuel targets in aviation include Brazil (10% by 2030), Finland (30% by 2030), Indonesia (5% by 2025) and Norway (0.5% by 2020 and
30% by 2030)
Level of national
renewable power
share targeted for
jurisdictions with
EV targets
1-10 %
11-20 %
21-30 %
31-40 %
41-50 %
51-60 %
61-70 %
71-80 %
81-90 %
91-100 %
Hainan Province Hainan Province
Balearic IslandsBalearic Islands
100% electric vehicle target or targeted ban
on internal combustion engine vehicles
Sub-national renewable
power target
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R AIL , AVIATION, SHIPPING AND POR T S
Although rail, aviation and shipping are the fastest growing
transport sectors and account for a rising share of total final
energy use in transport, they continue to receive much less
policy attention than road transport. This is in part because
road transport remains responsible for most transport energy
use, and because renewable fuel options for these other sectors
remain costlier than fossil fuels.115 Additional challenges include
the fragmented, international nature of rail, aviation and shipping,
which makes co-ordinated actions more difficult, and the lack
of commercially available renewable technologies that can be
applied cost-effectively at scale.116
Most renewable energy initiatives in the rail sector are aimed
at supporting renewable electricity. In 2020, just two countries
enacted new policies and targets to advance the use of
renewables in rail transport. India set a target to electrify 7,000
rail kilometres by 2020-2021 and to electrify all routes on its
broad-gauge rail network by 2023, while also advancing plans
to integrate rising amounts of renewable power capacity for
its operations as well as efficiency and other sustainability
improvements.117 France’s national railway company committed
to meeting a portion of its electricity needs using renewable
electricity and signed a renewable electricity power purchase
agreement to provide around 2% of the electricity consumption
of all national passenger trains.118 In the private sector, UK-based
Network Rail became the first railway organisation to set a
science-based target in line with the Paris Agreement’s goal to
limit global temperature rise to 1.5 degrees Celsius above pre-
industrial levels.119
During 2020, no jurisdictions adopted new targets to advance
the use of renewables in shipping, and only one country
added renewable energy policy support in the sector. The
Netherlands announced plans obliging suppliers of heavy fuel
oil and diesel for inland shipping to take part in its renewable
fuel scheme.120 A few jurisdictions advanced policy support for
the use of renewables in ports. The Spanish Port Authority of
Valencia committed to building 8.5 MW of solar PV at two of
its ports on Spain’s coast, and Portugal and the Netherlands
signed a memorandum of understanding to connect Portugal’s
renewable hydrogen project with a seaport in the Netherlands.121
Only one country had a new biofuel blending policy for aviation
by year’s end, with Norway’s blending mandate of 0.5% biofuels
in all aviation fuel entering into force in 2020.122 By year’s end,
only four countries had biofuel targets for the aviation sectori.
However, other plans to support renewables in aviation advanced.
For example, the EU held a public consultation for its draft plan
(ReFuelEU) to cut emissions 55% (replacing a previous target of
40%) and to scale up the use of renewable biojet fuel (also called
sustainable aviation fuel), including through a blending mandate,
auctioning mechanism, funding and monitoring.123
At the national level, France was in the process of adopting
legislation as part of its 2021 budget that would require planes
that refuel in the country to use at least 1% sustainable aviation
fuel from 2022, with the blend increasing to 2% by 2025, 5% by
2030 and 50% by 2050.124 Germany published a draft law that
would require airlines to increase sustainable aviation fuel of
non-biogenic origin to 0.5% by 2025, 1% by 2028 and 2% by
2030.125 Sweden planned to introduce an emission reduction
requirement for aviation fuel sold in the country of 0.8% in
2021 and increasing to 27% by 2030.126 Meanwhile, the United
Kingdom’s Jet Zero Council, a public-private partnership, began
supporting sustainable aviation fuel through R&D.127
Alongside the somewhat slow public policy support for
renewables in the rail, shipping and aviation sectors, several
private sector players moved forward on their own to
implement initiatives and programmes to support the uptake
of renewables in transport. (p See Transport section in Global
Overview chapter.)
77
i Distributed generation, also called decentralised generation, refers to generation of electricity from sources at a relatively small scale and near the point of
consumption, as opposed to centralised generation sources such as large power plants. Distributed generators can be renewable (e.g., rooftop solar PV) or
fossil-based (e.g., distributed natural gas generation).
ii A utility is defined as an entity engaging in the generation and/or delivery of energy (including, but not limited to, electricity and natural gas) to consumers in a
specific geographical area/jurisdiction. Because utilities can be generators, distributors and retailers of energy, they often own and operate network infrastruc-
ture. Utilities can be publicly or privately held, and in many cases governments or municipalities still hold a large (or majority) stake in a private utility. Utilities
traditionally have been state-owned, vertically integrated monopolies. However, since the 1990s many jurisdictions have adopted reforms including unbundling
of the energy sector and liberalisation of the energy market, generally giving consumers more choice in electricity and gas suppliers.
RENEWABLES 2021 GLOBAL STATUS REPORT
POWER
As in previous years, the power sector continued to receive
the most renewable energy policy attention in 2020. Policies
to support renewable electricity generation include targets,
renewable portfolio standards (RPS), feed-in policies (tariffs and
premiums), auctions and tenders, renewable energy certificates
(RECs, or Guarantees of Origin – GOs), net metering, financial
incentives (such as grants, rebates and tax credits) and policies
to encourage self-consumption – as well as various enabling
policies.
A global trend in the power sector is the increasing decentralisation
of power generation. The uptake of renewable distributed
generationi is accelerating, particularly for larger commercial and
industrial consumers but also for residential consumers; however,
it still accounts for only a small share of electricity generation
worldwide.128
Targets continued to be a popular form of intervention to spur
investments in both centralised and distributed renewables.
By the end of 2020, 137 countries had some form of renewable
electricity target (down from 166 countries in 2019). (k See
Reference Table R6 in GSR 2021 Data Pack.) In addition, many
electric utilitiesii (both private and government-owned) have set
targets for increasing shares of renewable power.129 (p See Box 5.)
Of the countries and states/provinces that set new renewable
power targets in 2020, 2 set targets for 100% (or more) renewable
electricity. Austria’s new target for 100% renewable electricity by
2030 represents an almost 50% increase of renewable electricity
from 2020 levels.130 Nauru committed to 100% renewable energy
by 2050, In line with its target for net zero greenhouse gas
emissions by that year.131 At the sub-national level, the governor
of Rhode Island (US) signed an executive order for renewables to
provide all of the state’s electricity by 2030.132 The Australian state
of Tasmania announced a renewable power target of 200% by
2040, to be fulfilled in part by exporting excess renewable power
to other parts of the country.133
BOX 5. Utility-Led Activity to Support Renewables
In some places, electric utilities are responsible for the
infrastructure needed to deliver electricity to consumers, and
they may own the generation systems as well. Utilities thus
have an important role to play in enabling increased uptake
and integration of renewables. In some jurisdictions, utilities’
roles and responsibilities are changing in response to both
the proliferation of distributed energy resources and rising
electrification of transport and heating.
Utilities can play a key role in encouraging the integration
and use of renewables by implementing their own renewable
energy targets. For example, Ørsted in Denmark set a target
for more than 99% renewable energy generation by 2025
and had already reached a 75% share as of 2018. In Uruguay,
UTE set a target of 100% renewable electricity generation,
98% of which was achieved by 2017. Greece's biggest power
utility (51% government owned) pledged to shut down most
of its coal-fired plants by 2023 and committed EUR 3.4 billion
(USD 4.2 billion) to expand its use of renewables and
modernise the Greek distribution grid.
At a sub-national level, by the end of 2020 at least 19 US
utilities had committed to targets of 50% or 100% renewable
generation in the coming decades, including at least 6
that have set net zero emission targets. While some have
committed to phasing out “coal-only” plants, many still plan
to continue building natural gas plants and infrastructure and
are relying largely on offsets to reach net zero goals.
Source: See endnote 129 for this chapter.
78
i US states and jurisdictions with 100% renewable or “carbon-free” electricity targets include California, Hawaii, Maine, Nevada, New Mexico, New York, Virginia,
Washington and the District of Columbia.
ii Feed-in policies may focus on a certain type or scale of renewable energy technology or may apply to many types and scales of technologies.
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Many other countries set targets in 2020 for renewable electricity
shares lower than 100%, demonstrating the scope of ambition
among governments around the world. Zimbabwe set a target
for 16.5% renewable installed power capacity by 2025 and 30%
by 2030.134 Saudi Arabia announced a target of 50% renewable
electricity generation by 2030, and Israel set a target of 30%
renewable electricity by 2030, with an intermediate target of 20%
for 2025.135 Papua New Guinea committed in its updated NDC to
raising the share of grid-connected renewable power capacity
from 30% in 2015 to 78% in 2030 (although down from its earlier
target of 100% renewable electricity by 2030), conditional upon
funding support from other nations.136
In Asia, the Republic of Korea’s ninth long-term energy plan
included targets for expanding the share of renewables in the
electricity mix from 15.1% in 2020 to 40% by 2034.137 Japan
announced a target for 50% renewable electricity generation
by 2050 as a means of achieving its carbon neutrality goal.138
In Uzbekistan, a new strategy on electrical generation includes
targeted shares of 8% solar power and 7% wind power in total
electricity generation by 2030.139
Several targets were set or revised in Europe. The United Kingdom
announced a new wind power capacity goal that boosts the
previous target for 30 GW of offshore wind by 2030 to 40 GW.140
Hungary’s new climate change strategy sets a target for 90%
fossil fuel-free electricity production by 2030 (to be achieved
through nuclear as well as renewable power).141 Regionally, the
EU raised its offshore wind power capacity target to 60 GW by
2030 (up from the existing 2020 capacity of 25 GW) and 300 GW
by 2050, and set targets for ocean power capacity of 1 GW by
2030 and 40 GW by 2050 (up from the existing 2020 capacity of
around 11 MW).142
In the United States, the state of Arizona approved a plan for
100% “carbon-free” power by 2050 (including nuclear as well
as renewables).143 Virginia set a 100% carbon-free electricity
target through its renewable portfolio standard (RPS), as well
as targets for scaling up investment in energy efficiency, energy
storage, and solar and wind power.144 Virginia joined at least 8
other US jurisdictionsi that had already made 100% carbon-free
electricity RPS commitments (many of which include 100%
renewable electricity), and at least 12 additional states were
considering such commitments by mid-2020.145
Feed-in policiesii, including feed-in tariffs (FITs) and feed-in
premiums (FIPs), can be used to promote both large-scale
(centralised) and small-scale (decentralised) renewable power
generation. Although these remain among the most widely used
policy mechanisms for supporting renewable power, the trend
continued away from administratively set feed-in pricing policies
to the use of competitive tenders or auctions for large-scale power
generation.146 (p See Figure 16.) FITs nevertheless remained
popular in 2020 and by year’s end were in place in 83 jurisdictions
at the national and state/provincial levels (unchanged from 2019).
(k See Reference Table R10 in GSR 2021 Data Pack.)
FIGURE 16.
Renewable Energy Feed-in Tariffs and Tenders, 2010-2020
Note: A country is considered to have a policy (and is counted a single time) when it has at least one national or state/provincial-level policy.
Source: REN21 Policy Database. See Reference Tables R10-R11 in GSR 2021 Data Pack.
Number of countries
Feed-in tari
/ premium payment Tendering
83
116 The shift towards
competitive
auctions
and tenders
continued
in 2020.
120
100
80
60
40
20
0
2017 2019 20202015201320112010 2018201620142012
79
i Under Japan’s FIT programme, the purchase price for the end-user of electricity is determined at a fixed rate regardless of the variation in market prices. Under the
new FIP programme, renewable energy projects will receive a certain premium on top of the market price for the electricity that they generate starting in 2022.
ii Vietnam increased the FIT for biomass power projects and set new FIT rates for utility-scale, rooftop and floating solar PV installations.
iii Ukraine reduced FIT payments by: 7.5% for solar projects with installed capacity below 1 MW and wind projects commissioned during 2015-2019; 15% for
solar projects with installed capacity exceeding 1 MW; and 2.5% for plants that begin operation up to the end of 2022.
iv The six countries that held auctions for the first time in 2020 were Bhutan, Croatia, Mozambique, Myanmar, Philippines and the Slovak Republic. See Reference
Table R11 in GSR 2021 Data Pack.
v Typically, under a net metering arrangement, customers have lower electricity bills because they generate a portion of their own power. However, these
customers may not be covering as much of the costs to maintain grid infrastructure as those who do not self-generate, and these costs are then shifted
to these other customers. Some governments have chosen to counteract this by charging a fee to net-metered customers.
RENEWABLES 2021 GLOBAL STATUS REPORT
During 2020, at least nine countries took new action on renewable
energy feed-in policies. In at least four countries, these policy
changes were to support or maintain existing programmes. Japan
committed to transitioning its FIT to a FIP programmei starting in
2022, and Vietnam set new rates for its FIT programme, ensuring
its continuation following a period of policy uncertaintyii.147 Turkey,
which previously had planned to end its FITs in 2020, allocated
TRY 3.9 billion (USD 570 million) to the programme and extended
it until 30 June 2021.148 Moldova approved 15-year FITs for
renewable energy projects of 1 MW or less.149
In contrast, at least five countries, almost exclusively in Europe,
cut back support for FITs by either reducing existing payments
or cancelling their programmes in favour of auctions or tenders.
The Czech government announced retroactive cuts for FITs
granted to existing solar PV, wind and hydropower projects, and
France retroactively cut FIT contracts signed between 2006
and 2010 for solar PV projects larger than 250 kilowatts (kW).150
Ukraine reduced its FIT payments for some wind and solar
projectsiii and announced that, starting in 2022, the FIT for
ground-mounted solar projects of 1 MW-plus would be
replaced by the country’s auction regime (which came into
force in January 2020).151 Switzerland provided CHF 470 million
(USD 532 million) to eliminate the waiting list for FIT contracts
for small-scale solar PV systems, but also announced plans
to replace FITs for large-scale solar PV with an auction
mechanism.152 Outside of Europe, China announced plans to
phase out FITs for solar PV starting in 2021.153
Meanwhile, at least 33 countries held renewable energy
auctions or tenders at the national or sub-national levels
during 2020 (down from 41 countries in 2019). At least 3 of these
auctions or tenders were technology-neutral. (k See Reference
Table R11 in GSR 2021 Data Pack.) Many of the auctions and
tenders took place in Africa, including in Angola, Chad, Djibouti
and Nigeria, continuing the trend from previous years.154
At least 6 countriesiv adopted renewable energy auctions or
held auctions for the first time. For example, the Slovak Republic
launched its first technology-neutral, large-scale renewable
energy auction.155 Bhutan launched its first tender for renewable
power capacity to build the country’s first solar PV plant, and
the Philippines published a policy governing “green energy”
auctions, the first of which was expected to be held in 2021.156
Croatia introduced a tender scheme in which renewable energy
and co-generation projects will be awarded a FIP above spot
market prices.157
Some governments
modified their auction
design in 2020. Germany
launched its first tender
under a new technology-
neutral innovation auction
programme, which grants
a fixed market premium
on top of spot market
prices (instead of the
sliding FIP awarded via
traditional renewable
energy auctions).158 The UK government decided to allow solar
PV, onshore wind power, hydropower, landfill gas, sewage gas
and energy from waste to participate in the country’s 2021
power capacity auction, for the first time since 2015.159
Most net metering policies compensate the owners of
renewable power systems for surplus electricity fed into the grid.
These policies often do not distinguish between centralised/
decentralised and large-/small-scale generation, although in
some jurisdictions the focus is exclusively on small-scale or
distributed renewable energy. Of the net metering policies that
do not distinguish between size or type of generation, 7 new
programmes were added in 2020, bringing the total number
of countries, states and provinces with net metering policies
to 72 by year’s end (compared to 70 in 2019).
During 2020, Botswana launched a new net metering programme
for both large and small rooftop solar PV systems.160 Tunisia issued
a decree allowing private companies that generate renewable
power for their own use to sell any excess generation to the
national utility under net metering rules.161 Zimbabwe launched a
net metering programme for rooftop solar PV, and Saudi Arabia
established a new net billing programme for small-scale (1 kW
to 2 MW) distributed solar PV.162 At the sub-national level, Kerala
(India) introduced a net metering programme for residential
systems under 1 MW, and the US state of Virginia expanded its
net metering cap from 1% to 6%.163
Despite the popularity of net metering in many places,
some jurisdictions have begun to transition away from these
programmes or have modified them to charge customers fees
for participatingv. Dubai (United Arab Emirates) announced that
its net metering programme will no longer apply to large-scale,
groundmounted projects and capped the maximum capacity
for rooftop PV systems at 2,080 kW.164 Egypt confirmed plans to
impose a “merger fee” on net-metered solar PV systems in the
country, although as of October 2020 the fee had not yet been
determined.165 The Belgian region of Wallonia also announced
a fee for net-metered systems, which the government will
reimburse at least partially until 2024.166
At least 4 countries
strengthened support for
feed-in policies
in 2020, while 5 countries
cut back support.
80
i Renewable energy generated will count towards the targets for both the host and the contributing states, with the split based on the share of investment.
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Some US states have pulled back from net metering, either
implementing caps or adopting successor policies. For example,
Kentucky committed to establishing new crediting structures
based on dollar value rather than kilowatt-hour netting.167
Virginia enacted a bill directing regulators to develop a net
metering successor when a certain installed capacity threshold
is reached, while Illinois hit its net metering cap and initiated a
process to transition away from net metering.168 Utah established
a net metering successor that provides compensation at a
rate between the retail cost and the avoided cost for exported
energy.169 New York approved an alternative to net metering for
residential and small commercial customers that will include
new monthly fees, but it delayed implementation to 2022 due
to the COVID-19 crisis.170 Arkansas regulators allowed utilities to
propose net metering alternatives beginning in 2023.171
Financial incentives for renewable power were especially
important in 2020 as a result of the COVID-19 pandemic. While
many of these incentives were tied to economic recovery
packages, not all were. For example, the EU, as part of its Green
New Deal, released details of a new financing mechanism
intended to bring together renewable energy investors and project
developers through regular public tenders and to allow Member
States to invest in renewables projects in other countriesi.172
Within Europe, Austria doubled the budget for its residential
solar subsidy programme (capacities up to 5 kW), bringing
the rebate for installed grid-connected capacity to EUR 250
(USD 307) per kW and for systems integrated into buildings to
EUR 350 (USD 429) per kW.173 Greece allocated EUR 850 million
(USD 1,044 million) for homeowners to install solar PV systems
and energy storage on residences.174 The Netherlands doubled the
funding available under its green energy subsidy programme to
EUR 4 billion (USD 4.5 billion), and Spain provided EUR 181 million
(USD 222 million) for renewable energy projects in seven regions.175
Switzerland provided CHF 470 million (USD 532 million) to
expand renewable energy, with a focus on new solar PV systems,
and allocated CHF 46 million (USD 52 million) to its residential
and commercial rooftop rebate programme to stimulate
demand.176 The United Kingdom, meanwhile, set out plans to
become the world leader in wind energy, including committing
GBP 160 million (USD 217 million) to upgrade ports and
infrastructure along coastlines to increase offshore wind power
capacity.177
Elsewhere, Colombia made it easier to access tax incentives for
renewables by halving the time required to secure tax deductions,
customs exemptions and accelerated depreciation rates for
renewable power technologies.178 Turkey slashed the administrative
fee charged to owners of rooftop solar PV systems (10-100 kW),
reducing it from TRY 529 (USD 72) to TRY 278 (USD 38).179
Jordan launched a programme offering 30% rebates for installing
residential solar PV systems below 3.6 kW, and Israel committed
ILS 80 billion (USD 25 billion) to additional solar PV deployment to
support a target of 30% renewable power by 2030.180
81
i RECs are market-based instruments that represent the property rights to the environmental, social and other non-power attributes of renewable electricity
generation. A REC certifies the ownership of 1 megawatt-hour of renewable electricity. Unbundled RECs may be bought and sold separately from the physical
sale of electricity.
ii A unit (for example, a REC or a greenhouse gas emission reduction) is considered “additional” if it arises because of the incentives associated with the
existence of a specific policy rather than as part of a business-as-usual practice.
iii Communities may vary in size and shape (for example, schools, neighbourhoods, city governments, etc.), and projects vary in technology, size, structure,
governance, funding and motivation. See REN21’s Renewables in Cities Global Status Report.
iv Virtual net metering utilises the same compensation mechanism and billing schemes as net metering without requiring that a customer’s distributed general
system (or share of a system) be located directly on site.
v Shared ownership refers to the collective ownership and management of renewable energy assets.
vi These energy communities will enable users to co-ordinate a shared solar PV array with a single grid connection to inject surplus power back into the
electricity network, and also allow for distributed systems to be connected at different locations from their consumers.
RENEWABLES 2021 GLOBAL STATUS REPORT
At a sub-national level, the Indian state of Uttar Pradesh
announced subsidies for residential solar rooftop projects
(between 1 kW and 10 kW), depending on the project size
and location.181 In Australia, New South Wales unveiled a
AUD 32 billion (USD 25 billion) plan to deliver 12 GW of new
renewable energy capacity and 2 GW of storage capacity by
2030, and Victoria adopted an interest-free loan programme
for landlords that will provide subsidies of up to AUD 3,700
(USD 2,835) for installing a rooftop solar PV system.182
China, in contrast, reduced some financial incentives for
renewables in 2020. It ended funding completely for new
offshore wind farms and halved its budget for subsidising
new solar power from CNY 3 billion (USD 460 million) to
CNY 1.5 billion (USD 230 million).183 Company efforts to meet
deadlines in China for the phase-out of the onshore wind power
feed-in tariff resulted in a spike in wind power investment
during the year.184 (p See Investment chapter.) However, China
also committed to increasing grants for solar and wind power
starting in 2021.185
In addition to net metering, other policies to encourage
renewable self-consumption have evolved as residential,
commercial and industrial power consumers become more
interested in generating their own power. In 2019, California
became the first jurisdiction to make solar PV mandatory for
newly constructed homes starting in 2020, although some
loopholes exist.186 The German state of Bremen passed similar
legislation in 2020 to require solar PV on new homes and public
buildings.187
Tradeable renewable energy certificates (RECs, also called
Guarantees of Origin or GOs in Europe)i also can be used to
support renewable electricity, although concerns have been
raised about additionalityii.188
Several countries and regions across all major continents already
permit the use of RECs, and in 2020 a few more countries
allowed their use.189
Bahrain announced the
issuance of the country’s
first-ever REC, through an
electronic platform.190 In
West Africa, companies
were able at the start of the
year to begin purchasing
RECs documented by
the International REC
Standard.191
COMMUNIT Y ENERGY ARRANGEMENTS
Through small-scale community energy arrangements, residents,
businesses and others located within a relatively small geographic
area are able to develop, own, operate, invest in and/or benefit
from a renewable energy projectiii. Policy support plays a crucial
role in these arrangements and includes measures supporting
self-consumption, virtual net meteringiv and various forms of shared
ownershipv of renewables, including community solar.192
In 2020, Chile introduced rules giving people who own small-
scale solar PV systems for self-consumption the option of
supplying power to multiple consumers, thereby creating “energy
communities”vi.193 France similarly updated its legislation to
allow consumers and producers of renewables to create energy
communities on low-voltage networks.194 Italy launched a pilot
programme that allows homes, businesses and public entities with
rooftop solar PV systems of 200 kW or less to own, generate, sell,
store and distribute renewable energy; to boost the development
of these energy communities, the government provides a 20-year
tariff of EUR 0.10 to EUR 0.11 (USD 0.12 to USD 0.14) per kWh of
power shared among members.195 Montenegro made it possible
for individuals who generate renewable electricity to store
and sell surplus power to others, either individually or through
aggregation with other generation systems.196 At a sub-national
level, the US state of Virginia established a multi-family shared
solar programme in 2020.197
Support for renewables in
community
energy
increased in at least
5 countries during 2020.
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SYSTEMS INTEGRATION OF VARIABLE
RENEWABLE ELECTRICIT Y
As the penetration of variable renewable energy (VRE) sources
such as solar and wind power increases, maintaining the
reliability of power systems may become more challenging and
costly.198 Successful integration of VRE is critical to ensuring
an efficient and effective power system.199 (p See Systems
Integration chapter.) Increasingly, jurisdictions with relatively high
shares of VRE (both large-scale/centralised and small-scale/
decentralised generation) have implemented policies to ensure
more successful VRE integration. This includes policies related
to the design and operation of power markets, transmission
and distribution system enhancements, and policies supporting
energy storage.200
Changes to power market rules can increase system flexibility
and control and make it easier for both centralised and distributed
VRE, as well as energy storage systems, to participate in
electricity markets. For example, in 2020 the US Federal Energy
Regulatory Commission expanded its access rules to enable
renewable distributed energy generators and energy storage to
compete in regional wholesale electric markets, alongside large-
scale generators.201
Policies to improve electricity infrastructure, including
policies aimed at expanding or modernising transmission and
distribution systems, also can facilitate VRE integration and boost
resilience.202 In 2020, India’s government-owned transmission
company approved seven new transmission projects to support
renewable generation projects in the country.203 South Africa’s
public utility Eskom announced plans for transmission expansion
to strengthen the grid and to connect 30 GW of additional
capacity, much of it expected to come from renewable energy
projects.204 In the United Kingdom, energy utility regulator Ofgem
unveiled a five-year funding package that provides more than
GBP 3 billion (USD 4.1 billion) for transmission grid upgrades
to ensure that the network can manage rising levels of VRE.205
In Australia, a number of states including New South Wales,
Queensland and Victoria announced that they would strengthen
transmission networks to support the deployment of planned
Renewable Energy Zones.206
Policies that promote energy storage deployment also help
with successful VRE integration, since storage can make it easier
to balance the supply and demand of renewable generation
and minimise the curtailment of electricity.207 In 2020, Turkey’s
government introduced new rules for the grid connection of
energy storage systems to encourage storage projects linked
to rooftop solar PV.208 New South Wales (Australia) announced
funding for four large-scale battery projects to support
renewables as the state transitions away from coal.209
Policies supporting solar-plus-storage explicitly link solar PV
and energy storage. In 2020, both Austria and Italy provided
financial support for solar-plus-storage installations. Austria
launched a EUR 36 million (USD 44 million) rebate programme
for small solar-plus-storage installations, and the regional
government of Lombardy (Italy) allocated EUR 20 million
(USD 25 million) in rebates to promote energy storage coupled
with residential and commercial solar PV.210
83
Country Regulatory Policies Fiscal Incentives and Public Financing
R
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ew
ab
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e
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c
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su
b
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d
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s
or
r
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at
es
High Income Countries
Andorra
Antigua and Barbuda E, P
Australia P, P*(N), T* , ,
6,
*
Austria E, P, HC(O), T 6 6,
Bahamas, The E, P
Bahrain E, P
Barbados1 E, P
Belgium E, E*, P(O), P*(O), HC, T 6
Brunei Darussalam E
Canada P* , , * 6, 6 ,
6,7,
* 7
Chile P , 6 6 , 6
Croatia E, P(O), HC(O), T 6 6
Cyprus E(N), P(O), HC(O), T(N)
Czech Republic E, P(O), HC(O), T 6 6
Denmark E, P(N), HC(O), T(O) 6 8, 9 , 6 6,
Estonia E, P, HC, T , , 6
Finland E, P(O), HC(O), T 6, 7 6,
France E, P(N), HC, T , 6 6 6
Germany E, P(N), HC(O), T 9 , 6,
Greece E, HC(O), P, T 8 6 , 6,
Hungary E(N), P(N), HC(O), T(N) , 6
Iceland E(O), T(O), HC(O), P(O)
Ireland E, P(N), HC(O), T(O) 8 6 6, 7
Israel E(N), P(N), T , 6 ,
Italy E, P, HC(O), T , 6
6, 7,
*,
Japan E, P , , 6
Korea, Republic of E, P 6
Kuwait P
Latvia E(N), P(O), HC(O), T(N)
Liechtenstein
Lithuania E, P, HC, T(O) 6 8 , 6 , 6
Luxembourg E, P(O), HC, T , , 6
Malta E, P(O), HC(O), T 6
Mauritius P 6
Monaco
Nauru
Netherlands E, P(O), HC, T(O) 6 8 6 6 6, ,
New Zealand P
Norway E(O), P(O), T(O), HC(O) 7 9 6
Oman P(N)
Palau E(O), P
Panama E
Poland E, P, HC(O), T , 6,
Portugal2 E, P, HC(O), T(N) , , 6
Qatar P
Romania E(N), P(O), HC(N), T(N) 6
San Marino
Saudi Arabia P ,
Seychelles E, P
Singapore P(O)
Slovak Republic E, P(O), HC(O), T 7 6
Slovenia E(N), P(O), HC(N), T(N) 6
Spain3 E(N), P(N), HC(O), T(N) , 6,
St. Kitts and Nevis
Sweden E(N), P, HC(O), T(O) O
Switzerland P 6
Taipei, China P n/a
Trinidad and Tobago P
United Arab Emirates P, P*(O) * ,
United Kingdom E(O), P(N), P*(O), T(N), HC(O)
8 ,
6, 7,
, *
United States T(N), P*(N) * * , , 9 ,
7, 7,
, *
6, 7,
*
Uruguay 6
RENEWABLES 2021 GLOBAL STATUS REPORT
TABLE 6.
Renewable Energy Targets and Policies, 2020
Note: Please see key on last page of table.
84
Country Regulatory Policies Fiscal Incentives and Public Financing
R
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ew
ab
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e
n
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R
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c
ap
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su
b
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d
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or
r
eb
at
es
Upper-Middle Income Countries
Albania E, T(O) ,
Argentina E, P 6 6 , 6
Armenia E, P 6
Azerbaijan P(N)
Belarus P
Belize P
Bosnia and
Herzegovina E(O), HC(O), T(O), P
Botswana P ,
Brazil P, T
Bulgaria E, P(N), HC, T(N) 6
China E(N), P(N), HC(O), T(O) ,
7 , ,
6,7,
Colombia E, P ,
Costa Rica P 6
Cuba P
Dominica
Dominican Republic E, P
Ecuador
Equatorial Guinea
Fiji E, P
Gabon E, P
Georgia E 6
Grenada P
Guatemala P
Guyana P
Indonesia E, P, T
Iran P(O)
Iraq P(O)
Jamaica P ,
Jordan E, P, HC(O) , 6
Kazakhstan P
Kosovo E(O), P(O), HC(O) n/a
Lebanon E, P(O), HC 6 6
Libya E, P, HC(O)
Macedonia, North E, P, HC(O), T(O) 6 6
Malaysia P, HC(O), T(O)
Maldives E, P(O)
Marshall Islands E, P(O)
Mexico E(O), P(O), HC, T(O) , 6,
Montenegro E(O), P(O), HC(O), T(O)
Namibia P
Paraguay T(N)
Peru
Russian Federation E(O), P
Samoa E
Serbia E(O), P, HC(O), T(O)
South Africa P 6
St. Lucia P
St. Vincent and the
Grenadines1 P(O)
Suriname P
Thailand E, P, HC, T , 6, 7
Tonga P
Turkey P, HC 8 , 6
Turkmenistan
Tuvalu E, P(O)
Venezuela
PO
LI
CY
L
AN
DS
CA
PE
02
TABLE 6.
Renewable Energy Targets and Policies, 2020 (continued)
Note: Please see key on last page of table.
85
Country Regulatory Policies Fiscal Incentives and Public Financing
R
en
ew
ab
le
e
n
er
g
y
ta
rg
et
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R
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E
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s,
c
ap
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su
b
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d
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s
or
r
eb
at
es
Lower-Middle Income Countries
Algeria P
Angola P
Bangladesh E, P(N) ,
Benin E, P
Bhutan E, P, HC
Bolivia P
Cabo Verde P
Cambodia E
Cameroon P
Comoros E, P
Congo, Republic of P
Côte d’Ivoire P
Djibouti E, P
Egypt E, P 6
El Salvador
Eswatini P
Ghana P
Honduras E, P
India E, P, P*, HC, T , * , , , 6, 7*
Kenya E, P, HC
Kiribati E, P
Kyrgyzstan
Lao PDR E
Lesotho P
Mauritania E(O), P(O)
Micronesia,
Federated States of E(O), P(O)
Moldova E(O), P(O), HC(O), T(O)
Mongolia E, P ,
Morocco P, HC(O) 6
Myanmar P
Nepal E(O), P
Nicaragua P
Nigeria P(N)
Pakistan E, P(N)
Palestine, State of 5 E, P(O)
Papua New Guinea E, P
Philippines E, P , 6
São Tomé and
Príncipe P
Senegal P
Solomon Islands E, P
Sri Lanka P(N), T(O)
Tanzania E, P
Timor-Leste E, P
Tunisia E, P , 6
Ukraine E, P(O), HC(O), T(O) 6
Uzbekistan E, P(N) ,
Vanuatu E, P
Vietnam E(N), P(N), T ,
Zambia
Zimbabwe T(N), P ,
RENEWABLES 2021 GLOBAL STATUS REPORT
TABLE 6.
Renewable Energy Targets and Policies, 2020 (continued)
Note: Please see key on last page of table.
86
Country Regulatory Policies Fiscal Incentives and Public Financing
R
en
ew
ab
le
e
n
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g
y
ta
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R
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P
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c
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su
b
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ie
s
or
r
eb
at
es
Low Income Countries
Afghanistan E, P
Burkina Faso E, P
Burundi E, P
Central African
Republic P
Chad P
Congo, Democratic
Republic of E, P
Eritrea P
Ethiopia E, P
Gambia E, P
Guinea E, P
Guinea-Bissau E, P
Haiti E, P
Korea, Democratic
People's Republic
Liberia E, P, T
Madagascar E, P
Malawi E, P, HC
Mali E, P
Mozambique P, HC, T
Niger E, P(O)
Rwanda E
Sierra Leone P, HC
Somalia P
South Sudan E, P
Sudan E, P
Syria P
Tajikistan P(O)
Togo E, P(O)
Uganda P
Yemen E(O), P, T(O), HC(O)
PO
LI
CY
L
AN
DS
CA
PE
02
1 Certain Caribbean countries have adopted hybrid net metering and feed-in policies whereby residential consumers can offset power while commercial
consumers are obligated to feed 100% of the power generated into the grid. These policies are defined as net metering for the purposes of the GSR.
2 FIT support removed for large-scale power plants.
3 Spain removed FIT support for new projects in 2012. Support remains for certain installations linked to this previous scheme.
4 State-level targets in the United States include RPS policies.
5 The area of the State of Palestine is included in the World Bank country classification as “West Bank and Gaza”.
6 Includes renewable heating and/or cooling technologies.
7 Aviation, maritime or rail transport
8 Heat FIT
9 Fossil fuel heating ban
Note: Countries are organised according to annual gross national income (GNI) per capita levels as follows: “high” is USD 12,536 or more, “upper-middle”
is USD 4,046 to USD 12,535, “lower-middle” is USD 1,036 to USD 4,045 and “low” is USD 1,035 or less. Per capita income levels and group classifications
from World Bank, “Country and lending groups”, http://data.worldbank.org/about/country-and-lending-groups, viewed May 2021. Only enacted policies are
included in the table; however, for some policies shown, implementing regulations may not yet be developed or effective, leading to lack of implementation or
impacts. Policies known to be discontinued have been omitted or marked as removed or expired. Many feed-in policies are limited in scope of technology.
Source: REN21 Policy Database. See GSR 2021 Data Pack at www.ren21.net/gsr-2021.
Existing national policy or tender framework
(could include sub-national)
Existing sub-national policy or tender framework
(but no national)
National tender held in 2020
Sub-national tender held in 2020
Targets
E Energy (final or primary)
P Power
HC Heating or cooling
T Transport
* Indicates sub-national target
(R) Revised
(N) New
(O) Removed or came to term
Renewable energy not included in NDC
Policies
New (one or more policies of this type)
* New sub-national
Revised (from previously existing)
* Revised sub-national
Removed
TABLE 6.
Renewable Energy Targets and Policies, 2020 (continued)
87
http://data.worldbank.org/about/country-and-lending-groups
http://www.ren21.net/gsr-2021
Ørsted’s strategic suppliers are asked to disclose their own emissions, set science-based carbon
reduction targets and use 100% renewable electricity in manufacturing, among other key requirements.
03
i Municipal solid waste consists of waste materials generated by households
and similar waste produced by commercial, industrial and institutional
entities. The wastes are a mixture of renewable plant- and fossil-based
materials; proportions vary depending on local circumstances. A default
value is often applied based on the assumption that 50% of the material is
“renewable”.
ii The traditional use of biomass for heat involves burning woody biomass
or charcoal, as well as dung and other agricultural residues, in simple and
inefficient devices to provide energy for residential cooking and heating in
developing and emerging economies.
03
Bioenergy involves the use of biological materials for
energy purposes. A wide range of materials can be
used, including residues from agriculture and forestry,
solid and liquid organic wastes (including municipal solid waste
(MSW)i and sewage), and crops grown especially for energy.1
Many different processes can convert these feedstocks into heat,
electricity and fuels for transport (biofuels). While some of these
processes are fully established, others are in the earlier stages of
development, demonstration and commercialisation.2
BIOENERGY MARKETS
Biomass provides energy for heating in industry and buildings,
transport and electricity production. Overall, bioenergy
accounted for an estimated 11.6%, or 44 exajoules (EJ), of total
final energy consumption in 2019 (latest available data).3 More
than half of this total bioenergy came from the traditional use of
biomassii, which provided around 24.6 EJ of energy for cooking
and heating in developing and emerging economies, notably in
Sub-Saharan Africa.4
MARKET AND
INDUSTRY TRENDS
Modern bioenergy provided 5.1% of
total global final energy demand in
2019, accounting for around half of all
renewable energy in final energy
consumption.
Modern bioenergy for industrial process
heat grew around 16% between 2009 and
2019, while bio-heat demand in buildings
grew 7% over the same period.
In 2020, global biofuel production fell
5%, with ethanol production down 8%,
while biodiesel production rose slightly to
meet increased demand in Indonesia, the
United States and Brazil.
Bioelectricity production grew 6% in
2020, with China the major producer.
K E Y FA C T S
03
BIOENERGY
89
i Modern bioenergy is any production and use of bioenergy that is not classified as “traditional use of biomass”. See footnote ii on previous page.
88.4%
Non-biomass
5.1%
6.5%
Modern
bioenergy
Non-
bioenergy
Traditional
biomass
Modern
bioenergy
4.0
9.0
1.7
ElectricityHeat,
buildings
Heat,
industry
Transport
100%
75%
50%
25%
0%
4.6
24.6Electricity
0.5%
1.2 % 1.0 %
2.5 %
Heat, industry
Heat,
buildings
Transport
Traditional
biomass
RENEWABLES 2021 GLOBAL STATUS REPORT
Other more modern and
efficient uses of bioenergyi
provided around half of all
renewable energy in final
energy consumption in
2019 – an estimated 19.5
EJ, or 5.1% of total global
final energy demand.5
(p See Figure 17.) Modern
bioenergy provided around
13.7 EJ for heating (7.3%
of the global energy
supply used for heating), 4.0 EJ for transport (3.3% of transport
energy needs) and 1.7 EJ for global electricity supply (2.1% of the
total).6 Modern bioenergy use has increased most rapidly in the
electricity sector – up 27% between 2010 and 2019 – compared
to around 15% growth for transport use and less than 5% for
bio-heat.7
BIO-HEAT MARKETS
The use of biomass for heating has changed relatively little in
recent years.8 (p See Figure 18.) The traditional use of biomass
in developing and emerging economies is to supply energy for
cooking and heating in traditional open fires or inefficient stoves.9
(p See Distributed Renewables chapter.) The amount of biomass
used in these applications has decreased some 9% since 2009,
from 27.0 EJ to an estimated 24.6 EJ in 2019.10
Because of the negative effects of the traditional use of biomass
on local air quality and public health, as well as the unsustainable
nature of much of the biomass supply, governments and
international organisations are making significant global efforts
to improve access to cleaner fuels for cooking and heating.11
These fuels include fossil-based liquefied petroleum gas (LPG),
electricity, and cleaner forms of biomass, such as ethanol fuels
and wood briquettes and pellets.12
Modern bioenergy can provide heat efficiently and cleanly for
industry and for residential, public and commercial buildings. The
final user can consume biomass directly to produce bio-heat in
a stove or boiler. Alternatively, bio-heat can be produced in a
dedicated heat or district heating plant (including through the
co-generation of electricity and heat using combined heat and
power (CHP) systems) and distributed through the grid to final
Note: Data should not be compared with previous years because of revisions due to improved or adjusted data or methodology. Totals may not add up due to
rounding. Buildings and industry categories include bioenergy supplied by district energy networks.
Source: Based on IEA. See endnote 5 for this section.
FIGURE 17.
Estimated Shares of Bioenergy in Total Final Energy Consumption, Overall and by End-Use Sector, 2019
The amount of
biomass used
for heating
has grown 11% since 2009.
90
i Excluding the contribution to building heating from district heating; see discussion later in this section.
15
12
8
4
0
Exajoules
2009 2010 2015 20192014 2017201620122011 2013
District heating
Buildings,
modern bioenergy
Total average
annual change:
Industry
+1.4%
+0.3%
+5.9%
+1.2%
M
AR
KE
T
AN
D
IN
DU
ST
RY
T
RE
ND
S
03
consumers. Most of the biomass used for heating is wood-based
fuel, but liquid and gaseous biofuels also are used, including
biomethane, which can be injected into natural gas distribution
systems.13
In 2019 (latest data available), modern bioenergy applications
provided an estimated 13 EJ of direct heat, an 11% increase from
2009.14 In addition to the direct use of bio-heat in industry and
buildings, bioenergy provided some 0.7 EJ to district heating
systems in 2019; 51% of this was used in industry and agriculture
and the remainder in buildings.15 Bioenergy is the major source of
renewable heat in district heating systems, accounting for 95% of
all renewable heat supplied.16 Its contribution grew 57% between
2010 and 2019.17
In 2019, 9.1 EJ of biomass was used to provide heat for industry
and agriculture, meeting a combined 9.5% of these sectors’ heat
requirements.18 Bio-heat demand in the two sectors has grown
16% since 2009.19 Modern bioenergy provided 4.7 EJ to the
buildingsi sector in 2019, or around 5.0% of its heat demand.20
The amount of bio-heat provided to buildings has increased 7%
since 2009.21
Although final data for 2020 were not available at the time
of publication, total energy use for heating was expected to
decrease around 3.1% due to the economic effects of the
COVID-19 pandemic.22 The decline was expected to be highest
in industry, down a projected 4.1%, due to the curtailment of
industrial production in most regions (except China).23 The use
of bioenergy for industrial heat was expected to fall by the same
percentage, but to hold its market share.24 Heat use in buildings
was projected to decrease 1.8%, with most of the decline
occurring in commercial heating because of increased working
and schooling from home.25 Total bioenergy consumption in 2020
was expected to remain at 2019 levels.26
Industry use of biomass for heat production is primarily in bio-
based industries, such as paper and board, sugar and other food
products, and wood-based industries. These industries often use
their wastes and residues for energy, including the “black liquor”
produced in paper manufacture.27
Bioenergy is not yet widely used in other industries. However,
biomass and waste fuels met around 6% of the cement industry’s
global energy needs in 2019.28 In Europe, these fuels provided
around 25% of the energy used in cement making in 2019.29 The
use of biomass and waste fuels for cement production in China
is also growing.30
Bioenergy use for industrial heating is concentrated in countries
with large bio-based industries, such as Brazil, China, India and
the United States. Brazil uses large quantities of sugarcane
Source: Based on IEA. See endnote 8 for this section.
FIGURE 18.
Global Bioenergy Use for Heating, by End-Use, 2009-2019
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RENEWABLES 2021 GLOBAL STATUS REPORT
residue (bagasse) from sugar and ethanol production to generate
heat in CHP systems, producing an estimated 1.6 EJ in 2019.31
India, also a major sugar producer, was the second largest user
of bioenergy for industrial heat (1.4 EJ), followed by the United
States (1.3 EJ), which has an important pulp and paper industry.32
Biomass can produce heat for space heating in buildings through
the burning of wood logs, chips or pellets produced from wood
or agricultural residues. The informal use of wood and other
biomass to heat individual residences is prevalent in developed
economies as well as in developing and emerging ones.33 This
can be a significant source of local air pollution if inefficient
appliances and/or poor-quality fuels are used.34 Stringent
national regulations are being introduced to control emissions
from small combustion facilities. Systems that can meet these
requirements are commercially available, but at a higher cost.35
Larger-scale systems, such as those used for district heating, can
meet air quality requirements more easily and economically.
Modern use of bio-heat in buildings has been concentrated in the
European Union (EU), which accounted for 47% of this total use in
2019, increasing 2% during the year to 3.8 EJ.36 Policy measures
that aim to promote renewable heat alternatives to meet the
requirements of the EU Renewable Energy Directive (RED) – such
as capital grants for biomass heating systems – have generated the
growth in biomass use. Limiting the use of oil and natural gas for
heating also plays an important role in stimulating alternative heat
sources including biomass.37 France, Germany, Italy and Sweden
accounted for around half of the EU’s bio-heat demand in 2019.38
Most of the biomass fuel used to heat buildings is in the form of
logs and wood chips. However, the use of wood pellets for heating
has been growing rapidly and was up 6% globally in 2019, to
around 19.2 million tonnes (345 petajoules, PJ).39 The bulk of the
pellets (77%) were used in residences, with the rest consumed
at commercial premises.40 The EU remained the largest user
(16.4 million tonnes or 294 PJ), with Italy still the world’s largest
market for pellet heating (3.4 million tonnes), followed by Denmark
and Germany (2.3 million tonnes each), France (1.8 million tonnes)
and Sweden (1.2 million tonnes).41 Despite growth in the use of
biogas for heating, and particularly in the production of biomethane
and its introduction into gas grids, biogas provided only 4% of bio-
heat in European buildings in 2019.42
North America was the second leading user of bioenergy in
buildings in 2019. More than 1.8 million US households (1.4% of the
total) relied on wood or wood pellets as their primary heating fuel,
and an additional 8% used wood as a secondary heat source.43
Use was concentrated in rural areas, with one in four rural US
households combusting wood for primary or secondary space
heating.44 Total wood use in the US residential sector amounted
to 0.55 EJ.45 In Canada, the residential heating sector used some
0.13 EJ of bio-heat from wood fuels in 2019.46 North America
was the second largest regional market for pellets for building
heating, up 4% in 2019 to 2.6 million tonnes (47 PJ).47 Smaller-
scale markets were found in non-EU Europe (0.9 million tonnes)
and Asia (0.3 million tonnes), principally in the Republic of Korea
(0.2 million tonnes) and Japan (0.1 million tonnes).48
Europe leads in the use of bioenergy in district heating. District
heating (from all sources) supplied around 12% of the EU’s
heat demand in 2018.49 The residential sector was the major
user of district heat (45%), followed by the industrial (33%) and
commercial and services (21%) sectors.50 District heating meets
at least 30% of heat demand in seven countries, including a 45%
share in Denmark.51
This provides an important market opportunity for biomass,
which supplied around 25% of all district heating in Europe in
2018 (620 PJ).52
Sweden was the largest user of bioenergy for district heating
(130 PJ) in 2018, followed by Germany, Denmark and Finland (75 PJ
each) and France (69 PJ), where the use of bioenergy grew 35%
between 2015 and 2019, promoted by the Fonds Chaleur support
system.53 Lithuania has the highest share of district heat from
biomass (65%, or 23 PJ); the country’s use of bioenergy for this
purpose has grown three-fold since 2010, driven mainly by the need
to reduce dependency on imported oil to lower costs and improve
energy security.54 Bioenergy use has led to a 60% reduction in
Lithuania’s carbon dioxide (CO2) emissions from heating.55
92
i This section concentrates on biofuel production, rather than use, because available production data are more consistent and up-to-date. Global production
and use are very similar, and much of the world’s biofuel is used in the countries where it is produced, although significant export/import flows do exist,
particularly for biodiesel.
ii Hydrotreated vegetable oil is also referred to as hydroprocessed esters and fatty acids (HEFA). It is also called renewable diesel, especially in North America.
iii Often referred to as renewable natural gas (RNG), especially in North America. See Glossary.
iv The meaning of the word “corn” varies by geographical region. In Europe, it includes wheat, barley and other locally produced cereals, whereas in the United
States and Canada, it generally refers to maize.
Average annual
growth
Energy content (exajoules)
HVO/HEFA
Biodiesel (FAME)
Ethanol
0
2
4
1
3
2016201520142013201220112010 2017 2018 2019 2020
4.1%
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TRANSPORT BIOFUEL MARKETS
Global productioni of liquid biofuels decreased 5% in 2020,
dropping from 4.0 EJ (161 billion litres) in 2019 to 3.8 EJ
(152 billion litres), as overall demand for transport fuels fell as
a consequence of the COVID-19 pandemic.56 While ethanol
volumes declined sharply in 2020, biodiesel production and
use held steady.57 Lower transport demand for diesel fuel was
offset by higher blending requirements and other factors, and
the production and use of hydrotreated vegetable oil (HVO)ii
increased significantly.
The United States remained the world’s leading biofuel producer,
with a 36% share in energy terms, despite a reduction in the
country’s ethanol production.58 The next largest producers were
Brazil (26%) followed by Indonesia (7.0%), Germany (3.4%) and
China (3.0%).59 In total, in 2020, ethanol accounted for around
61% of biofuel production (in energy terms), fatty acid methyl
ester (FAME) biodiesel for 33%, and HVO for 6%.60 (p See
Figure 19.) Other biofuels included biomethaneiii and a range of
advanced biofuels, but their production remained low, estimated
at less than 1% of total biofuels production.61
Global production of ethanol decreased 8%, from 115 billion litres
in 2019 to 105 billion litres in 2020.62 Ethanol is produced primarily
from corniv, sugar cane and other crops. The United States and
Brazil, the two leading
producers, accounted
for 51% and 32%,
respectively, of global
production, followed by
China, India, Thailand and
Canada.63
US ethanol production
fell 11% in 2020 to 53.2
billion litres, the lowest
level since 2014, from
59.7 billion litres in 2019.64 The country’s ethanol consumption
fell 12%, mirroring the 13% decline in petrol use in transport as
blending opportunities were constrained and ethanol prices fell.65
Many ethanol producers reduced output due to lower demand,
negative operating margins and limited storage capacities.66
Ethanol production in Brazil decreased 6% to 34.0 billion litres,
down from 36.0 litres in 2019.67 Overall, petrol consumption in
the country fell some 11% due to declining demand.68 The drop in
petrol use directly influences ethanol sales, as all petrol in Brazil
contains 27% ethanol by volume.69 Low oil prices also affect the
competitiveness of 100% ethanol, which is widely available in the
country.70 Most Brazilian ethanol comes from sugar cane, with
some 350 sugar ethanol mills operating nationwide.71
Note: HVO = hydrotreated vegetable oil; HEFA = hydrotreated esters and fatty acids; FAME = fatty acid methyl esters
Source: See endnote 60 for this section.
FIGURE 19.
Global Production of Ethanol, Biodiesel and HVO/HEFA Fuel, by Energy Content, 2010-2020
Although ethanol
production dropped
sharply in 2020,
biodiesel
production
remained steady.
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However, a growing share of ethanol is produced from corn,
and as of mid-2020 some 16 corn ethanol production plants
were in operation and 7 more under construction.72 Most of
the plants can process both sugar cane and corn. Corn-based
ethanol production in Brazil more than doubled in 2020, to
2.5 billion litres.73
China’s ethanol production increased 3% to 4.0 billion litres in
2020 to meet growing domestic demand.74 Petrol demand in the
country fell some 7%, but growth in ethanol demand continued
as 10% ethanol blends (E10) were extended to more provinces.75
Production capacity doubled between 2017 and 2020, and
several large new plants were in development.76
Ethanol production in India fell some 8% in 2020 to 1.8 billion litres,
as petrol demand dropped 13% and as lower oil prices reduced the
affordability of ethanol relative to unblended gasoline.77 Canadian
ethanol production remained stable in 2020, at 1.8 billion litres,
while in Thailand, production fell 9% to 1.5 billion litres.78
Global production of biodiesel increased slightly (less than 1%)
to 46.8 billion litres in 2020, up from 46.5 billion litres in 2019.79
Its production is more widely distributed than that of ethanol;
11 countries account for 80% of global biodiesel production,
compared to just 2 countries for ethanol.80 This is due to the wider
range of biodiesel feedstocks that can be processed, including
vegetable oils from palm, soy, and canola, and a range of wastes
and residues, including used cooking oil. In 2020, Indonesia
was again the lead biodiesel producer (17% of the global total),
followed by the United States (14.4%) and Brazil (13.7%).81 The
next largest producers were Germany (7.4%), France (5.0%) and
the Netherlands (4.6%).82
Despite an estimated 12% reduction in demand for diesel for
transport, Indonesia’s biodiesel production grew 11% in 2020, to
8.0 billion litres.83 In the face of growing dependency on imported
oil, the blending level in the country is being increased gradually
to prioritise domestically produced biodiesel, primarily from palm
oil. The diesel blending level was increased from 20% to 30% in
January 2020 and was expected to rise to 40%.84
While total US diesel demand fell 5% in 2020 due to the impacts
of the COVID-19 pandemic, biodiesel production in the country
rose more than 3% to 6.8 billion litres, boosted by the federal
Renewable Fuel Standard (RFS2) and by California’s Low
Carbon Fuel Standard (LCFS).85 In addition, the federal Biodiesel
Blender’s Tax Credit was reintroduced.86 Increased duties on
biodiesel imports from Indonesia and Argentina also favoured
US domestic biodiesel production.87
In Brazil, biodiesel production rose 9% to a record 6.4 billion litres
to meet increased domestic demand.88 The country’s biodiesel
blending requirement increased from 11% to 12% and was
scheduled to rise to 15% by 2023.89
In Germany, reduced diesel fuel use limited biodiesel demand,
and production fell an estimated 9% to 3.5 billion litres in 2020,
down from 3.8 billion litres in 2019.90 Production in France also
declined slightly to 2.4 billion litres, while production in the
Netherlands stayed stable at 2.1 billion litres.91
Argentina dropped from fifth to ninth place among producers
as biodiesel production decreased some 35% to 1.6 billion litres,
with US duties on biodiesel imports discouraging trade.92
HVO production, a process of hydrogenating bio-based oils fats
and greases, continued to grow sharply in 2020, rising 12% to
an estimated 7.5 billion litres, up from 6.5 billion litres in 2019.93
While early production capacity was concentrated in Finland,
the Netherlands and Singapore, HVO capacity in the United
States has increased rapidly in recent years, in line with the
surging US market for these fuels.94 HVO use in the country is
heavily incentivised by the RFS2, by California’s LCFS and by the
availability of an investment tax credit.95 US use of HVO under the
RFS2 grew some 48% in 2020, to 3.5 billion litres (114 PJ).96
Biomethane is used as a transport fuel mainly in Europe and
the United States (the largest producer and user of biomethane
for transport).97 US production and use of biomethane is also
stimulated by the RFS2 (which includes biomethane in the
advanced cellulosic biofuels category) and by California’s LCFS,
thereby qualifying for a premium.98 US biomethane use under the
RFS2 increased 24% in 2019 to around 41 PJ.99
In Europe, the use of biomethane for transport increased 74%
in 2019 to 14 PJ (latest data available).100 Sweden remained the
region’s largest biomethane consumer, using nearly one-third of
the total, followed by the United Kingdom (where biomethane
use increased five-fold in 2019), Germany and Italy (where use
rose from nearly zero to 1.7 PJ in 2019).101
Although efforts to develop other “advanced biofuels” continued,
and some new production
capacity was installed (p
see Industry section in
this chapter), these fuels
have been produced
and used only in small
quantities to date. For
example, the contribution
of cellulosic ethanol under
the US RFS2 scheme
declined by a factor of five
in 2020 to below 0.2 PJ.102
The United States and
Brazil, the two leading
producers of biofuels,
account for around 80% of
global
production.
94
Average annual
growth
Terawatt-hours
EU-28
Rest of World
China
South America
Rest of Asia
North America
0
400
600
200
300
500
100
201620152014201320122011 20192010 2017 2018 2020
6.3%
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BIO-POWER MARKETS
Global bio-power capacity increased an estimated 5.8% in
2020 to around 145 gigawatts (GW), up from 137 GW in 2019.103
China had the largest capacity in operation by the end of 2020,
followed by the United States, Brazil, India, Germany, the United
Kingdom, Sweden and Japan.104
Total bioelectricity generation rose some 6.4% to around
602 terawatt-hours (TWh) in 2020, from 566 TWh in 2019.105
(p See Figure 20.) China remained the leading producer of bio-
power, followed by the United States and then Germany, Brazil,
India, the United Kingdom and Japan.106
In line with the provisions of the country’s 13th Five-Year Plan
(2016-2020), China’s bio-power capacity rose 26% to 22.5 GW
in 2020, up from 17.8 GW in 2019.107 Generation increased 23%
to more than 111 TWh.108 In 2020, 77 additional projects, with
a combined capacity of 1.7 GW, were approved for financial
support in 20 provinces.109 They included projects using
municipal waste (1.2 GW), agroforestry raw materials (0.5 GW)
and biogas power generation (21 megawatts, MW).110
The United States had the second highest national bio-power
capacity and generation in 2020.111 The country’s 16 GW capacity
did not change significantly.112 Generation fell 2.5% to 62 TWh,
continuing the trend of recent years.113
Brazil was the third largest producer of bioelectricity globally,
with most of the country’s generation based on sugarcane
bagasse.114 Brazil’s generation fell an estimated 10% to 50 TWh in
2020, as sugar production and the related electricity generation
was reduced.115
In the EU, bio-power capacity grew around 4% in 2020 to 48 GW,
and generation increased 4% to 205 TWh, providing 6% of all
generation.116 This increase occurred as countries pushed to meet
the region’s mandatory national targets for 2020 under the RED.117
Germany remained the region’s largest bioelectricity producer,
mainly from biogas: capacity increased 400 MW in 2020 to
10.4 MW, and generation rose 0.8% to 51 TWh.118 Generation
surged in the Netherlands (up 90%) to 11 TWh as the volume
of wood pellets co-fired in large power stations increased
significantly, supported by the SDE feed-in premium scheme and
to help the country meet its obligations under the EU RED.119
In the United Kingdom, bio-power capacity grew 135 MW to
8.0 GW.120 Generation rose 5.5% to 39.4 TWh, with increases in
large-scale pellet-fired generation, biogas and MSW plants.121
In Asia, Japan’s growth in bio-power capacity and generation grew
slowly during 2020, with capacity rising 9% to 5.0 GW, and generation
increasing to 25 TWh.122 In the Republic of Korea, bio-power capacity
rose 3% to 2.7 GW, with generation up 30% to 12.3 TWh, supported
by the Renewable Energy Certificate Scheme and feed-in tariffs.123
In India, bio-power capacity increased marginally to 10.5 GW,
and generation remained stable at 45 TWh.124
The use of internationally traded pellets produced from wood and
agricultural by-products for power generation continued to grow.
In 2019, 18 million tonnes of pellets were used for power generation,
up 7% from the previous year.125 Nearly three-quarters of the
pellets were used in the EU, particularly in the United Kingdom
(8.5 million tonnes), Denmark (2.0 million tonnes) and the
Netherlands, where use more than doubled to 0.8 million tonnes.126
The rest were used in Japan (1.5 million tonnes) and the Republic
of Korea (0.9 million tonnes).127
Source: See endnote 105 for this section.
FIGURE 20.
Global Bioelectricity Generation, by Region, 2010-2020
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RENEWABLES 2021 GLOBAL STATUS REPORT
BIOENERGY INDUSTRY
Solid Biomass Industry
The companies that make up the solid biomass industry range
from small, locally based entities that manufacture and supply
smaller-scale heating appliances and their fuels, to major regional
and global players involved in the supply and operations of large-
scale district heating and power generation technology.
Most solid biomass projects rely on local feedstocks, such as
wood residues and sugarcane bagasse, which can be used where
they are produced. The growth in biomass pellet production to
serve international markets for heat and electricity production
is an important development in the sector, enabling countries
to scale up the use of bioenergy even when they have limited
national biomass resources.
In 2019, global production of biomass pellets reached an estimated
59 million tonnes.128 Production data for China are uncertain but
reached an estimated 20 million tonnes in 2018.129 Production in
the rest of the world grew 9% to 39.4 million tonnes in 2019.130 The
EU remained the largest regional producer (17 million tonnes),
with production rising 5% that year.131 Production from other
European countries rose 17% to over 4 million tonnes, with
production in the Russian Federation up 21%.132 North American
production increased 12% to 12.4 million tonnes.133
Excluding China, 19 million tonnes (5,326 PJ) of biomass
pellets were used worldwide to provide heat in the residential
and commercial sectors.134 Pellets also provided an estimated
7.5% of the biomass used to heat buildings.135 Worldwide,
18 million tonnes (31 PJ) were used for power generation, CHP
production and other industrial purposes in 2019.136
The United States was the world’s largest exporter of wood
pellets in 2020.137 While US pellet production decreased 2% to
9.3 million tonnes, exports rose 1% to 6.8 million tonnes.138
The wood pellet market for power generation continued to grow
in the EU, where power producers can co-fire pellets with coal or
convert coal plants, or build new plants that operate entirely on
pellets.139 The market also expanded in Japan and the Republic of
Korea, stimulated by favourable support schemes.140 By the end of
2020, Japan’s Ministry of Economy, Trade and Industry had approved
70 projects with a capacity of nearly 8 GW under the feed-in tariff.141
Debate continues regarding the carbon savings and other
environmental impacts related to pellet production from forestry
materials and their use in power generation.142 Starting in 2020, the
sustainability provisions in the EU’s RED included solid biomass,
setting tighter sustainability criteria; as of 2021, minimum greenhouse
gas reduction thresholds also were set for new projects seeking
national support.143 Sustainability criteria are being put in place in
Japan as well, which is expected to reduce the use of palm-based
products but increase the use of certified wood pellets.144
Liquid Biofuels Industry
The liquid biofuels industry produces ethanol, FAME biodiesel
and increasingly HVO. Together, these comprise nearly all current
global biofuels production and use. In addition, the industry is
developing and commercialising new types of biofuels designed
to serve new markets, notably for the aviation and marine
sectors. These offer improved results in terms of greenhouse
gas footprints and other sustainability criteria. There is a growing
interest in the production of bio-materials and chemicals as part
of the shift to a broader bioeconomy.145 (p See Box 6.)
In 2020, the industry was negatively affected by the lower
demand for transport fuels during the COVID-19 pandemic,
which constrained production and reduced profitability. At the
height of the 2020 crisis, more than half of US ethanol industry
production capacity was idled.146 For example, ADM announced
that it would idle four of its plants for at least four months in mid-
2020.147 Global ethanol prices fell 28% between January 2020 and
April 2020, before recovering to within 5% of the January value
by year’s end.148 In Brazil, ethanol demand was constrained and
prices fell as much as 19% in 2020, with more sugar cane used for
sugar than for ethanol production.149
By contrast, markets for FAME biodiesel were less affected by
the pandemic. Although fossil diesel demand also fell, biodiesel
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levels were maintained due to higher incentives or increased
blending mandates in key producing countries, such as the
United States, Brazil and Indonesia.150 Biodiesel production in
Argentina was affected by import duties in the United States.151
HVO production capacity rose sharply in 2020, driven by attractive
market incentives, particularly those provided by the US RFS2
and California’s LCFS and under the EU’s RED.152 Many plans for
new capacity were announced.153 Total HVO production capacity
reached an estimated 9.2 billion litres (0.3 EJ) in 2020.154 When
taking into account both the expansion of existing facilities and
new production sites, the additional capacity under construction
or being planned was estimated to reach more than 41 billion litres
(equivalent to 1.1 EJ per year) at the end of 2020.155 With these new
projects, total existing and planned HVO capacity is expected to
exceed that of FAME biodiesel and to equate to around 60% of
2020 ethanol production, underscoring a significant evolution of
biofuels in transport.156
Most of the existing and planned capacity is based on treating
vegetable oils, animal fats and other by-products with hydrogen
to produce HVO/HEFA, which then can be refined to produce
fuels with the same properties as fossil-based diesel, jet fuel and
other hydrocarbon products, including biopropane. When these
feedstocks are wastes or by-products (such as used cooking oil,
animal fats or tall oil), the greenhouse gas savings associated
with their use are much higher than for virgin vegetable oils,
such as palm or canola oil.157 The fuels then qualify for higher
credits under biofuels support schemes. For example, under the
California LCFS, HVO from used cooking oil qualifies for a credit
up to twice that for HVO produced from soy oil.158 Under the EU
RED, waste- and residue-based fuels are counted twice towards
national targets and can earn double credits under national
support schemes in member countries.159
In 2020, several companies
that produce HVO fuels
announced that new
capacity was available
or planned. For example,
Phillips 66 (US) announced
plans to extend production
capacity at its UK
Humberside plant from
57 million litres to 460
million litres per year and to
convert the Rodeo facility
at its San Francisco oil refinery to produce HVO and jet fuel.160
The Rodeo facility would be one of the world’s largest such plants,
producing 4 billion litres of the fuels from used cooking oils, fats,
greases and soy oils starting in 2024.161
Other oil majors are undertaking similar refinery conversions. Total
(France) announced plans in 2020 to convert its Grandpuits refinery
in the Seine-et-Marne department of France to produce biojet
fuel, with an investment of EUR 500,000 (USD 0.6 million).162 This
complements Total’s La Mède plant, which was converted in 2019 to
produce 570 million litres of HVO and biojet from palm oil and waste
fats and oils.163 ENI (Italy) converted its refineries in Venice and Sicily
to make HVO and is more than doubling its capacity in Venice to
more than 1.6 billion litres.164 Marathon Oil (US) planned to convert
its North Dakota plant to HVO by the end of 2020, with an annual
production capacity of 700 billion litres, along with its Martinez
refinery (California), which is expected to reach an HVO capacity of
some 3 billion litres by 2022.165 While most HVO projects are in the
United States and Europe, Pertamina (Indonesia) is developing two
projects in Indonesia, which will produce a combined 1.5 billion litres
of HVO from palm oil under the country’s strategy to increase the
share of biofuels in diesel to 40%.166
BOX 6. Bioenergy and the Bioeconomy
While bioenergy can directly replace fossil fuel use for
heating, transport and electricity generation, biomass-based
materials also could play an expanded role in the move to a
sustainable bioeconomy. This would lower greenhouse gas
emissions by reducing the use of fossil-based feedstocks for
materials such as plastics and by replacing energy-intensive
materials such as concrete and steel with wood- and
agricultural-based materials.
Policy emphasis on recycling bio-based materials (within
a circular economy) has increased, as has industry interest
in developing a wider range of high-value-added products
based on sustainably produced biomass feedstocks. Policy
measures are being developed to promote the bioeconomy
concept. The EU has drafted an integrated bioeconomy
strategy, which it views as contributing to the European Green
Deal, and the US Renewable Chemicals Act, introduced in
2020, provides tax credits for bio-based chemical production.
The growth of bioplastics is also a relevant trend. In 2020,
these represented around 1% of the more than 368 million
tonnes of plastic produced annually worldwide. Bioplastics
that are also biodegradable, such as polylactic acid (PLA),
polyhydroxyalkanoates (PHA) and starch-based plastics,
account for 60% of global bioplastics production.
Industrial investment and engagement in bioplastics
production grew in 2020. Braskem (Brazil), the world’s
largest bioplastics producer, produced 200,000 tonnes of
polyethylene from ethanol that year. UPM (Finland) also
announced a EUR 550 million (USD 644 million) investment
in a German plant that will convert wood to bio-monoethylene
glycol (BioMEG) and monopropylene glycol (BioMPG),
intermediates used to produce plastics utilised as fibre and
packaging material.
Source: See endnote 145 for this section.
Production of
HVO biodiesel
rose sharply in 2020,
driven by attractive market
incentives in the United
States and Europe.
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RENEWABLES 2021 GLOBAL STATUS REPORT
In addition to these projects, which hydrogenate oils and fats,
several other technological approaches that use a wider range of
feedstocks are being demonstrated and commercialised. Projects
designed to produce HVO and jet fuels by gasifying MSW or
forestry residue feedstocks and synthesising the resulting gas
via the Fischer-Tropsch process are under development. Their
aggregate capacity is over 1 billion litres of fuel and includes the use
of feedstocks such as forestry and timber residues and processed
MSW, which is less expensive and thus produces cheaper fuel.167
The Red Rock Biofuels (US) project in Lakeview, Oregon (US)
will convert 166,000 dry tonnes of waste woody biomass into 60
million litres of drop-in jet, diesel and petrol fuels to be supplied
under eight-year off-take agreements with FedEx and Southwest
Airlines.168 The project is based on gasification and Fischer-Tropsch
technology provided by Velocys (UK). Velocys has launched a
project at Immingham (UK) in collaboration with British Airways
PLC and Shell (Netherlands) to produce jet fuels from MSW
and is developing another in the US state of Mississippi that will
use paper and timber residues from local industries.169 In 2020,
Fulcrum Energy (US), which is developing two MSW projects in
the United States, began work to produce jet fuel from MSW in
Japan, in collaboration with Japan Airlines Marubeni, JXTX Nippon
OIL and JGC Japan.170
Three projects involving pyrolysis of wastes and other feedstocks
were under way in Canada and in the Netherlands at year-end
2020.171 The Lieksa plant of Green Fuel Nordic Oy (Finland), with a
capacity of 24 million litres per year, also began supplying fuel oil
(for heat) produced by the pyrolysis of wood residues.172
Other approaches include the conversion of ethanol to fuels such as
biojet. In 2020, the FLITE consortium, led by SkyNRG (Netherlands)
and Lanzatech (US), initiated a project in the Netherlands to build
an ethanol-to-biojet facility to convert waste-based ethanol to
sustainable aviation fuel, producing more than 30,000 tonnes per
year.173 The project received EUR 20 million (USD 23 million) in
grants from the EU’s Horizon 2020 programme.174
Only a small number of facilities producing ethanol from cellulosic
materials were operating successfully worldwide by the end of
2020.175 During the year, construction was under way at Clariant’s
(Switzerland) planned plant in Romania, and the company also has
licensed its technology for projects in Bulgaria and China.176
Despite the sharp drop in air travel and related fuel use in 2020,
the market for sustainable aviation fuels (SAF) – biofuels tailored
for use in aircraft engines – continued to expand, with seven fuel
pathways approved for use by year’s end.177 As of 2020, 45 airlines
had used SAF, and 7 airlines were actively investing in SAF
production capacity.178
Some 100 million litres of
SAF was expected to be
available for use in 2021.179
The availability of these
fuels has increased at
airports, with continuous
supply established in
2020 at San Francisco
International Airport and
at London Luton Airport.180
GASEOUS BIOMASS INDUSTRY
The gaseous biomass industry is involved mainly in producing
and using gas produced by the anaerobic digestion of biomass
feedstocks, which produces biogas, a mixture of methane, CO2
and other gases.181 The same process occurs in waste landfills, and
the resulting landfill gas can be collected and used – providing
energy while also reducing emissions from the landfill site. The
gases can be used directly for heating or power generation.
Alternatively, the methane component can be separated and
compressed and used to replace fossil gas by injecting it into
gas pipelines or for transport purposes. Biomethane production
totalled an estimated 1.4 EJ in 2018, or just over 1% of total global
fossil gas demand.182
Biogas can be used at a small scale in developing economies
as a sustainable fuel source for cooking, heating and electricity
production and to improve energy access. (p See Distributed
Renewables chapter.) In developed economies, most biogas is
used for power generation or in CHP systems, often stimulated
by favourable feed-in tariffs and other support mechanisms.183
The energy content of biogas upgraded to biomethane and used
for transport or injection into gas grids, primarily in the United
States and Europe, rose to around 170 PJ in 2020.184 Stimulating
this development are incentives that favour biomethane
production over power production, notably under the US RFS2
and the California LCFS, which offer larger incentives than those
for power or heat generation.185
US biomethane production capacity rose sharply in 2020, with
many new projects based on landfill gas, cattle waste, and other
wastes and residues. In total, 157 production facilities were
in operation during the year (up 78% from 2019), with another
76 projects under construction and 79 projects in the planning
phase.186 The total operating production capacity in 2020 was
more than 60 PJ.187
Biomethane
production
is rising, and accounts for
around 1% of total global
fossil gas demand.
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Recent projects illustrate that both specialist companies and
energy majors are involved in the rapidly growing US biomethane
sector.188 In August 2020, Republic Services and Aria Energy
(both US) announced a start-up project to process and purify
landfill gas from the South Shelby (Tennessee) landfill site; BP will
then inject the gas into the interstate natural gas pipeline grid and
market it to renewable energy customers.189 In September 2020,
Fortistar and Rumpke Waste and Recycling (both US) started
building a landfill gas project in Shiloh, Ohio that will extract and
capture waste methane and transform it into biomethane for
distribution to natural gas vehicle fuelling stations.190
In 2020, Aemetis (US) completed construction of two dairy
digesters and a pipeline to supply biomethane to provide
fuel for biomethane trucks and buses.191 Verbio (Germany)
announced the installation of an anaerobic digester at the former
DuPont cellulosic ethanol plant in Nevada, which will now use
100,000 tonnes of corn stover annually to produce biomethane
with the energy equivalent of 80 million litres of petrol.192
Biogas and biomethane installations also have grown rapidly in
Europe, which in 2020 was home to at least 18,855 biogas plants
producing 176 TWh, as well as 726 biomethane plants with a total
capacity of 64 PJ (an increase of 66 biomethane plants and 4 PJ
compared to 2019).193 Recent projects include Gasum’s (Finland)
construction of two new biogas plants in Sweden: a 120 gigawatt-
hour (GWh) plant that will produce liquefied biogas from manure
and food waste slurry from a local pretreatment plant, and a 70 GWh
plant established alongside a local farmer co-operative that will use
manure and other agricultural waste products.194 Weltec Biopower
(Germany), working with Agripower France, a local agroindustrial
firm, commissioned a EUR 11 million (USD 13 million) biomethane
plant in Normandy, France that processes around 70,000 tonnes
of substrates to produce biogas, which is then refined into
biomethane.195 The plant’s raw material mix, comprising inexpensive
waste and other byproducts from the agriculture and food industry,
is gathered from within a seven-kilometre radius.196
The market continued to expand in China, where the national
energy plan prioritises the growth of biogas and biomethane.
Construction was under way on two EnviTec Biogas projects:
one in Henan province, where the state-run PowerChina Group
is the prime contractor, and the other operated by Shanxi Energy
& Traffic Investment in Qinxian province.197 Once completed, the
Qinxian plant’s four digesters are expected to convert agricultural
waste such as corn stover into around 0.5 PJ of biogas per year,
which then will be upgraded into biomethane.198
Growing demand from delivery companies for clean fuels is
boosting the biomethane market. The UK supermarket company
ASDA ordered 202 biomethane-fuelled Volvo FH tractors in 2020
and aims to convert all of its trucks from diesel to biomethane by
2024, after in-house trials showed that biomethane reduced CO2
emissions more than 80%.199 Air Liquide (France) also will provide
biomethane at six of its sites.200
BIOENERGY WITH CARBON CAPTURE AND STORAGE OR USE
The capture and storage of carbon dioxide emitted when bioenergy
is used is a key feature of many low-carbon scenarios.201 Removing
from the atmosphere the CO2 that is produced during bioenergy
production, which is considered part of the carbon cycle, offers
a dual benefit resulting in net negative emissions.202 Although
policy makers have shown increasing interest in such options,
strong policy drivers that might make such efforts economically
attractive are lacking. Thus, very few projects demonstrating these
technologies have operated at scale to date.203
Additional pilot-scale carbon capture projects were conducted
during 2020. Drax Power (UK) successfully demonstrated carbon
capture using a novel technology at its large-scale bio-power
plant in the United Kingdom and has begun planning for large-
scale application.204 In the United States, Power Tap is producing
hydrogen for use as a transport fuel by reforming biomethane
and capturing the CO2 that is released.205
99
i The two pathways cross downstream when geothermal resources are used
for electricity generation, because a portion of the electricity is used for “in-
direct” thermal applications, such as cooling (air conditioning) and heating
(via heat pumps or through electric resistance).
ii This does not include the renewable final energy output of ground-source
heat pumps. (p See Systems Integration chapter.)
iii Net additions were somewhat lower due to decommissioning or derating
of existing capacity.
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GEOTHERMAL MARKETS
Geothermal resources are harnessed for energy
applications through two primary pathways (similar
to solar- and bioenergy), either through the generation of
electricity or through various “direct-use” thermal applications
(without conversion to electricity), such as space heating and
industrial heat inputi. Geothermal electricity generation was
around 97 TWh in 2020, while direct useful thermal output was
about 128 TWh (462 PJ)ii.1 In some instances, geothermal plants
produce both electricity and heat for thermal applications
(co-generation), but this option depends on location-specific
thermal demand coinciding with the geothermal resource.
An estimated 0.1 GWiii of new geothermal power generating
capacity came online in 2020, bringing the global total to around
14.1 GW.2 The distinct feature of 2020 was the disproportionately
small growth in capacity relative to recent years (attributable
in part to pandemic-related disruption), with almost all new
facilities located in Turkey. Other countries that added minor
amounts of geothermal power capacity in 2020 were the United
States and Japan.3 (p See Figure 21.)
An estimated 0.1 GW of new geothermal
power generating capacity came online
in 2020 – significantly less than in recent
years – with just one country (Turkey)
representing the bulk of new installations.
Direct use of geothermal energy for
thermal applications continues to grow
around 8% annually, but the market
remains geographically concentrated, with
only four countries (China, Turkey, Iceland
and Japan) representing three-quarters of
all direct geothermal use.
The main focus continued to be on
technological innovation, such as new
resource recovery techniques and
seismic risk mitigation, with the aim of
improving the economics, lowering the
development risk and strengthening
prospects for expanded geothermal
resource development.
K E Y FA C T S
GEOTHERMAL POWER AND HEAT
Note: Figure shows known new capacity and capacity increases at existing facilities but does not indicate known capacity decommissioning or derating of
existing facilities, although those may be reflected (at least partially) in total capacity values.
Source: See endnote 3 for this section.
FIGURE 21.
Geothermal Power Capacity and Additions, Top 10 Countries and Rest of World, 2020
100
i If a geothermal power plant extracts heat and steam from the reservoir at a rate that exceeds the rate of replenishment across all its boreholes, additional wells
may be drilled over time to tap additional steam flow, provided that the geothermal field overall is capable of supporting additional steam flow.
ii In general, a power plant’s net capacity equals gross capacity less the plant’s own power requirements and any seasonal derating. In the case of geothermal
plants, net capacity also would reflect the effective power capability of the plant as determined by the current steam production of the geothermal field. See
endnote 5 for this section.
iii In a binary-cycle plant, the geothermal fluid heats and vaporises a separate working fluid (with a lower boiling point than water) that drives a turbine to generate
electricity. Each fluid cycle is closed, and the geothermal fluid is re-injected into the heat reservoir. The binary cycle allows an effective and efficient extraction of
heat for power generation from relatively low-temperature geothermal fluids. Organic Rankine Cycle (ORC) binary geothermal plants use an organic working fluid,
and the Kalina Cycle uses a non-organic working fluid. In conventional geothermal power plants, geothermal steam is used directly to drive the turbine.
iv Based on net generation of 15.5 TWh in 2019, revised from 16 TWh as reported in early 2020. Likewise, generation for 2018 was first reported as 16.7 TWh but
later revised to 16 TWh. The implied growth of 9.4% may be found to be smaller, if 2020 generation figures are later revised downward, as was the case for the
preceding two years. See endnote 22 for this section.
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The 10 countries with the largest stock of geothermal power
capacity at the end of 2020 were the United States, Indonesia, the
Philippines, Turkey, New Zealand, Mexico, Kenya, Italy, Iceland and
Japan.4 In some instances, effective generating capacity (running
capacity) may be lower than indicated values, due to gradual
degradation of the steam-generating capability of geothermal
fields or to insufficient drilling of make-upi wells to replenish steam
flow over time. For example, the effective netii generation capacity
in the United States was 2.6 GW at the end of 2020, whereas the
gross nameplate generator capacity was 3.7 GW.5
Turkey’s geothermal capacity expansion in 2020 (net of any
deratings) was reported to be 99 MW, which was the country’s
smallest annual increment since 2014 and less than half the
mean annual additions for the preceding five years.6 However,
new capacity installations reported during the year amounted to
around 128 MW, all in the last quarter.7 Five binary-cycleiii power
plant commissions were announced for the month of October,
ranging from 3.5 MW to 26 MW.8
Each of these plants, including the 20 MW Nezihe Beren
facility, qualified for Turkey’s highest national feed-in tariff for
geothermal installations due to local content manufacturing.9
Following an identical addition in 2019, the Pamukören complex
added another 32 MW unit in December.10 Also, the Efeler
complex was expanded at least 25 MW by the end of the year.11
All of Turkey’s new geothermal power plants are located in
Western Anatolia (along with all existing capacity), with most
concentrated in an area extending less than 100 kilometres.12
In 2020, Turkey still ranked fourth globally for total geothermal
power capacity, with 1.6 GW.13 Geothermal power supplies
around 3% of the country’s electricity.14
The technology-specific feed-in tariff (FIT) in place since 2011 has
been instrumental in Turkey’s geothermal energy development.15
Revisions to the FIT were anticipated throughout 2020, possibly
causing some projects to be rushed to completion before
the scheduled expiration of the FIT at year’s end (but this was
extended to mid-2021 on account of the pandemic).16 A new FIT
introduced in early 2021, around one-third lower than the existing
tariff, abandoned the USD-based structure for the local currency,
for both the basic tariff and the local content increment.17
The United States holds an enduring global lead in installed
geothermal power capacity despite being a relatively stagnant
market in recent years. Minor changes in 2020 raised the
country’s net geothermal capacity by around 32 MW, bringing
total net operating capacity to 2.6 GW.18 After more than 30 years
of operation, the Steamboat Hills power plant in Nevada
saw its capacity rise by around 19 MW (to 84 MW) following
refurbishment that included the replacement of all generating
equipment as well as resource modifications.19 The upgrades
are expected to increase the plant’s productivity and efficiency
while reducing maintenance costs per unit of output.20 In
November, the Puna geothermal power plant in Hawaii, which
had been disabled by a volcanic eruption in 2018, resumed partial
operation.21 Geothermal power in the United States generated as
much as 16.9 TWhiv in 2020, a notable increase of 9.4% over 2019,
representing around 0.4% of US net electricity generation.22
In Japan, following the completion of two plants in 2019, some
small additions saw light in 2020. The renovation of the Otake
geothermal plant in Oita Prefecture improved efficiency and
raised its capacity by 2 MW to 14.5 MW.23 The upgrade improved
stability and efficiency of operation by incorporating bi-level
steam pressure to feed a single turbine.24 Elsewhere, two 150 kW
low-temperature binary modules were installed: a bottoming-
cycle unit at an existing high-temperature geothermal plant
to more fully use the available thermal energy, and a unit at a
traditional Japanese spa.25
Indonesia, which ranks second to the United States for installed
geothermal capacity, did not manage to complete any facilities
in 2020 due to pandemic-related delays to three projects that
previously were planned to come online that year.26 The delayed
projects, now expected online in 2021, are the 45 MW Sorik Marapi
Unit 2 in North Sumatra (Unit 1 completed in 2019), the 90 MW
Rantau Dadap and the 5 MW Sokoria Unit 1.27 In all, Indonesia
aimed to complete nearly 200 MW of geothermal power capacity
in 2021.28 A potential danger associated with geothermal energy
exploration and extraction is the uncontrolled or excessive release
of noxious gases. During preparations for commissioning of the
Sorik Marapi Unit 2 in early 2021, procedural failures led to the
release of hydrogen sulphide gas in concentrations that caused
multiple injuries and five deaths among nearby residents.29
101
i Direct use refers here to deep geothermal resources, irrespective of scale, that use geothermal fluid directly (i.e., direct use) or by direct transfer via heat exchangers.
It does not include the use of shallow geothermal resources, specifically ground-source heat pumps. (p See Heat Pumps section in Systems Integration chapter.)
RENEWABLES 2021 GLOBAL STATUS REPORT
Along with Turkey, Indonesia has been a relatively strong and
consistent market with around 700 MW added since 2015 and a
total installed capacity of 2.1 GW.30 Geothermal power supplied
14.1 TWh of electricity to Indonesia in 2019, or 4.8% of the
country’s total generation that year.31
As part of an effort to more than double the renewable share of
Indonesia’s electricity supply to 23% by 2025, the government
committed to absorbing some of the early exploration risk by
taking over exploratory drilling from private developers going
forward.32 The objective is to accelerate progress towards long-
term geothermal energy targets by improving geothermal data
before again auctioning off development areas to developers,
starting in 2023.33 Combined with new reimbursements for
exploration activities, the government expects these changes
to reduce the risk premium on new projects, leading to lower
electricity rates for consumers.34 Exploratory drilling was planned
for three areas in 2021 but later reduced to two due to budget
constraints.35 Indonesia’s geothermal resources are located
mainly in mountainous conservation areas and far from load
centres, further complicating development.36
With no capacity added since 2018, the Philippines still ranks
third for total installed capacity, at 1.9 GW, although dependable
capacity is reported to be somewhat less (1.8 GW).37 To spur
investment in geothermal power, the government moved
in 2020 to allow full foreign ownership in renewable energy
projects.38 Nonetheless, with five prospective geothermal areas
up for auction until early 2021, no foreign firms had placed bids
by the end of 2020.39 The local geothermal industry awaits the
implementation of a risk mitigation fund by the government
to ameliorate the risk of pursuing the mostly low-enthalpy
resources that are up for exploration.40 New discoveries of
high-enthalpy resources in the country are considered unlikely,
and for existing known resources, mountainous terrain adds to
project costs, while permitting is complicated by laws protecting
ecologically sensitive areas and rural populations.41
New Zealand’s geothermal electricity sector has been relatively
inactive over the last five years, following a period of rapid growth
in the use of geothermal energy in the prior decade.42 While the
country has not added any capacity since 2018, geothermal
power has remained at nearly 18% of the generation mix since
2015, in large part because the country has seen no growth in
electricity demand during the last decade.43
Demand growth was expected to be dampened further in 2021
by the proposed closing of an aluminium smelter.44 However, the
successful appraisal of a new geothermal field confirmed the
viability of the proposed 152 MW Tauhara plant, to be built by
2023 near Taupō on the North Island.45 The developer considers
the field to be especially attractive because its associated CO2
emissions are just one-eighteenth those of a coal-fired unit.46
By early 2021, New Zealand’s 32 MW Ngawha plant was
commissioned after three years of construction.47
Worldwide, the capacity for geothermal direct usei – direct
extraction of geothermal energy for thermal applications –
increased by an estimated 2.4 gigawatts-thermal (GWth) (around
8%) in 2020, to an estimated 32 GWth.48 Geothermal energy use
for thermal applications grew an estimated 11.3 TWh during the
year to an estimated 128 TWh (462 PJ).49
Geothermal heat has varied direct applications. Bathing and
swimming remains the largest category, comprising around 44%
of total use in 2019 (latest available consolidated data), and it is
growing around 9% annually on average.50 Second, but with the
fastest growth, was space heating (around 39% of direct use),
expanding around 13% annually on average.51 The remaining
17% of direct use was allocated to greenhouse heating (8.5%),
industrial applications (3.9%), aquaculture (3.2%), agricultural
drying (0.8%), snow melting (0.6%) and other uses (0.5%).52
The top countries for geothermal direct use (in descending order)
in 2020 were China, Turkey, Iceland and Japan, which together
represented roughly 75% of the global total.53 (p See Figure 22.)
Geothermal
direct use
capacity
increased by around 8%
in 2020, to an estimated
32 GWth.
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China is both the largest user of geothermal heat (47% of the
total) and the fastest growing market, with its installed capacity
growing more than 18% annually on average during 2015 through
2019, and consumption growing more than 21% annually on
average.54 That period of growth coincides with the government’s
first geothermal industry plan, issued in 2017, for rapid expansion
of geothermal energy use, especially for heat applications.55
As of 2019, China had an estimated 14.2 TWth of installed
geothermal capacity for direct use (excluding heat pumps), with
7 TWth allocated to district heating, 5.7 TWth serving bathing and
swimming applications, and the rest used for food production
and other industry.56 Most of China’s hydrothermal resources are
relatively low enthalpy; of the 546 production wells drilled during
the period 2015 through 2019, 94% had a wellhead temperature
below 100°C.57
Other top countries (Turkey, Iceland and Japan) have
experienced more moderate capacity growth of around 3-4%
annually (consumption growth of 3-5%).58 In Turkey, geothermal
development is devoted mainly to electricity generation, while
investment in direct use has contracted somewhat over the
last decade.59 Iceland has significant thermal demand served
by district heat networks and continues limited drilling of
reinjection and make-up wells for those systems as well as
for existing power plants.60 In Japan, more than 80% of direct
use is believed to be associated with bathing facilities located
near geothermal springs, but due to limited data gathering,
information is lacking on immediate prospects for further
development.61 The remaining countries that rely on geothermal
heat, each representing less than 3% of direct use, include
(in descending order) New Zealand, Hungary, the Russian
Federation, Italy, the United States and Brazil.62
Some of the most active markets for direct use do not have
access to high-enthalpy resources and often endure higher costs
and greater technical challenges to access geothermal heat.
Several examples are found in continental Europe where low-to-
medium enthalpy resources are used mainly for district heating
and greenhouse cultivation. This market remained active in 2020
with notable new development in France, Germany and the
Netherlands.
In Germany, Munich completed drilling in 2020 for what will be
the country’s largest geothermal plant, exceeding 50 megawatts-
thermal (MWth) and expected to provide heat for more than 80,000
city residents.63 By use of absorption chillers, the plant also will
contribute to the city centre’s district cooling network, which was
undergoing expansion during the year.64 In addition, plans were
under way for what would be the seventh geothermal facility
serving the municipality since the first plant came online in 2004.65
France continues to see growing use of localised geothermal
resources, mostly for district heating. In the greater Paris region,
several geothermal district heating systems have been developed
in recent years, with new projects started or announced in 2020.
In August, drilling commenced in Vélizy-Villacoublay, southwest of
central Paris, on a system that is expected to meet 66% of the energy
demand of the local district heat network, serving the equivalent
Source: See endnote 53 for this section.
FIGURE 22 .
Geothermal Direct Use, Estimates for Top 10 Countries and Rest of World, 2020
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i EGS encompasses the use of hydraulic fracturing of hot rock to create the conditions for a geothermal reservoir. Specifically, the objective is to attain a combination
of heat, permeability and flow of geothermal fluid that is sufficient to make extraction economical for heat and/or electricity generation.
ii Frontier Observatory for Research in Geothermal Energy.
RENEWABLES 2021 GLOBAL STATUS REPORT
of 12,000 dwellings; the
project was aiming for
completion in 2021.66
In the eastern suburbs of
Paris, the communities of
Champs-sur-Marne and
Noisiel advanced work
on the construction of
a joint heating network
following a drilling phase.
Expected for completion
in late 2021, the geothermal district heating project will supply heat
to the equivalent of 10,000 homes across the two municipalities;
the renewable energy component of the supply is expected to be
82%.67 For another project in the nearby communities of Drancy
and Bobigny, four wells were drilled in 2020 and distribution of
geothermal heat began in early 2021.68 The project is expected
to supply the equivalent of 20,000 homes when completed,
displacing 60% of the fossil fuels currently used on the network.69
A once-promising geothermal project in the Alsace region of
France came to an apparent end in late 2020, and its fate could
have repercussions for geothermal development in the area going
forward.70 After a series of earthquakes over the course of a year,
attributed to geothermal drilling and associated well stimulation
on the northern outskirts of Strasbourg, local authorities ordered
the final shutdown of the Vendenheim facility in December, along
with three other permitted projects in the area.71 Local authorities
claimed that the operator had exceeded permitted well pressures
for stimulation as well as the authorised well-drilling depth,
reaching beyond the sandstone strata into the deeper bedrock,
which increased the risk of seismic activity.72
Problems associated with induced seismic activity also affected
projects in the Netherlands. A Dutch geothermal greenhouse
operation was declared bankrupt in 2020 after two years of
inactivity following seismic disturbances in 2018.73 Although the
operator claimed that the earthquakes near the project were
unrelated, Dutch regulators declared continued operations too
risky.74 The operator observed that unlike other Dutch geothermal
projects that tap only the porous sandstone layer, the drilling in
this case penetrated deep bedrock in the search for greater
hydrothermal flow.75
In the Netherlands, geothermal energy output grew 10% in
2020 (following 51% growth in 2019), to 6.2 PJ, driven mostly
by drilling activity in the preceding year.76 The country’s use of
geothermal energy is generally limited to greenhouse horticulture,
but expansion into district heating and industrial applications is
anticipated, pending the construction of heat networks but also
the need to overcome political, financial and social barriers to uses
beyond horticulture.77 Multiple drilling operations were under way
or completed in 2020.78
As Dutch mining laws and regulations pertaining to geothermal
exploration and development were being reviewed in 2020, the
country’s geothermal industry raised concerns about regulatory
uncertainty and any associated project delays.79
GEOTHERMAL INDUSTRY
In a year of project delays as well as both meagre and highly
concentrated market growth, the geothermal industry found
promise in the pursuit of new technology. Technological
innovation, such as new resource recovery techniques and
seismic risk mitigation, continued to be the industry’s main focus
towards achieving improved economics, lower development risk
and overall better prospects for expanded geothermal resource
development around the world. However, industry hopes to
expand development beyond the relatively few and concentrated
centres of existing activity remained largely unfulfilled, as in years
past. While high costs and project risks continue to create a
drag on investment in most places, especially in the absence of
government support (i.e., feed-in tariffs and risk mitigation funds),
certain pockets of industry innovation attracted new investment
from established entities in the energy industry.
In some markets, the real or perceived risk of induced seismic
activity related to geothermal development appears to
present a specific risk to individual geothermal developers,
if not a systemic risk to the industry (as evidenced by recent
events in France and the Netherlands). Beyond the projects
directly affected, collateral damage has emerged in the form
of cancellations of other nearby projects (i.e., Alsace) and of
shaken public confidence.80 The prevalence of such events has
grown with the increased application of hydraulic fracturing
(well stimulation), as was used in the Vendenheim project in
Strasbourg. Before that, earthquakes associated with such
enhanced geothermal systems (EGS)i in Switzerland (Basel in
2006 and St. Gallen in 2013) caused severe setbacks for Swiss
geothermal prospects.81 Yet a solution is needed if geothermal
energy use is to expand significantly beyond the relatively few
locations in the world that enjoy the most valuable, medium-to-
high enthalpy geothermal resources.82
Driven by the early setbacks and the need to rekindle local
geothermal development, Swiss researchers continue to pursue
technological and procedural solutions to the problem of
induced seismic activity. In late 2020, Geo-Energie Suisse AG
(GES) proved the concept of forming a sufficiently permeable
“heat exchanger” reservoir at a depth of 4-5 kilometres through
a process of multi-stage (incremental steps) stimulation that
minimises the probability of induced seismic events.83 Further
validation of the technology will be conducted at the US test site
FORGEii in Utah. GES anticipates that these findings will improve
government confidence in a currently suspended geothermal
pilot project for the technology in the canton of Jura.84
Across Germany, the Netherlands and Italy, industry actors
and research institutions worked to draw attention to the
potential of geothermal energy to aid in the renewable energy
transition (particularly to meet thermal energy demand) and to
highlight the need for additional support policies. In Germany,
geothermal industry and research institutions came together
under the banner of “Heat transition through geothermal energy”
(Wärmewende durch Geothermie).85 The Dutch geothermal
Technology
innovations
promise expanding project
viability and are attracting
investment from the oil
and gas majors.
104
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industry also indicated that the sector will be critical to the
pending heat transition in the Netherlands, while drawing
attention to the alleged lack of financial incentives and to the
perceived un-level playing field, relative to other technologies.86
The Italian Geothermal Union similarly claimed that ineffective
incentives and national legislation had severely slowed Italy’s
geothermal development and jeopardised industrial know-how.87
The persistent but variable emissions of CO2 and hydrogen
sulphide from open-loop geothermal facilities remain a concern.
In most instances, CO2 emissions are far below those from
fossil fuel facilities, but they are non-negligible nonetheless,
and sometimes geothermal plant emissions can rival those of
coal-fired power plants.88 Significant progress has been made
in recent years to advance the process of sequestering CO2.
The Icelandic company Carbfix, with its international partners,
has developed a process to permanently capture and store
CO2 by imitating and accelerating the natural process through
which dissolved CO2 reacts with sub-surface rock formations to
form stable carbonate minerals.89 In 2020, an agreement was
reached to build a CO2 sequestration plant in Iceland capable of
removing 4,000 tonnes of atmospheric CO2 per year, combining
the Carbfix method with the direct air capture technology for
CO2 removal provided by Climeworks of Switzerland.90
When resource exploration disappoints and precludes conventional
hydrothermal projects, new technologies may help. For example, in
Gertetsried, Germany, a developer drilled two wells, starting in 2013
(the first being the deepest geothermal well in Europe to date, at over
6,000 metres), that proved unable to produce enough hydrothermal
flow to make a conventional geothermal power project viable.91
Eavor Technologies (Canada) joined the project in 2020 to deploy
its new modular closed-loop technology, which is well suited for the
local geothermal conditions and thus to improve viability of the site.92
Eavor’s technology, first demonstrated in Alberta (Canada) in early
2020, uses directional drilling techniques developed in the oil and
gas industry to create a closed-loop system that circulates a working
fluid to extract heat from bedrock without bringing geothermal fluid
(brine) to the surface. In addition to eliminating surface emissions
of CO2 and hydrogen sulphide, the thermosiphon effect (bringing
hot fluid up on one side as cold fluid descends on the other) of the
closed-loop design reportedly mitigates the energy demand from
pumping that is associated with other geothermal techniques.93
Such innovations have gained the attention of the oil and
gas majors. In early 2021, Eavor Technologies completed a
USD 40 million funding round including investments from BP
Ventures and Chevron Technology Ventures, among others.94
Chevron also announced investment in Baseload Capital A.B.
(Sweden), whose projects include the deployment of modular
“heat power” units by Climeon (Sweden) for low-temperature
electricity generation from geothermal or other sources of excess
heat (including both of the units installed in Japan in 2020).95
The industrial entities that provide the technology for geothermal
energy capture and conversion (excluding drilling) comprise a
relatively small group. The power unit (turbine) manufacturers
include Atlas Copco (Sweden), Exergy (Italy, subsidiary of Tica
Group of China since 2019), Fuji Electric (Japan), Mitsubishi and
its subsidiary Turboden (Japan/Italy), Ormat (US) and Toshiba
(Japan).96 In some key markets, such as Turkey, the suppliers of
binary-cycle technology are prominent (for example, Atlas Copco,
Exergy and Ormat), while other suppliers specialise in more
conventional flash turbines (for example, Toshiba and Fuji).97
Ormat Technologies and Exergy supplied most of the binary-
cycle plants that were completed during the year.98
105
i China’s share represented 65% of global total capacity additions; if China is
excluded, worldwide installed capacity decreased 44% between 2019 and 2020.
ii Where possible, all capacity numbers exclude pure pumped storage
capacity unless otherwise specified. Pure pumped storage plants are not
energy sources but rather means of energy storage. As such, they involve
conversion losses and are powered by renewable and/or non-renewable
electricity. Pumped storage plays an important role in balancing grid power
and in the integration of variable renewable energy resources.
Russian Federation 4 %
India 4 %
Norway 3 %
Turkey 3 %
Japan 2 %
France 2 %
Next
6 countries
China Brazil
29%
Rest of World
31%
9%
Canada
7%
United States
7%
17%
RENEWABLES 2021 GLOBAL STATUS REPORT
HYDROPOWER MARKETS
Despite a 24% increase in capacity additions, driven
mainly by Chinai, the global hydropower market did
not recover in 2020 following several years of deceleration.1
The effects of the COVID-19 pandemic were notable, with
the market slowing as construction was halted temporarily,
component supply chains were disrupted, and energy demand
fell.2 Capacity additions for the year totalled an estimated
19.4 GW, bringing the total installed capacity to 1,170 GWii.3 The
top 10 countries for total capacity did not change and were, in
order of installed capacity: China, Brazil, Canada, the United
States, the Russian Federation, India, Norway, Turkey, Japan
and France, together representing more than two-thirds of the
global total.4 (p See Figure 23 and Reference Table 2 in GSR
2021 Data Pack.)
China regained the lead from Brazil in commissioning new
hydropower capacity (both large and small installations),
followed by Turkey, India, Angola and the Russian Federation.5
(p See Figure 24.) As large and economically viable hydrological
The global hydropower market
expanded in 2020 but did not recover
from several years of deceleration.
China added 12.6 GW of hydropower
capacity in 2020, its largest addition of
the previous five years, and regained the
lead from Brazil in commissioning new
hydropower capacity.
Hydropower faced challenges including
operational and technical factors,
environmental and social acceptability,
a global decline in wholesale electricity
prices, and adverse climate impacts on
hydropower production and infrastructure.
K E Y FA C T S
HYDROPOWER
Source: See endnote 4 for this section.
FIGURE 23.
Hydropower Global Capacity, Shares of Top 10 Countries and Rest of World, 2020
106
i Fluctuations in weather patterns lead to modifications in hydrological conditions. Hydropower operations may vary due to price fluctuations in electricity mar-
kets, the contribution to grid stability through balancing services using storage capacities (reservoirs) and water supply management.
Gigawatts
IndiaTurkey Angola Russian
Federation
Norway Indonesia Guinea
+12.6+12.6
0
100
50
150
10
20
30
40
200
250
300
350
China Canada Brazil
50
Added in 2020
2019 total
+0.5+0.5
+2.5+2.5 +0.3+0.3
+0.4+0.4
+0.4+0.4
+0.2+0.2
+0.2+0.2
+0.3+0.3
+0.2+0.2
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FIGURE 24.
Hydropower Capacity and Additions, Top 10 Countries for Capacity Added, 2020
resources become more limited, markets increasingly have
developed the remaining untapped potential that is available
mainly from marginal resources and pumped storage.6
Global pumped storage capacity (which is counted separately
from hydropower capacity) increased 1.5 GW (0.9%) in 2020,
primarily from new installations in China and Israel.7
Global hydropower generation increased 1.5% in 2020 to reach
an estimated 4,370 TWh, representing around 16.8% of the
world’s total electricity generation.8 While some yearly variations
in global hydropower generation are due to changes in installed
capacity, most are the result of fluctuations in weather patterns
and in local operating conditionsi.
China added 12.6 GW of hydropower capacity in 2020, its
highest amount in the previous five years, reaching 338.7 GW
by year’s end.9 The country’s capacity increased 15% during
the 2015-2020 period, and new hydropower plants represented
7% of China’s total newly installed power generation capacity
in 2020.10 The largest additions included the 1.6 GW Datengxia
plant in the Guangxi Zhuang autonomous region, with eight
200 MW turbines, and the five 850 MW units commissioned at
the Wudongde plant between Yunnan and Sichuan provinces.11
Wudongde will be the seventh largest plant in the world upon
completion, with 10.2 GW of total installed capacity.12
Other hydropower projects in China included the completed
reconstruction of the 1.5 GW Fengman plant and the ongoing
construction of the 16 GW Baihetan mega project, with commissioning
scheduled for 2021.13
China’s total hydropower
output reached 1,360 TWh,
up 4.1% from 2019 and
representing 18% of the
country’s electricity supply;
meanwhile, the Three
Gorges Dam set a new
world record for annual
electricity output in 2020.14
Source: See endnote 5 for this section.
China added 12.6 GW of
hydropower
capacity
in 2020, its highest amount
in the previous five years.
107
i The public sector companies subject to renewable power purchase obligations are power distribution companies, energy producers and certain consumers.
ii The 1,300 MW Engurhesi hydropower plant was completed in 1978, and the 130 MW Zhinvalhesi plant was completed in 1986.
RENEWABLES 2021 GLOBAL STATUS REPORT
Turkey added 2.5 GW of new hydropower capacity – its largest
increase since 2013 – for a total of 30.9 GW.15 The fast pace of
commissioning was driven in part by the pending expiration of
the country’s feed-in tariff scheme, applying to facilities brought
online before the end of the year.16 By early 2021, a new FIT was
announced for 2021-2025 that reduced the hydropower tariff by
around one-third.17 The largest hydropower facilities that went
online in 2020 were the 540 MW Yusufeli dam, the 500 MW
Lower Kaleköy plant, the 420 MW Çetin plant and the 1.2 GW
Ilisu dam (the second largest dam in the country, located on the
Tigris River, which began production after some delays).18
The intense drought in the Black Sea region in 2020 reduced
Turkey’s hydropower production 12% compared to 2019.19
Hydropower represented nearly one-third of the country’s power
capacity mix by the end of 2020 and around 56% of the new
power generating capacity added that year.20
India added 473 MW of net hydropower, for a total capacity
of 45.8 GW.21 The government has promoted hydropower as
a source of grid stability and flexibility, with a target of 70 GW
of installed capacity by 2030.22 Around 13 GW of capacity was
under construction in 2020.23 After eight years of delays following
protests related to safety concerns and other potential negative
impacts, construction resumed on the 2 GW Subansiri project
along the Assam-Arunachal Pradesh border.24 In mid-2020, the
government proposed a draft Electricity (Amendment) Bill to
boost India’s renewables sector.25 The bill includes provisions
that define a minimum percentage of electricity that public sector
companiesi must purchase from hydropower sources, in addition
to introducing a purchase obligation and providing incentives.26
Indonesia added 240 MW in 2020 for a total installed capacity
of 6.1 GW, and Lao People’s Democratic Republic (PDR) added
180 MW to reach nearly 7.4 GW.27 The 260 MW Don Sahong
project, commissioned in 2019, began commercial operations,
and commissioning was completed on the first unit of the 70 MW
Xelalong 1 plant.28 In Vietnam, 119.5 MW of hydropower was
added in 2020, bringing the total installed capacity to 17.1 GW.29
The commissioning of the 220 MW Thuong Kon Tum hydropower
plant and the expansion of the 1,920 MW Hoa Binh plant, both
expected by the end of the year, were postponed to 2021.30
In Uzbekistan, several facilities were finalised with modernisation
of the 15 MW Kadyrinskaya 3 plant, two power plants totalling
22.4 MW on the South Ferghana Canal and a 15 MW plant on
the Bozsu Canal.31 In Georgia, the Shuakhevi installation on the
Adjaristsqali River, the country’s largest hydropower plant built
since 1978ii, began commercial operations, adding 178 MW to
the grid; the facility is one of two plants in a 187 MW scheme.32
Georgia ended 2020 with a total installed capacity of 3.4 GW,
representing around 80% of the country’s power generating
capacity and 76% of its electricity production.33
The European hydropower market has reached near-maturity,
and possibilities for new, large installations are limited. Norway
added 324 MW of capacity – with nearly half of this consisting of
plants of less than 10 MW – in addition to several larger facilities,
including a 77 MW plant.34 The country’s total installed capacity
reached 32 GW in 2020, representing 89% of national electricity
production.35 In France, the 97 MW Romanche-Gavet plant was
commissioned after a decade of construction, replacing six power
plants and five dams built around 1910.36 To reduce the facility’s
visual impact, the developers located the plant underground and
replaced the previous structures with a single dam; in addition,
local species were replanted along the dam banks for ecological
restoration.37 In Albania, which relies entirely on hydropower
generation and electricity imports, the 197 MW Moglicë plant
– the second of two plants that are part of the 269 MW Devoll
Hydropower Scheme – started delivering electricity.38
The Indian government
has promoted hydropower
as a source of
grid stability
and flexibility.
108
i The dam will store water to generate electricity from hydropower, irrigate agricultural fields downstream and provide a flood protection system for populations
living in the White Volta basin.
ii The Indigenous peoples who own part of the project include the Tataskweyak Cree Nation, War Lake First Nation, York Factory First Nation and Fox Lake Cree Nation.
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Installed capacity in the Russian Federation reached 48.5 GW
after 380 MW was added in 2020.39 The largest project to
come online was the 346 MW Zaramagskaya plant in North
Caucasus.40 New small hydropower plants in the region also
added more than 22 MW of capacity across four facilities.41 The
sixth of seven units was commissioned at the Ust-Khantayskaya
facility under renovation in the Krasnoyarsk region, where 63 MW
units are being replaced with 73 MW units to increase the installed
capacity to 511 MW.42
Several projects were completed in Africa, including in Angola,
Ghana and Guinea. Angola continues to focus its long-term
electrification strategy on hydropower, with more than 4 GW
planned or under study.43 To achieve this, generation facilities are
being developed, upgraded or restored.44 Angola added 401 MW
of hydropower capacity in 2020, bringing the sixth (and final)
unit of the Laúca plant into commercial operation to reach an
installed plant capacity of 2.1 GW.45 By year’s end, Angola’s total
installed capacity was 3.8 GW.46
In Malawi, the Phalombe 3 MW plant reached its final phase
before commissioning, and the last two units at the 8.2 MW
Ruo-Ndiza hydroelectric power station were commissioned.47 In
Rwanda, four installations came online in 2020: three of these
totalled slightly more than 2 MW, while the 9.8 MW Giciye III came
online after 18 months of construction.48 Rwanda’s total installed
capacity reached 121 MW by year’s end.49 In Uganda, the Bukinda
6.6 MW facility was commissioned, and the 600 MW Karuma
project along the Nile River in the western region was nearing
completion after years of delays as well as recent pandemic-
related challenges.50 Once commissioned, the Karuma plant
will increase Uganda’s total hydropower capacity to more than
1.5 GW and will provide power to neighbouring Rwanda, northern
Tanzania, Kenya and the Democratic Republic of the Congo
through new regional transmission lines.51
In Ethiopia, the more than 6 GW Grand Ethiopian Renaissance
Dam moved towards completion, despite a lack of agreement
with Egypt and Sudan on filling and operating the dam.52 The
Ethiopian government considers this facility fundamental to the
country’s economic development, as half of the population lacks
access to the grid, and electricity supply blackouts are frequent.53
In line with this economic objective, the launch of commercial
operations at the 254 MW Genale Dawa 3 hydropower project
increased Ethiopia’s overall power capacity around 6%.54 The
country’s year-end hydropower installed capacity was 4.1 GW.55
In Guinea, 225 MW came online after the commissioning of
two units of the Souapiti dam, bringing the country's total
installed capacity to 0.7 GW.56 Ghana finalised the retrofit of the
160 MW Kpong facility, one of three large hydropower facilities
in the country, for a total installed capacity of 1.6 GW.57 Ghana’s
first small-scale plant, the Tsatsadu micro-hydro project,
funded primarily by the Bui Power Authority and by contributions
from development funds, also was fully commissioned.58 The
Ghanaian Parliament authorised construction of the 60 MW
Pwalugu multi-purpose dam projecti on the Volta River.59
Brazil, Canada and the United States, the largest hydropower
markets in the Americas, together added nearly 0.5 GW of capacity
in 2020.60 In Canada, the two large projects expected during the year
were delayed largely because of the pandemic. The commissioning
of the 695 MW Keeyask generation project near Hudson’s Bay
(owned by Manitoba Hydro and four Indigenous groupsii) was
pushed to 2021 after Indigenous groups erected blockades,
preventing workers from entering when activities resumed.61 In the
province of Newfoundland and Labrador, the first 206 MW unit
at the 824 MW Muskrat Falls facility on the Churchill River came
online in late 2020, and commissioning began on the second unit.62
By year’s end, Canada had around 82 GW of hydropower capacity,
providing around 60% of the country’s electricity supply.63
The United States commissioned 148 MW of capacity in 2020,
primarily following the replacement of turbines and generators
at the 122 MW Wanapum Dam, as well as a 3 MW expansion at
Shoshone Falls.64 Two new installations totalling less than 30 MW
were added, and a 6 MW facility was retired.65 This resulted in a
slight increase in the US total installed capacity, to 79.9 GW.66 After
a three-year decline, generation rose to 291 TWh, representing
7.2% of the country’s total electricity supply.67
In Latin America, the 104 MW Patuca III plant, the second largest
hydropower plant in Honduras and the country’s first project
financed by China, went into operation, increasing Honduras’
total installed capacity to around 0.8 GW.68 In Colombia, installed
capacity increased slightly from the previous year, with 24 MW
of additions and a total capacity of 11.9 GW by year's end.69
Preparations also began at the 2.4 GW Hidroituango project to
install the first two turbines after a 2018 accident that flooded and
damaged the powerhouse, displacing around 600 residents and
destroying infrastructure along the Cauca River.70
109
i As of 2018, 31% of Brazilian hydropower plants were more than 40 years old.
ii Gouvães will be the first of three plants in the 1.2 GW Tâmega complex, with an estimated project investment of more than EUR 1.5 billion (USD 1.8 billion).
iii The Huizhou and Guangdong pumped storage plants hold the current record for the largest number of turbines, with eight each.
iv With the large decrease in electricity demand, wholesale prices for hydropower fell, jeopardising revenues and capital flows; greenfield development and
critical modernisation projects were halted; and current and new government programmes designed to support the sector were postponed or cancelled. See
endnote 91 for this section.
v Technologies related to the energy transition (renewables, electric vehicles and battery storage) and digitalisation are among the sectors that have generated
the most interest from investors in the post-COVID-19 market.
RENEWABLES 2021 GLOBAL STATUS REPORT
Brazil, after nearly a decade of adding capacity in the gigawatt
range, commissioned only 213 MW in 2020, mainly divided
among small-scale facilities of 11 MW or less.71 This sharp
contraction from the previous year was due to rising
environmental concerns associated with the country’s remaining
exploitable hydropower potential.72 By the end of 2020, Brazil
had 109 GW of hydropower capacity, representing 62% of
its total operational power capacity.73
Brazil’s ageing hydropower fleeti has negatively affected the
reliability of the country’s electricity supply, causing frequent
service disruptions.74 In 2017, outages at hydropower plants
reduced total electricity production by 65 TWh, which is the
equivalent of 67% of the overall energy losses in Brazil’s electrical
transmission and distribution system.75 One study estimated
that rehabilitating the seven hydropower plants that were least
available that year due to forced outages would provide an
additional 1.9% of overall hydropower energy.76
Peru commissioned the 20 MW Manta hydropower plant with an
investment of USD 43.6 million.77 Commercial operation of the
84 MW La Virgen plant on the Tarma River was delayed after
fieldwork was halted for three months in the second quarter of
the year.78 Chile commissioned 206 MW in 2020.79
Globally, the pumped storage installed capacity increased
1.5 GW in 2020, bringing the total capacity to 160 GW.80 Israel’s
first pumped storage facility (300 MW) started operation during
the year, and in China 1,200 MW of pumped storage was
commissioned.81 Additional large pumped storage projects in
the pipeline include Greece’s 680 MW Amfilochia complex,
Scotland’s 1.5 GW Cloire Glass facility and Turkey’s first pumped
storage facility, the 1 GW Eğirdir.82 In India, two identical hybrid
projects secured financing: the Pinnapuram and Saundatti
facilities each have pumped storage capacity of 1.2 GW combined
with 4 GW total of solar and wind power capacity.83
With most of Australia’s hydropower potential already developed,
pumped storage is an increasingly important component of the
country’s energy expansion, especially its plans to integrate
variable renewable energy (VRE) sources.84 The Snowy 2.0
project, which aims to expand the existing Snowy scheme
by 2 GW, received government approval to build related
infrastructure, and the Ravine substation was commissioned
to power this construction.85 In Tasmania, Lake Cethana was
identified as the first pumped storage project of the Battery
of the Nation initiative, with capacity nearing 600 MW.86
The 500 MW Dungowan and 400 MW Big-T projects under
development aim to support VRE integration, providing firm
power and grid services.87
In Portugal, the 880 MW Gouvãesii pumped storage facility was
on track for commissioning in 2021, and construction also began
on one of Vietnam’s first pumped storage projects, the 1.2 GW
Bac Ai project.88 The 250 MW Hatta pumped storage facility
in the United Arab Emirates also progressed, with the service
tunnels completed and construction of the upper dam under
way.89 In China, the 3.6 GW Fengning project began storing water
in its lower reservoir; upon completion, the facility is expected to
be the world’s largest pumped storage installed capacity, with a
record 12 reversible 300 MW turbinesiii.90
HYDROPOWER INDUSTRY
The hydropower industry continued to face challenges and
opportunities in 2020, augmented by the pandemic-induced
recessioniv as well as by new opportunities stemming from the
growing recognition of renewables as a valuable component of
a sustainable economic recoveryv.91 The challenges included
operational and technical factors, environmental and social
acceptability, a global decline in wholesale electricity prices,
and adverse climate impacts on hydropower production and
infrastructure.92 Among the opportunities for industry expansion
were technology improvements and increased performance, the
remaining untapped potential of smaller resources, synergies
with VRE and increased needs for grid flexibility.
110
i Major technology providers included Andritz Hydro (Austria), Bharat Heavy Electricals (India), Dongfang Electric (China), GE (US), Harbin Electric (China),
Hitachi Mitsubishi Hydro (Japan), Impsa (Argentina), Power Machines (Russian Federation), Toshiba (Japan) and Voith (Germany).
ii The Stability Pathfinder approach aims to provide inertia and other vital services without generating unnecessary electricity by using technologies such
as pumped storage, gas-fired power stations and synchronous condensers. Five six-year contracts were awarded in the first stage in early 2020.
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The disruptive effect of the pandemic-induced recession had
an impact on most of the world’s major hydropower technology
providersi. Voith Hydro suffered from a slowing market and
reported a 46% decline in orders and a 17% decline in sales.93
The Americas represented the largest share of Voith’s sales,
followed by Asia and Europe.94 GE Hydro Solutions, representing
more than 25% of total installed capacity worldwide, reported
lower-than-expected revenues.95 Andritz Hydro registered a
12% decline in revenues but nearly the same level of order
intake as in 2019.96
Although renewable energy was underrepresented in
government recovery packages in 2020, some plans aimed to
boost economic growth, create jobs and cut greenhouse gas
emissions. The International Energy Agency included hydropower
modernisation in its three-year recovery proposal, which calls
for spending around USD 20 billion annually over this period to
support continued generation and to boost the creation of skilled
jobs.97 Similarly, the International Hydropower Association (IHA)
and the International Renewable Energy Agency joined forces
to foster development of the 850 GW of hydropower capacity
expected to be needed by 2050 to achieve the climate goals of the
Paris Agreement.98
The modernisation and refurbishment of hydropower plants
continued in 2020 and was expected to remain a priority.
Worldwide, tens of thousands of ageing water storage facilities
have reached their end-of-life, and the 52% of global hydropower
capacity that was installed before 1990 could be due for major
rehabilitation.99 Across Europe, North America, Central Asia and
Latin America, the refurbishment of ageing facilities has resulted
in improved operational efficiency and enhanced resource use.100
Refurbishment and improvement of the 3.1 GW Yacyretá plant
on the Argentina/Paraguay border increased its capacity by
735 MW, and at the 14 GW Itaipu plant on the Brazil/Paraguay
border a USD 660 million digitalisation project was announced
to replace the original analog technology.101 In Australia, Voith
announced a collaboration with Snowy Hydro to use acoustic
sensing equipment, combined with cloud-based data collection
and analysis and remote surveillance, to monitor hydropower
assets in order to detect malfunctions before they occur and to
optimise preventive maintenance.102
With the rising penetration of variable renewables in electricity
production, grid operators increasingly are looking for resources
to boost the flexibility of generation. Hydropower and pumped
storage can provide the flexibility and support services that
the grid requires through quick ramping and other grid service
capabilities, with a lower emission profile than fossil fuel
generation assets.103 Hydropower generators contribute greatly
to grid reliability, but their primary revenue stream (market energy
prices) does not always compensate for the other ancillary
services that they can provide (such as inertial response and
voltage regulation). These ancillary services could come at the
expense of displacing the maximum operating capacity of the
plant to support them.104
In the United States, the California Independent System
Operator (CAISO) signed contracts in 2019 to explicitly
compensate for the inertial and primary frequency response
services supplied by hydropower.105 Under current US market
conditions, the cost-benefit ratio of delivering ancillary
services versus power generation is under study, and market
mechanisms are emerging to monetise other grid services
that hydropower provides.106 In 2019, the UK electricity system
operator held its first tender for “grid stability” and in early 2020
it awarded a contract to the 440 MW Cruachan pumped storage
station to supply synchronous compensation.107 The Cruachan
facility began providing inertia in mid-2020, using a world-first
approachii estimated to save consumers up to GBP 128 million
(USD 174 million) over the six-year period.108
More than half of
global
hydropower
capacity
could be due for major
rehabilitation.
111
i Operators can benefit from more stable yearly generation, as solar will produce more than hydropower in the dry season, and the reverse will occur during
the rainy season.
ii The novel closed-loop installation design required the use of a submersible pump turbine in a vertical “well” to replace the traditional underground power-
house, which is one of the most expensive and riskiest components of this type of facility.
RENEWABLES 2021 GLOBAL STATUS REPORT
In West Africa, a study found that with adequate management
and operation of current and future facilities, hydropower
flexibility can support VRE integration while displacing fossil
fuel plants.109 The industry is embracing these trends as projects
combining large amounts of solar and wind with hydropower
or pumped storage are emerging and costs are becoming
competitive.110 The 500 MW Dungowan pumped storage plant in
New South Wales, Australia was designed as part of the 4 GW
Walcha Energy Project to provide grid support services and firm
power.111 Relatively low wind power prices in locations such as
Québec, Canada, where hydropower is abundant, can shift the
dispatching approach by encouraging the use of wind when it is
available and storing water until it is needed.112
Projects combining hydropower reservoirs and floating solar PV
increased in 2020.113 The major benefits of these hybrid systems
include reduced evaporation, lower energy infrastructure costs
and generation complementarity due to seasonalityi.114 In some
cases, this approach is proposed to compensate for the declining
performance of some hydropower plants.115 Other synergies
being explored include using hydropower to power hydrogen
electrolysers. Construction of one of the largest electrolysers
using hydropower, with capacity nearing 90 MW, was announced
in Canada, while small-scale hydrogen production facilities were
being pursued in Iceland.116
Innovations in 2020 included the deployment of the world’s
largest hydropower turbine, a 1 GW turbine at the Baihetan
facility built by China Three Gorges Corporation.117 Advances at
small facilities included the use of fish-friendly installations that
limit the diversion of river flow by using submerged generators
or low-head turbines with blades designed to allow safe fish
passage.118 The US market demonstrated increased commercial
viability for pumped storage through an innovative configuration
for closed-loop pumped installationsii that reduces project
costs, environmental impacts and development time.119
The industry also is addressing the sustainability of hydropower,
using an integrated resource management approach to focus on
load balancing, water quality and water supply for non-energy
needs (such as irrigation, flood control, sediment management
and responding to other requirements from communities and
natural resources).120 Lao PDR and other countries along the
Mekong River have experienced frequent extreme low water
flows due to reduced rainfall and flow modifications upstream
caused by hydropower operations. To promote and co-ordinate
sustainable management of the basin, the Mekong River
Commission released the Hydropower Mitigation Guidelines to
provide risk management and mitigation guidance during the
early stages of hydropower facility design.121 Poor management
has resulted in tensions among countries along the Mekong,
Nile, Tigris and other rivers.122 To address the inherent risks
facing the industry, particularly in heavily hydropower-dependent
regions, hydropower must be transformed into a resilient energy
source in the face of climate change.123
In 2020, in response to environmental concerns, areas of the
Balkans including the Federation of Bosnia and Herzegovina,
Montenegro and the Serbian region of Sokobanja faced a
surge of restrictions on small hydropower developments.124 The
region’s hydropower industry launched an initiative in early 2021
to implement international good practices in development, in
line with the IHA Hydropower Sustainability Tools.125 Another
sustainability initiative led by the IHA, the Hydropower
Sustainability Assessment Fund, aims to help hydropower
developers and operators assess the environmental, social and
governance performance of projects that are under preparation
and development or already in operation.126
112
i Ocean power technologies harness the energy potential of ocean waves, tides, currents, and temperature and salinity gradients. In this report,
ocean power does not include offshore wind, marine biomass, floating solar PV or floating wind.
ii These are the same in-stream technologies used in some types of hydropower plants.
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OCEAN POWER MARKETS
The oceans contain the largest untapped source of
renewable energy. While ocean power technologiesi
represent the smallest share of the renewable energy market, they
are steadily advancing towards commercialisation. Deployments
in 2020 added around 2 MW, bringing the total operating
installed capacity to an estimated 527 MW at year’s end.1 Two
tidal barrages using mature turbine technologiesii represent
more than 90% of total installed capacity: the 240 MW La Rance
station in France (installed in 1966) and the 254 MW Sihwa plant
in the Republic of Korea (2011).2
Tidal stream and wave power are the main focus of development
efforts. Advancements in these technologies have been
concentrated largely in Europe, especially the United Kingdom,
which has significant resources. However, generous revenue
support and ambitious research and development programmes
in Canada, the United States and China are spurring increased
development and deployment elsewhere.3 In 2020, the EU set
an ambitious target for 40 GW of ocean power capacity by
2050, including at least 100 MW of pilot projects by 2025 and
1 GW by 2030.4
Tidal stream devices are approaching maturity, and pre-
commercial projects are under way. Device design for utility-scale
generation has converged on horizontal-axis turbines mounted
on the sea floor or attached to a floating platform.5 These devices
have demonstrated considerable reliability in performance, with
total generation surpassing 60 GWh by the end of 2020 (up
from 45 GWh the year before).6 A range of other concepts are
under development, designed to meet specific applications or
environmental conditions, such as providing power to remote
communities or at low-energy sites.
Wave power devices remain in the prototyping phase, and
there is no convergence on design yet owing to the complexity
of extracting wave energy from a variety of wave conditions and
the wide range of possible operating principles.7 Developers
generally have chosen one of two distinct pathways for wave
energy development: devices above 100 kW target utility-scale
electricity markets, whereas smaller devices, usually below
50 kW, are intended primarily for specialist applications (oil and
gas, aquaculture, maritime monitoring and defence).8
Ocean power generation continued to
rise in 2020, surpassing 60 GWh.
The industry is now moving from small-
scale demonstration and pilot projects
towards semi-permanent installations
and arrays of devices.
Maintaining revenue support for
ocean power technologies is considered
paramount if the industry is to achieve
greater maturity.
K E Y FA C T S
OCEAN POWER
113
i Minesto’s Deep Green device comprises a turbine integrated with a wing, which is tethered to the seabed and operates in a manner similar to an airborne kite.
RENEWABLES 2021 GLOBAL STATUS REPORT
OCEAN POWER INDUSTRY
The ocean power industry faced significant challenges in 2020
as the COVID-19 pandemic slowed manufacturing, delayed
deployments and interfered with maintenance schedules. Most
planned deployments were postponed to 2021, although some
deployments took place and power generation continued despite
reduced maintenance. In total, seven tidal stream devices were
successfully deployed in 2020, including a three-turbine array, a large
commercial-scale turbine and smaller demonstration deployments.
In China, the China Three Gorges Corporation (CTG) manufactured
a 500 kW tidal turbine, designed by SIMEC Atlantis Energy, and
deployed it between two islands in Zhoushan archipelago.9 The
CTG also made progress on the Zhoushan tidal current energy
project, deploying a 300 kW turbine.10 Another project, led by
Zhejiang Zhoushan LHD New Energy Corporation Limited
(LHD), achieved cumulative power generation exceeding
1.95 GWh in October 2020.11 The modular device currently
comprises two vertical-axis turbines of 400 kW and 600 kW,
and LHD is working on adding a 1 MW turbine and increasing
the capacity of the platform to 4.1 MW.12 The main structure,
now completed, was planned to be deployed in the first quarter
of 2021.13 The project will be the first to benefit from a temporary
feed-in tariff of EUR 0.33 (USD 0.40) per kWh, introduced in 2019.14
In the United States, Verdant Power installed a 105 kW array of
three tidal power turbines at its Roosevelt Island Tidal Energy
Project site in New York’s East River, marking the first licensed
tidal power project in the country.15 As of January 2020, the
array had operated continuously for three months, achieving
100 megawatt-hours (MWh) of generation in its first 85 days.16 In
Igiugig, Alaska, the Ocean Renewable Power Company (ORPC,
US) redeployed its 35 kW RivGen Power System, a submerged
cross-flow river current turbine.17 Combined with microgrid
electronics and energy storage, the system will reduce diesel use
in Igiugig Village by an estimated 90%.18 OPRC also continued
construction on a second RivGen device, targeting deployment
in summer 2021, and received USD 3.7 million in funding from the
Department of Energy’s Advanced Research Projects Agency.19
Two deployments took place in the United Kingdom in 2020.
Nova Innovation (UK) completed the installation of its 100 kW
turbine in the Shetland Islands.20 This is the first of three turbines
deployed as part of the EnFAIT (Enabling Future Arrays in Tidal)
project, a EUR 20 million (USD 24.6) effort to demonstrate a
viable cost-reduction pathway for tidal energy.21 Nova Innovation
also continued to successfully operate its 0.3 MW array in the
Bluemull Sound in Shetland, where the turbines have generated
without incident since 2016.22 DesignPro Renewables (Ireland)
successfully completed deployment and testing of its 60 kW
DPR60 turbine at Kirkwall in the Orkney Islands, Scotland.23
Minesto (Sweden) installed and commissioned its 100 kW
DG100 tidal kite systemi in the Vestmannasund strait, Faroe
Islands.24 By December, it had successfully delivered electricity
to the Faroese grid under a 2019 power purchase agreement
(signed with the Faroese utility company SEV) for up to
2.2 MW of installed tidal capacity.25 Minesto also is seeking
the necessary permits to deploy a 100 KW device at the EDF-
owned Paimpol Bréhat site in France.26 Minesto received
EUR 14.9 million (USD 18.3 million) in EU funding through the
Welsh European Funding Office in 2019 and completed work in
2020 on its Holyhead assembly hall, which will serve as a hub
for engineering and operational activities.27 An array of up to
80 MW capacity is planned for the Holyhead Deep site, eight
kilometres off the coast of north-west Wales.28
Scotland’s MeyGen tidal stream array (the world’s largest at 6
MW), owned and operated by SIMEC Atlantis Energy (UK),
surpassed 35 GWh of electricity generation in 2020.29 Having
entered its 25-year operational phase in 2018, it generated
continuously in 2019, the longest period of uninterrupted
generation to date from a commercial-scale tidal array.30 In 2020,
the array faced operational challenges, and three turbines were
retrieved for servicing in April 2021.31 SIMEC holds a seabed lease
that would allow it to build the project out to 398 MW.32 SIMEC
also shipped a 500 kW turbine to Japan for installation in early
2021 as part of Kyuden Mirai Energy’s demonstrator project in the
country’s Goto islands.33
Tidal stream
devices generated
15 GWh
of electricity in 2020.
114
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In Canada, the government of Nova Scotia offered a feed-in tariff
of between CAD 385 and CAD 530 (USD 301 and USD 415)
per MWh for demonstration projects.34 As of the end of 2020,
five Canadian developers were approved for a total of up
to 22 MW.35 During the year, NewEast Energy obtained an
800 kW permit under Nova Scotia’s demonstration permits
programme, which issued permits for a total of 9.3 MW of capacity
(of the 10 MW available).36 Canada committed substantial new
funding to tidal projects in 2020, investing CAD 28.5 million
(USD 22.3 million) in Sustainable Marine Energy‘s floating
tidal array (up to 9 MW) and CAD 4 million (USD 3.1 million) in
Nova Innovation’s 1.5 MW array in the Bay of Fundy.37
DP Energy and Sustainable Marine Energy (both Canada)
continued to advance the Uisce Tapa project under development
at the Fundy Ocean Research Centre for Energy (FORCE).
The CAD 117 million (USD 91.5 million) project aims to install
a 9 MW array of six Andritz Hammerfest turbines and is
supported by a Canadian government grant of CAD 29.8 million
(USD 23.3 million).38 BigMoon Power successfully applied to
occupy a vacant berth at FORCE.39 Other provinces also are
making progress on ocean power, particularly as a means to
provide electricity to remote communities.40
Several projects have been progressing in France. The
HydroQuest 1 MW marine tidal turbine prototype was deployed
at Paimpol-Bréhat in April 2019 and connected to the national
grid in June 2019, and has operated continuously since then.41
Featuring a dual vertical-axes design, this cross-flow turbine
turns irrespective of the flow direction, enabling the device to
be fixed to its foundation without any efficiency loss. DesignPro
Renewables continued testing its 25 kW turbine at the dedicated
SEENEOH test site on the Garonne River, where it has been
deployed since September 2018.42 SABELLA (France) is planning
to redeploy its grid-connected D10-1000 tidal energy converter
on Ushant Island in 2021 and is also working with Morbihan
Hydro Energies (France) to deploy two 250 kW turbines in the
Gulf of Morbihan.43 In Normandy, the government approved
the transfer of a 12 MW lease in Raz Blanchard to Normandie
Hydroliennes, a consortium of partners including SIMEC Atlantis
Energy and the Development Agency for Normandy.44
In the Netherlands, the Dutch company Tocardo acquired the
1.25 MW Oosterschelde Tidal Power Plant and subsequently
resumed full continuous operation.45 The plant comprises five
of Torcado’s T-2 tidal turbines mounted on a sluice gate of the
Oosterschelde storm surge barrier.
Two wave power deployments took place in 2020, with most
planned deployments delayed by stalled manufacturing and
pandemic-related lockdowns during the year.
In China, a consortium led by the Guangzhou Institute of Energy
Conversion deployed a full-scale 500 kW wave energy converter.
The Sharp Eagle-Zhoushan converter combines electricity
generation with aquaculture and was deployed as part of the
Wanshan megawatt-level Wave Energy Demonstration Project,
supported by the Ministry of Natural Resources.46 The Penghu
device, based on the Sharp Eagle, completed its 18-month
testing period in December 2020.47 Construction also began on a
second 500 kW device, Changshan.48
Building on a successful
scale test in Denmark,
Danish company Wave-
piston tested a full-scale
device at the Oceanic
Platform of the Canary
Islands (PLOCAN, Spain).
The initial phase of the
200 kW project was
deployed in December
2020.49 The system
pressurises sea water,
which can then be used to drive a turbine or can be pumped
through a reverse osmosis system to obtain desalinated water.
A second device that will produce both electricity and
fresh water was slated for deployment in 2021.50
Existing deployments continued to operate through 2020,
passing some significant milestones. The 296 kW Mutriku wave
plant in Spain, commissioned in 2011, surpassed a cumulative
2 GWh of electricity production.51 At the SEM-REV test site in
France, the Wavegem hybrid wave and solar platform designed
by GEPS Techno reached 18 months of offshore testing, which
began in August 2019.52
US company Ocean Power Technologies (OPT) reported
continuous operation of its device, deployed in the Adriatic
Sea, during its first 18 months.53 The device was leased by Eni,
which in March 2020 opted to extend the lease for an additional
18 months.54 Amid international travel restrictions that delayed
deployment of a device in Chile, OPT contracted with SeaTrepid
International (US) to conduct a remote installation, training local
engineers virtually on technical procedures and installation
requirements.55
Many companies focused on technology and project
development in 2020. For example, Bombora Wavepower (UK)
delayed a planned deployment but accelerated design work on
a 3 MW project scheduled for deployment in Lanzarote, Spain in
2022.56 Bombora also entered into an agreement with Technip
FMC (UK) to develop a floating offshore wind foundation
incorporating wave energy.57 The first phase of the project will
integrate 4 MW of wave power and 8 MW of wind power on a
shared floating platform.58
Wave Swell Energy (Australia) finalised construction of its 200
kW device, scheduled for deployment on King Island, Tasmania in
early 2021.59 Also in Australia, Carnegie Clean Energy continued
to develop its CETO 6 device, after restructuring following the
company’s entry into voluntary administration in 2018.60 Carnegie
also is developing a wave predictor that uses machine learning to
predict wave characteristics up to 30 seconds before they reach
the device, thereby increasing efficiency.61
US-based company Oscilla Power is finishing construction of a
100 kW device, expected to be installed in Hawaii in 2021.62 The
company also entered the planning stages of a 1 MW demonstration
project, targeting deployment off the coast of Kerala in southern
India.63 In the United States, the OEbuoy device developed by
Ocean Energy (Ireland), which was transported from the state of
Oregon to Hawaii in 2019, is expected to be deployed in 2021.64
The EU aims to install
40 GW
of ocean power
capacity by 2050.
115
RENEWABLES 2021 GLOBAL STATUS REPORT
Other ocean power technologies, such as ocean thermal energy
conversion (OTEC) and salinity gradient, remain well short of
commercial deployment, and only a handful of pilot projects have
been launched. REDstack (Netherlands) successfully tested its
reverse electrodialysis (RED) technology and was planning a
first demonstration plant.65 Akuo Energy (France) announced
plans to develop an OTEC plant on Bora Bora, French Polynesia,
as part of the EU-funded project, Integrated Solutions for the
Decarbonization and Smartification of Islands (IANOS).66 Puerto
Rico (US) is in the early stages of developing the Puerto Rico
Ocean Technology Complex (PROtech) and aims to invest an
estimated USD 300 million to build a 5 MW to 10 MW OTEC
plant by mid-2027.67
The Ocean Thermal Energy Association was recently reinvigorated,
and a group of member countries of the International Energy
Agency’s Ocean Energy Systems collaboration are working to
assess the current status and global potential of OTEC, with a
white paper expected in 2021.68
Technology improvements and steep cost reductions are
still needed for ocean power to become competitive in utility
markets. The industry has not yet received the clear market
signals it needs to take the final steps to commercialisation.69
The lack of consistent support schemes for demonstration
projects has proven especially challenging for developers, who
have struggled to build a compelling business case, and the
sector remains highly dependent on public funding to leverage
private investment.70 Dedicated revenue support is considered
paramount for increasing investment certainty by providing
predictable returns until the industry achieves greater maturity.
The 2020 announcement of two large private investments
provide some positive indications. CorPower Ocean (Sweden)
secured EUR 9 million (USD 11 million) in equity funding, and
SIMEC Atlantis concluded a share placement agreement, raising
an initial investment of GBP 2 million (USD 2.7 million), with the
option of increasing this to GBP 12 million (USD 16 million).71 The
UK government is expected to reform its Contract for Difference
(CfD) mechanism, separating ocean power from offshore wind,
thereby increasing price competitiveness.72
As of 2018, more than EUR 6 billion (USD 7.4 billion) had been
invested in ocean power projects worldwide, of which 75%
was from private finance.73 A 2018 European Commission
implementation plan estimated that EUR 1.2 billion (USD 1.5 billion)
in funding was needed by 2030 to commercialise ocean power
technologies in Europe, requiring equal input from private sources,
national and regional programmes, and EU funds.74 The industry
is collaborating to develop a common evaluation framework
for ocean power technologies, aiming to provide clarity for all
stakeholders, including public and private investors.75
Deploying ocean energy at scale also will require streamlined
consenting processes.76 Uncertainty regarding environmental
interactions often has led regulators to mandate significant data
collection and strict environmental impact assessments, which can be
costly and threaten the financial viability of projects and developers.77
Current scientific knowledge suggests that the deployment of a
single device poses little risk to the marine environment, although
the impacts of multi-device arrays are not well understood.78
This calls for an “adaptive management” approach that responds
to new information over time, supported by more long-term data
and greater knowledge sharing across projects.79
116
i For the sake of consistency, the GSR endeavours to report all solar PV capacity data in direct current (DC); where data are known to be in AC, that is specified
in the text and endnotes. Data are preliminary and a range of estimates exists; global estimates in text are based on data from International Energy Agency
Photovoltaic Power Systems Programme and Becquerel Institute. See endnote 1 in this section for further details.
ii Distributed refers to systems that provide power to grid-connected consumers, or directly to the grid, but on distribution networks rather than on bulk trans-
mission or off-grid systems. See endnote 5 for this section. For more on distributed off-grid systems for energy access, see Distributed Renewables chapter.
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SOL AR PV MARKETS
Solar PV had another record-breaking year, with
new installations reaching as much as an estimated
139 GWDCi; this brought the global total to an estimated
760 GWDC, including both on-grid and off-grid capacity.1 These
preliminary global numbers are uncertain, and the level of
uncertainty is increasing year-by-year.
Business closures, stay-at-home orders and restrictions on
movement related to the COVID-19 pandemic all reduced
electricity consumption and shifted daily demand patterns.2 The
pandemic also resulted in delays in shipping and deliveries of
solar panels and related hardware, in customer acquisitions, and
in project permitting and construction, exacerbating existing
challenges in some markets.3 Yet, while growth in some markets
was below the strong expectations going into 2020, solar PV
managed to achieve the largest increase in capacity ever seen
in a single year.4 The distributedii sector was affected more than
the utility sector, but several countries saw surges in residential
demand.5 Looming policy changes at the end of the year drove
much of the growth in the top three markets (China, the United
States and Vietnam), but several other countries also experienced
noteworthy market expansion.6 (p See Figure 25.)
Solar PV had another record-breaking year in
2020. Anticipated policy changes drove much of
the growth in the top three markets – China, the
United States and Vietnam – but several other
countries saw noteworthy expansion.
Favourable economics have boosted interest
in distributed rooftop systems. In South
Australia, the growth of distributed solar PV
has made the state’s power system the first
large-scale system in the world to approach
the point at which rooftop solar PV effectively
eliminates demand for electricity from the grid.
The solar PV industry rode a roller coaster in 2020,
driven largely by pandemic-related disruptions,
as well as by accidents at polysilicon facilities
in China and a shortage of solar glass. These
disruptions, due in large part to heavy reliance on
China as the world’s dominant producer, combined
with concerns about possible forced labour
in polysilicon production, led to calls in many
countries for the creation of local supply chains.
New actors entered the sector. Competition
and price pressures continued to motivate
investment to improve efficiencies, reduce
costs and improve margins.
K E Y FA C T S
SOL AR PHOTOVOLTAICS (PV)
117
i In the United States, tax credits also continued to play an important role. See endnote 20 for this section.
Gigawatts
621621
~760
Gigawatts
World
Total
0
100
200
300
400
500
800
700
600
Annual additions
Previous year‘s
capacity
3939
+17
7070
100100
138138
178178
228228
305305
407407
512512
+31
+30
+38
~760
+40
+50
+77
+103
+104
+110
+139
2016201520142013201220112010 2017 2018 2019 2020
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: Data are provided in direct current (DC). Totals may not add up due to rounding.
Source: Becquerel Institute and IEA PVPS. See endnote 6 for this section.
FIGURE 25.
Solar PV Global Capacity and Annual Additions, 2010-2020
Demand for solar PV is spreading and expanding as it
becomes the most competitive option for electricity generation
in a growing number of locations, both for residential and
commercial applications and increasingly for utility-scale
projects – even without accounting for the external costs of fossil
fuels.7 This also is becoming the case for solar-plus-storage in
an increasing number of markets.8 In 2020, an estimated 20
countries added at least 1 GW of new solar PV capacity, up from
18 countries in 2019, and all continents contributed significantly
to global growth.9 By the end of 2020, at least 42 countries had
a cumulative capacity of 1 GW or more.10
Solar PV plays a meaningful role in electricity generation in
a growing number of countries. By the end of 2020, at least
15 countries had enough capacity in operation to meet at least 5%
of their electricity demand with solar PV.11 Solar PV accounted for
around 11.2% of annual generation in Honduras and for notable
shares also in Germany (10.5%), Greece (10.4%), Australia (9.9%),
Chile (9.8%), Italy (9.4%) and Japan (8.5%), among others.12 Spain
and the United Kingdom broke solar generation records early in
the year, due largely to new capacity as well as to higher output
resulting from clearer air during COVID lockdowns; clearer skies
during lockdowns also enabled nearly 10% more sunlight to reach
solar panels in Delhi and contributed to increased output in the
United Arab Emirates.13 However, smoke from wildfires in Australia
and the US state of California had the reverse effect on output,
while also negatively affecting solar variability and forecasting.14
There are still challenges to address for solar PV to become
a major electricity source worldwide, including policy and
regulatory instability in many countries, unreliable or insufficient
grid infrastructure, and financial and bankability challenges.15
As the level of penetration rises, the variability of solar PV is
having an increasing effect on electricity systems, raising the
importance of effectively integrating solar energy under varying
technical and market conditions in a fair and sustainable
manner.16 In general, opposition to solar PV deployment from
local incumbents is lower than a decade ago, with many utilities
now actively engaged in solar PV deployment and operations,
including distributed generation; however, opposition persists
in several countries and among some actors, particularly in the
fossil and nuclear energy industries.17
The cost-competitiveness of solar PV is increasingly a driver
of investment, but generally it is insufficient on its own.18 In
most countries, there is still a need for adequate regulatory
frameworks and policies governing grid connections to
overcome cost or investment barriers in some markets and
to ensure a fair and level playing field.19 Government policies
continued to propel most of the global market in 2020, with
feed-in tariffs (FITs) and tenders the leading policy driversi of the
centralised market, and FITs and incentivised self-consumption
or net metering the primary drivers of the distributed market.20
(p See Distributed Renewables chapter for off-grid solar and
related policies for energy access.)
118
i Note that Turkey is considered to be part of the Asia region for purposes of the GSR.
ii This is the capacity addition of the Netherlands, which ranked tenth for annual installations.
iii “Distributed” solar PV in China includes ground-mounted systems of up to 20 MW that comply with various conditions, in addition to commercial,
industrial and residential rooftop systems. Distributed generation consists largely of commercial and industrial systems and, increasingly, residential
and floating projects. See endnote 29 for this section.
20172016201520142013201220112010 20202018 2019
Rest of World
India
Japan
United States
European Union
China
0
100
200
300
400
500
700
Gigawatts
800
600
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Self-consumption continued to represent an important and
growing share of the market for new distributed systems in several
countries.21 Although still a small share of the annual market,
a number of purely competitive (without direct government
support) large-scale systems were being constructed in 2020;
interest in this segment is considerable and growing rapidly.22
For the eighth consecutive year, Asiai eclipsed all other regions
for new installations, accounting for nearly 58% of global
additions; even excluding China, Asia was responsible for around
23% of new capacity in 2020.23 Asia was followed by the Americas
(18%), which moved ahead of Europe (16%).24 China continued to
dominate the global market (and solar PV manufacturing), with a
share of nearly 35% (up from 27% in 2019).25
The top five national markets – China, the United States, Vietnam,
Japan and Germany – were responsible for almost 66% of newly
installed capacity in 2020 (up from 58.5% for the top five in 2019
but down from around 75% in 2018, as the global market becomes
somewhat less concentrated); the next five markets were India,
Australia, the Republic of Korea, Brazil and the Netherlands.26 The
annual market size required to rank among the top 10 countries
remained at around 3 GWii.27 The leading countries for cumulative
solar PV capacity continued to be China, the United States, Japan,
Germany and India, and the leaders for capacity per capita were
Australia, Germany and Japan.28 (p See Figure 26.)
China added 48.2 GW of solar PV capacity in 2020 (including
32.7 GW of centralised and 15.5 GW of distributediii solar PV),
making the year second only to 2017 (52.9 GW) for annual
additions.29 The market increase of 60% – driven largely by
pending changes to the country’s FIT structure – followed two
consecutive years of contraction, and came despite project
construction delays early in 2020 caused by pandemic-related
labour shortages and supply chain disruptions.30 The central,
eastern and southern regions of China accounted for about 36%
of additions, with 64% in the western and northern regions.31
The leading provincial installers were Guizhou (5.2 GW), Hebei
(4.9 GW) and Qinghai (4.1 GW).32 At year’s end, China’s total
grid-connected capacity exceeded 253.4 GW, well above the
official 13th Five-Year Plan (2016-2020) target for the year
(105 GW).33
A major driver of China’s solar PV market was a rush to install
projects before the national FIT was phased out at year’s end
for centralised as well as commercial and industrial distributed
systems.34 The policy changes result from a mounting deficit
in China’s Renewable Energy Development Fund, which has
caused a backlog of outstanding FIT payments for existing
projects (only worsened by the pandemic), and from the central
government’s belief that solar (and wind) power is capable of
competing without subsidies with coal-fired power.35
Note: Data are provided in direct current (DC). European Union includes the United Kingdom throughout the 2010-2020 period.
Germany's share of the EU total has declined from over 58% in 2010 to just under 36% in 2020 due to growth in other EU markets.
Source: See endnote 28 for this section.
FIGURE 26.
Solar PV Global Capacity, by Country and Region, 2010-2020
119
Gigawatts
China
+28.7+28.7
+11.1+11.1 +4.1+4.1
+4.4+4.4
+4.1+4.1
0
100
50
150
20
40
60
80
200
300
250
Rest
of World
100
+48.2+48.2
+8.2+8.2
Added
in 2020
2019 total
+4.9+4.9
+3.1+3.1 +3.0+3.0
+19.2+19.2
NetherlandsBrazilRepublic
of Korea
AustraliaIndiaGermanyJapanVietnamUnited
States
RENEWABLES 2021 GLOBAL STATUS REPORT
China’s market for
centralised utility systems
(greater than 20 MW)
expanded considerably,
up nearly 83% in 2020.36
The increase is thanks in
part to the completion of
enormous hybrid projects
– combining solar PV,
wind power and energy
storage – by some of
the biggest state-owned
companies.37 China’s largest solar-plus-storage project (2.2 GW
of solar PV plus nearly 203 MW of battery storage) was connected
to the grid in late 2020 in the desert of Qinghai province.38 Total
distributed installations also rose (27%) during the year, with
annual additions of residential systems almost doubling relative
to 2019 (to 10.1 GW) and more than making up for a decline
in commercial and industrial installations (5.4 GW).39 Most
of the residential capacity was added in Shandong province
(4.57 GW) and Hebei greater area (4.1 GW).40
Curtailment of solar energy in China averaged 2% for the year,
unchanged from 2019, although the average rate was higher
during pandemic-related lockdowns in January (2.8%) and
February (5.6%) due to reduced electricity consumption.41 The
curtailment rate continued to be highest in northwest China,
particularly in Xinjiang and Gansu, but the region’s annual
average declined to 4.8%.42 Minimising curtailment is a national
priority and is considered particularly important for utility-scale
“grid parity” projects, which were introduced in 2019 to help
China move away from subsidies.43 China’s output from grid-
connected systems increased more than 16% in 2020, to 261
TWh, bringing solar PV’s share of electricity generation (from
grid-connected sources) to 3.4% in 2020 (up from 3% in 2019).44
The central and provincial governments are focused increasingly
on renewable energy integration. In 2020, China’s central
government issued guidance to ensure that renewable electricity
is consumed locally, to the extent possible, and governments at
all levels increasingly link solar PV support and bidding rounds
to energy storage and local grid capacities.45 By the end of
2020, one-third of China’s provinces mandated that new
solar PV installations be combined with energy storage.46
Vietnam saw another surge in installations: after adding
4.8 GW in 2019 (up from 106 MW in 2018 and 8 MW in 2017),
the country brought an estimated 11.1 GW into operation in
2020, raising it to third place globally for additions and eighth
for total solar PV capacity.47 (p See Figure 27, and Reference
Table R15 in GSR 2021 Data Pack.) Whereas growth in 2019
was driven by the pending expiration of Vietnam’s FIT1
scheme, which encouraged large ground-mounted projects,
most of the increase in 2020 was in rooftop systems, racing to
qualify for the FIT2 before it expired at year’s end.48
Note: Data are provided in direct current (DC).
Source: See endnote 47 for this section.
FIGURE 27.
Solar PV Capacity and Additions, Top 10 Countries for Capacity Added, 2020
Vietnam added an
estimated
11.1 GW in 2020,
up from 4.8 GW in 2019
and 0.1 GW in 2018.
120
i For details on India, see endnote 59 for this section.
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In total, nearly 83,000 rooftop systems were installed in Vietnam
in a single year, increasing rooftop capacity from less than
0.4 GW to 9.7 GW (with 6.7 GW connected in December alone),
and bringing the country’s total solar PV capacity to 16.4 GW.49
Vietnam’s interest in solar PV is largely to meet rising electricity
demand – which has increased 10% annually on average in recent
years due to population growth and economic expansion – as
well as to ensure energy security and reduce carbon emissions.50
The rapid growth in solar generation has placed additional
stress on the country’s underdeveloped grid, leading to
curtailment, and as of early 2021 Vietnam was considering
options for financing necessary system upgrades.51
The third largest market in Asia and the fourth largest globally was
Japan.52 Following four years of contraction, Japan added 8.2 GW
(up more than 16%) for a total of 71.4 GW – surpassed only by China
and the United States.53 However, Japan’s market continued to face
challenges related to land availability and grid constraints, which
are helping to keep the country’s large-scale solar PV costs among
the highest in the world.54 In 2020, the country’s FIT was revised
to focus support on systems for locally consumed generation (self-
and community-consumption), the ability to isolate in the event
of blackouts, and agricultural PV (see later discussion).55 Solar
PV accounted for an estimated 8.5% of Japan’s total electricity
generation in 2020, up from 7.4% in 2019, with the highest
local contributions in Shikoku (13%) and Kyushu (14%).56
India’s solar PV market contracted again, to the lowest level in five
years, and investments in the solar sector were down 66% relative
to 2019.57 Despite the ongoing decline, India ranked sixth globally
for additions and fifth for total capacity.58 Around 4.4 GWi of solar
PV capacity was added during the year, bringing the national
total to 47.4 GW.59 In the large-scale market, pandemic-related
lockdowns and labour shortages delayed project construction and
auctions.60 These setbacks further aggravated existing challenges,
such as the lack of transmission infrastructure and land permits,
the reluctance of distribution companies to sign power purchase
agreements (PPAs) (due to expectations that project bids at
auction will continue to fall at a rapid pace), the extension of duties
on imported solar equipment and the cancellation of some projects
awarded under earlier auctions due to regulatory delays.61
The rooftop market (1.3 GW) in India has been hampered by
inconsistent government policy and restrictions, as well as
by uncertainties related to the pandemic and pressure by
distribution companies to discontinue net metering and adopt
grid usage charges.62 After falling through much of 2020,
demand for rooftop systems rose towards the end of the year as
government incentives enticed residential consumers, and as the
commercial and industrial sectors (the primary rooftop markets)
saw solar as a means to reduce their operational costs.63
Other Asian countries that added substantial capacity in 2020
included the Republic of Korea (4.1 GW), Chinese Taipei (1.7 GW)
and the Philippines (1.1 GW).64 The Republic of Korea moved up
two steps in the global rankings for capacity added, to eighth
place, and continued to rank ninth for total capacity (15.9 GW).65
Turkey added an estimated 1 GW for a total of 9.5 GW.66 The
Turkish market was driven by a new net metering law and self-
consumption, representing a shift away from the traditional
market of megawatt-scale projects.67 Pakistan also added
capacity, as did Kazakhstan, which held auctions and brought
online at least two large projects in 2020.68
The Americas represented around 18% of the global market in
2020, due largely to the United States, which continued to rank
second globally for both new installations and total capacity.69
(p See Figure 28.) The country added a record 19.2 GW – up
43% over 2019 and 27% above the previous peak in 2016 – for a
total approaching 96 GW.70 Solar PV was the leading source of
new power capacity for the second consecutive year, accounting
for 43% of all US power capacity additions in 2020 (compared
with 4% a decade earlier), the largest share to date.71 The market
continued to be more geographically diverse, with 27 states
adding more than 100 MW, even as the top states for additions
remained California (3.9 GW), Texas (3.4 GW) and Florida
(2.8 GW).72 Utility-scale solar PV (87.7 TWh) plus grid-connected
small-scale systems (41.7 TWh) generated a total of 129.5 TWh, or
3.2% of US net generation in 2020.73
121
i Includes commercial, government, non-profit and community solar PV systems.
35%
21%
23%
China
8% Vietnam
Rest of World
Japan 6 %
Germany 4 %
India 3 %
Australia 3 %
Republic of Korea 3 %
Brazil 2 %
Netherlands 2 %
Next 7 countries
14%
United States
RENEWABLES 2021 GLOBAL STATUS REPORT
The US market was led by the utility-scale sector, which was
up 67% to nearly 14 GW, for a year-end total of 59.8 GW.74
The significant jump came as developers rushed to qualify
for the federal investment tax credit (ITC) before the expected
rate reduction at the end of the year (the rate ended up being
extended for two years in December 2020).75 The volume of
new projects announced in 2020 reached 30.6 GW, bringing the
pipeline of US utility-scale solar PV projects under contract at
year’s end to 69 GW.76 Growth in this sector is driven by several
factors, including self-enforced utility carbon reduction plans, the
expansion of state-level mandates through renewable portfolio
standards (RPS laws), and large corporations with renewable or
carbon reduction goals (p see Feature chapter).77
Non-residentiali installations declined (down 4%) for the
third consecutive year and faced the worst pandemic-related
delays of any sector, adding 2.1 GW for a total of 16.7 GW.78
In contrast, the residential market rose 11% compared with
2019, with a record 3.2 GW added for a total of 19.1 GW.79 The
pandemic caused great disruption in this sector as well, with
installers laying off thousands of employees and some filing
for bankruptcy, and it forced many installers to shift sales from
in-person to online and to make serious price cuts.80 Battles to
weaken state net metering laws also continued during the year.81
Despite the challenges, the market picked up considerably
in the second half of 2020 due in part to increased interest
in home improvements.82 Residential solar PV with battery
installations also rose, particularly in California following rolling
power outages due to massive wildfires.83
Demand for solar-plus-
storage systems was up
in all US sectors in 2020.
It accounted for nearly
6% of behind-the-meter
solar systems and for
more than one-fourth
of all contracted utility-
scale projects.84 Utility
commissions in some
states (e.g., Nevada)
established goals for
energy storage procurement, and some utilities brought into
operation new solar-plus-storage plants, while others released
solicitations for new capacity.85 Interest in energy storage for
large-scale plants has been driven by falling costs (of both solar
generation and batteries) combined with rising solar energy
penetration, which improves the business case for projects that
can dispatch this power to meet evening peak demand.86 Demand
is also growing for hybridised solar and wind power plants,
encouraged by falling costs and looming tax credit deadlines,
and as a means to optimise land use and transmission capacity
and to increase revenue.87 (p See Systems Integration chapter.)
A handful of countries in Latin America and the Caribbean
continued to expand their solar PV capacity, despite challenging
economic conditions, thanks largely to an abundance of solar
resources, falling prices and favourable policies in some countries.88
The region’s top four installers in 2020 were Brazil (adding 3.1 GW),
Mexico (1.5 GW), Chile (0.8 GW) and Argentina (0.3 GW).89
Note: Totals may not add up due to rounding.
Source: See endnote 69 for this section.
FIGURE 28.
Solar PV Global Capacity Additions, Shares of Top 10 Countries and Rest of World, 2020
Increased interest in
home improvements
during the pandemic
helped drive demand for
new residential
systems
in several countries.
122
i The Contracts for Difference (CfD) is the UK government’s primary mechanism for supporting renewable electricity generation. Developers that win contracts
at auction are paid the difference between the strike price (which reflects the cost of investing in the particular technology) and the reference price (a measure
of the average market price for electricity).
ii Merchant projects are those with no regulated or contracted income. The electricity generated is sold into competitive wholesale markets.
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Brazil maintained its regional lead for annual additions and
surged past Mexico (5 GW) for total capacity, ending the year
with 7.7 GW.90 Annual installations in Brazil were up 68.6% over
2019.91 For the second year running, Brazil’s distributed segment
(defined as less than 5 MW) led the market for capacity added
(2.5 GW), investments and job creation, driven by a national net
metering regulation and electricity prices rising above inflation
rates.92 Residential systems accounted for the largest portion
of distributed installations (74.4%), but commercial and rural
systems also saw rising shares.93
During 2020, the debate regarding proposed changes to Brazil’s
net metering mechanism was interrupted as the National
Congress turned its focus to the pandemic, but a new legal
framework for distributed generation was under development in
early 2021 and expected to soon become law.94 Public energy
auctions for large-scale power plants were postponed, also due
to the pandemic, but new tenders (including for solar PV) were
scheduled for the years 2021-2023.95 Large projects also moved
ahead in the private sector: Brazil’s largest-ever solar PPA was
signed in March for the 330 MW Atlas Casablanca plant, which
will provide electricity for Anglo-American mining operations.96
The mining industry also helped drive new installations in Chile,
where a copper mining company signed a PPA in 2020 for
around-the-clock solar energy (with battery storage) to cover
12% of the Collahuasi mine’s electricity needs.97 Also in Chile,
an existing plant reportedly became the world’s first utility-scale
solar PV facility licensed to deliver commercial ancillary services
to the grid.98 Chile’s solar PV capacity was approaching 3.5 GW
at year’s end, with another 3.9 GW under construction.99
Europe followed the Americas for additions in 2020, with more
than 22 GW added for a year-end total of 162.7 GW, maintaining
its second-place regional ranking for total operating capacity.100
Installations in the EU-27 were up significantly relative to 2019,
and noteworthy additions also occurred elsewhere in the region.101
The Russian Federation nearly doubled its operating capacity,
adding more than 0.7 GW for a total of 1.9 GW.102 The United
Kingdom added 0.5 GW, above installations in the previous year
but well below the 2015 peak (4.1 GW), bringing total capacity
to 13.9 GW.103 However, several additional large-scale projects
without direct subsidies were under construction in the country,
some incorporating energy storage to access higher market
prices.104 As part of the effort to accelerate decarbonisation, the
UK government announced plans to reopen access to Contracts
for Differencei auctions for solar PV (and onshore wind power),
for the first time since 2015.105
Installations in the EU-27 were well below expectations due to
the pandemic; nevertheless, 2020 turned out to be the region’s
second-best year on record, and solar PV provided more
new power capacity than any other generating technology.106
Around 19.3 GW was brought online, raising total solar PV
capacity by about 15%, to 140.5 GW.107 Most EU markets have
moved beyond FITs and are propelled by the competitiveness
of solar generation – in many EU Member States, solar PV is
now the cheapest incremental source of electricity and the
fastest to install.108 Economic competitiveness is elevating
interest in self-consumption and corporate renewable power
sourcing (including via direct bilateral PPAs), and is encouraging
governments that are looking to meet national renewable energy
targets through tenders.109 At the same time, new challenges are
emerging, including access to grid connections, land availability
and planning permission (particularly in areas that already have
a large installed base), and a shortening of PPA time periods with
the shift towards merchant projectsii.110
123
i The United Kingdom ranks third in Europe for total capacity, following Germany and Italy.
ii Exceeding the 52 GW cap would have ended feed-in payments for new systems up to 750 kW. The revised law, passed in December, maintains the feed-in
payment for systems up to 300 kW. See endnote 119 for this section.
RENEWABLES 2021 GLOBAL STATUS REPORT
In 2020, 22 of the 27 EU
Member States added
more capacity than they
had installed in 2019;
even so, nearly three-
fourths of new capacity
came online in only
five countries.111 Germany
regained its top position
(held for most of the past
two decades) from Spain,
and was followed by
the Netherlands (3 GW), Spain (2.8 GW), Poland (2.6 GW) and
Belgium (1 GW).112 The top EU countriesi for total capacity at year’s
end were Germany, Italy, Spain, France and the Netherlands.113
Germany saw another large jump in installations (up 27%), with
nearly 4.9 GW added for a total approaching 53.9 GW.114 The
commercial segment saw slower growth in 2020, but still expanded
slightly and accounted for 59% of the total market.115 The large-scale
segment (>750 kW, mostly ground-mounted) accounted for less
than 18% of the market, but it saw substantial growth (up 61%) as a
result of special tenders.116 Demand for residential rooftop systems
(<10 kW) nearly doubled relative to 2019, and the sector accounted
for 23% of the annual market (up from 15%) as homeowners became
increasingly motivated by environmental concerns and the desire for
energy independence and electric mobility.117 More than half of the
new rooftop systems (<10 kW) were installed with battery storage.118
The 52 GW capii on solar PV systems under Germany’s feed-in
law was officially removed in July, only weeks before the limit
was reached.119 In late 2020, the federal government set new
targets for 83 GW by 2026 and 100 GW by 2030 under the new
Renewable Energy Sources Act (EEG).120 As solar PV penetration
continues to rise, feed-in management is playing an increasingly
important role. The EEG includes specific requirements for solar
systems, depending on plant size, to enable the grid operator to
remotely modulate the amount of electricity fed into the grid, as
needed.121 Solar PV produced an estimated 50.6 TWh in 2020,
accounting for 10.5% of Germany’s electricity generation.122
The Netherlands has seen steady market growth for several years,
driven by net metering for residential and small business systems
and tendering for larger plants.123 More than 3 GW was added
in 2020 (nearly half of which was commercial rooftop systems)
for a total of 10.2 GW.124 Interest in floating solar PV plants and
solar carports increased during the year, and the country’s largest
ground-mounted plant (110 MW) became operational.125 For all of
2020, grid-connected solar PV covered around 6.6% (7.92 TWh)
of the country’s electricity demand.126
Spain added around 2.8 GW in 2020 for a total of 12.7 GW.127
Whereas much of the capacity added in 2019 had been due to
tenders held in 2017, in 2020 a large portion of installations was
private PPAs for projects without direct public support.128 This
marks the first time that such a sizeable amount of capacity has
been grid-connected in Europe without a government subsidy
or auction programme.129 Spain’s self-consumption market
expanded nearly 30%, with tremendous growth in the residential
sector.130 Solar PV capacity accounted for 6.1% of Spain’s
electricity generation in 2020, up from 3.5% in 2019.131
The annual market in Poland more than doubled in 2020 (2.6 GW
added for a total of 3.9 GW), driven by favourable self-consumption
policies and low-interest loans.132 Industrial consumers have started
turning to renewables, including solar PV, in place of coal-fired
generation.133 Other notable developments in Europe included:
Switzerland saw a record market increase (up at least 30%), driven
in part by a rising desire for energy self-sufficiency; in Denmark
a solar initiative was under way to enable more than 400,000
residents to become shareholders in solar parks (totalling 1 GW)
across Denmark and Poland; and Lithuania reportedly became the
first country in the world to launch an online platform that enables
consumers to buy electricity from a remote solar panel.134
In the South Pacific, Australia continued to be the largest
market by far, ranking seventh globally for both additions and
total capacity.135 The first half of 2020 was challenging due to
devastating bushfires, delays in finalising grid connections as
well as the pandemic, all of which caused a lull in utility-scale
installations early in the year.136 But the fires also affected
thousands of kilometres of transmission and distribution lines,
which drove interest in – and policies supporting – micro grids
and stand-alone power systems, particularly solar PV, in remote
and rural areas.137 Overall, Australia added an estimated 4.1 GW
of solar PV capacity in 2020 for a total exceeding 20.4 GW.138
Despite the impacts of fires on solar output across much of the
country, solar PV generation rose more than 24%, to 22.5 TWh,
or 9.9% of Australia’s total; small-scale rooftop systems alone
accounted for 6.5% of total generation.139
The rooftop sector continued to contribute most of the capacity
added in Australia, with new records set for both solar PV and
home battery storage installations.140 More than 2.6 GW of solar
PV systems under 100 kW was installed on rooftops of homes
and small businesses in 2020, up from about 2.3 GW in 2019, for a
total exceeding 13 GW.141 Households added an estimated 23,796
small-scale battery systems (up 5% over 2019), with a combined
capacity of 238 MWh.142
The surge in demand for both solar PV and home storage
systems in Australia was driven by several factors, including
concerns about climate change, rising electricity costs,
supportive policies, the desire for energy independence and
pandemic-related impacts (home energy bills rose due to remote
work, even as solar prices continued to fall, and people had more
time to devote to home improvements).143 By one estimate, nearly
2.7 million homes and businesses across the country had rooftop
solar systems by the end of 2020.144 As of early 2021, the share
of dwellings with solar PV systems exceeded 20% in every state
and territory except Tasmania; the top three were Queensland
(41%), South Australia (40.3%) and Western Australia (33.2%).145
Small-scale rooftop systems
alone accounted for
6.5%
of Australia's total
electricity generation
in 2020.
124
i The decline in oil and gas prices decreased revenue in some countries, while falling energy prices due to lower demand also reduced the incentive to shift to
renewable energy. See endnote 159 for this section.
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The state of South Australia has achieved one of the highest
levels of solar penetration in the world and faces a widening
mismatch between supply and demand. On many days, the
amount of electricity entering the grid is well above the level of
demand, making the state’s power system the first large-scale
system in the world to approach zero operational demand due
to the growth of distributed solar PV, and requiring a number of
measures to maintain grid stability and manage the electricity
system.146 In response, new tariffs were introduced to encourage
a shift in consumption to peak solar hours, as well as new
technical requirements that enable the market operator to turn
off systems remotely.147
Across Australia, transmission infrastructure has not kept pace
with the growth of renewables, especially large-scale solar (and
wind) power projects.148 Grid challenges, including insufficient
system strength and congestion combined with a lack of clarity
about state and federal policies, have resulted in delayed and
cancelled renewable power projects, and have raised barriers to
investment.149 In early 2020, frustration over grid congestion led
Victoria to break away from national electricity market rules in
order to enact legislation to upgrade transmission infrastructure
and prioritise storage and other projects to ensure a resilient
energy system.150
To address challenges related to utility-scale projects in
particular, the Australian Energy Market Operator (AEMO) was
developing plans in 2020 for several Renewable Energy Zones
(REZs) across five Australian states; the REZs will host solar and
wind power projects co-located with energy-intensive industry,
along with energy storage and strong grid connections.151
In addition, Australia has seen a surge in small utility-scale
systems (especially around 5 MW), which are relatively easy to
grid-connect and face fewer transmission constraints.152
Other markets in the South Pacific remained small in comparison.
In 2020, New Zealand commissioned a 1 MW floating array atop
a wastewater treatment lake, the country’s largest installation,
and the Cook Islands, Fiji, Micronesia, New Caledonia, Papua
New Guinea and the Kingdom of Tonga were among the small
island states setting targets, commencing pilot programmes
or launching tenders for solar PV (plus storage in many cases)
in their efforts to reduce reliance on fuel imports and provide
universal electricity access.153 Fiji has seen rapid growth in
commercial rooftop systems since 2015 and, in 2020, moved
closer to its target of 100% renewable energy with plans to add
at least 15 MW to the national grid.154 As of 2020, Micronesia
generated more than 11% of its electricity with solar PV.155
The Middle East and Africa combined added an estimated
4 GW in 2020 for a year-end total as high as 24 GW.156 An
increasing number of countries across the region had net
metering policies in place (e.g., Israel, United Arab Emirates) or
introduced or passed new laws to that effect (e.g., Egypt, Ghana,
Kenya, Morocco, Nigeria).157 Several countries also published
requests for qualification (Saudi Arabia), floated tenders or
awarded capacity for solar PV projects (e.g., Israel, Malawi, Syria,
Tunisia, United Arab Emirates, Zimbabwe).158
In the Middle East, social impacts of the pandemic, combined
with a decline in oil and gas pricesi, slowed progress in the
planning and completion of new solar PV projects.159 At the
same time, the pandemic highlighted the importance of energy
security and increased awareness of and political support for
more-sustainable energy sources.160 The largest installers in the
region were Israel (0.6 GW), Oman (0.4 GW) and the United Arab
Emirates (at least 0.3 GW).161 Dubai (UAE) completed phase 3
(totalling 0.8 GW) of its Mohammad Bin Rashid Solar Park,
Jordan brought online a 46 MW plant, and Oman’s first renewable
independent power producer (125 MW) began commercial
operations.162 Oman also announced plans for a 3.5 GW project
to produce hydrogen with solar PV and is targeting thousands
of residential rooftop installations in Muscat.163
Focus on distributed rooftop generation is increasing across
the Middle East as a means to provide energy access and to
reduce electricity bills for residential, commercial and industrial
consumers.164 In 2020, Saudi Arabia launched its first regulatory
framework for 1-2 MW grid-connected systems, and several
other countries in the region were creating initiatives to advance
distributed solar PV in the commercial and industrial sectors.165
At year’s end, the top countries in the Middle East for total
operating capacity were the United Arab Emirates (almost
3 GW), Israel (2.5 GW) and Jordan (1.5 GW).166
125
i Countries that added their first plants of 50 MW and larger in 2020 include Mali and Oman. See endnote 179 for this section.
ii This project totals 2,245 MW (45 MW larger than China’s plant in Quinghai).
RENEWABLES 2021 GLOBAL STATUS REPORT
Across Africa, as costs
of solar PV (as well as
batteries) fall, solar PV
is viewed increasingly
as a means to achieve
a variety of objectives,
depending on the
country. These include
improving reliability and
security of electricity
supply, diversifying the
energy mix (and either reducing energy imports or increasing
exports), providing energy access, and meeting rising electricity
demand while limiting the growth of CO2 emissions.167 (p See
Distributed Renewables chapter for more on solar PV for energy
access.) Interest in solar energy for hospitals and other critical
facilities also increased as part of national responses to the
pandemic.168 Considerable challenges remain, including a lack of
suitable financing tools, lack of transparency, ongoing subsidies
for fossil fuels in many countries, social and political unrest in
some countries, and a heavy reliance on tenders for new capacity
combined with a race to the bottom in bid prices.169 Yet, some
of the challenges (such as lack of regulatory frameworks for
independent power producers and weak transmission grids) are
helping to drive commercial and industrial markets for distributed
solar PV.170
Several countries across Africa commissioned new capacity in
2020. West Africa’s largest plant (50 MW) came online in Mali,
where hydropower accounts for around half of the country’s
installed capacity but provides increasingly variable output
due to hydrological changes.171 Medium-to-large projects were
commissioned or began construction in several other countries,
including Egypt, Ethiopia, Ghana, Somalia and South Africa.172
The Egyptian government’s gradual removal of subsidies on
retail electricity prices is increasing the appeal of distributed
solar PV for residential, commercial and industrial uses.173 At
year’s end, Africa’s top countries for total capacity were South
Africa with 3.8 GW (added 1.1 GW), Egypt with around 2 GW
and Algeria with 0.5 GW.174
Around the world, favourable economics are raising interest
in distributed rooftop systems, which gained market share
relative to large utility-scale projects, from around 35% in 2019
to around 40% in 2020; this was due mainly to strong growth
in Vietnam, as well as increases in Australia, Germany and the
United States.175 Utility-scale capacity also rose during the year,
and the size and number of large-scale projects continued to
grow.176 (Even the size of distributed systems is trending larger
in many countries.177) The move towards ever-larger ground-
mounted systems is due at least in part to the growing use
of tenders and auctions, and increasingly also to PPAs, as
developers work to further reduce the price of solar electricity
through economies of scale in construction and in operations
and maintenance.178
During 2020, around 80 plants of 50 MW and larger were
completed (exceeding 21 GW in combined capacity), and such
plants were operating in at least 49 countriesi by year’s end.179
Developers completed at least 30 projects with capacity of
200 MW or larger.180 In addition to those mentioned earlier, new
facilities included Spain’s 500 MW Nuñez de Balboa, Europe’s
then-largest solar PV plant, which will serve several clients
through PPAs; and India’s 2.2 GWii Bhadla solar park, which
became the world’s largest with the completion of an additional
300 MW.181 Numerous other large projects around the globe were
either under way, completed construction or came online.182
If ground-mounted solar PV plants are well-designed and -built,
competition over land can be reduced, and studies have shown
that they can help to conserve biodiversity; however, large-scale
ground-mounted plants can cover vast areas and their increasing
numbers and scale are raising concerns about potential impacts
on ecosystems and landscapes, grid-connection challenges
and the use of agricultural lands and groundwater supplies (for
cleaning).183 As a result, there is increasing interest in alternatives.
The potential for rooftop solar systems remains enormous, and
many countries have established large rooftop programmes and
targets.184 There are also several niche markets that minimise
land requirements, including building-integrated PV (BIPV),
which is progressing only slowly, and the emergence of plans
among mainstream auto manufacturers, particularly in Asia,
to incorporate solar cells into electric vehicles.185 Several BIPV
projects were completed during 2020, including in India and the
United States; in Europe the sector is driven mainly by France
and Italy, which have targeted support schemes.186
The relatively small market for floating solar also continued its
rapid expansion, driven by the limited availability and high costs
of land in many places, as well as by design innovations that are
helping to reduce costs.187 Floating projects bring new risks and
generally higher costs than ground-mounted facilities, but they
also provide benefits (e.g., reducing land use for solar projects,
reducing evaporation), especially where land is scarce or where
they can be combined with hydropower.188 Economies of scale in
project sizes are helping to reduce associated costs.189
Ground-mounted systems are
growing
ever larger
as developers work to
further reduce the price
of solar electricity through
economies of scale.
126
i Glass prices rose sharply due to a combination of stagnating supply and the global year-end rush for solar PV installations, combined with rising interest in
larger modules as well as bifacial panels. Stagnating supply resulted from a cap on glass production capacity in China (home to 90% of global production
capacity) in response to past overcapacity in the building industry as well as environmental concerns associated with glass production. By one estimate,
shortages pushed up global solar glass prices more than 70% between July and November 2020. See endnote 202 for this section.
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Most floating solar PV projects are sited in Asia, but they can
be found in virtually every region.190 By one estimate, more
than 60 countries had such projects under way or in operation,
and total global capacity reached around 2.6 GW in 2020.191
Projects that became operational during the year included: in
the Netherlands, Europe’s largest floating plant (27.4 MW) was
connected to the regional grid; in Ghana, the first section (5 MW)
of a floating project was connected to the transmission system
of a dam on the Black Volta River; and Chile’s largest floating
project was deployed under the country’s net billing scheme.192
As of early 2021, the largest floating solar plant in operation was
a 181 MW plant off the west coast of Chinese Taipei.193 Interest
in moving offshore is rising, despite the additional challenges
associated with currents, waves and salt water.194
Agricultural PV – the use of the same site for both energy and crop
production – also is a rapidly emerging sector that can address
concerns associated with land use, especially with the growing
availability of bifacial systems (see later discussion).195 Rising
interest in this sector is also driven by concerns about potential
impacts of climate change on crops and livestock.196 While costs
are higher relative to traditional ground-mounted systems, several
studies have highlighted the advantages, including improved crop
yields, reduced evaporation, rainwater harvesting (with modules),
provision of shade for livestock or crops and protection against
extreme weather events, prevention of wind and soil erosion, as
well as additional income for farmers associated with electricity
production.197 Agricultural PV projects have been deployed for
a number of years in Japan, the Republic of Korea and India,
where there are active programmes to encourage deployment,
and numerous pilot projects were under way during 2020 across
Europe, China, Israel and the United States.198
SOL AR PV INDUSTRY
The solar PV industry rode a rollercoaster in 2020, with shockwaves
of disruption driven largely by the pandemic. In early 2020, China
– the dominant producer and global supplier of solar PV cells
and modules – closed manufacturing and distribution facilities
in several provinces.199 As China began reopening by the second
quarter, further disruption was triggered by pandemic-forced halts
in the construction of solar projects in Europe, then the United
States and elsewhere; at the same time, widespread economic
closures reduced electricity demand and created uncertainties
over future wholesale prices in many countries, slowing investment
in new projects and the signing of PPAs.200 By the third quarter,
restrictions were eased and project construction resumed in
many markets.201 Also, however, starting mid-year, accidents at
polysilicon facilities in Xinjiang, China, as well as a shortage of solar
glass, drove up module pricesi.202 Despite the many challenges,
new actors continued to enter the sector, and competition and
price pressures have motivated investment in technologies across
the value chain to improve efficiencies, reduce the levelised cost of
energy (LCOE) and improve margins.203
In response to COVID-related challenges, several countries
supported their domestic solar industries by extending
completion deadlines for awarded capacity or modifying tenders
(e.g., Germany, France, India), or by extending deadlines for
projects to receive incentives (e.g., the United States).204 Spain’s
Royal Decree explicitly included solar PV as a key part of the
national economic recovery, as did Italy’s Relaunch Decree, while
national and state governments in India took steps to support
solar PV (and wind power) operations and new investment,
including granting must-run status to insulate generators from
declining electricity demand.205 (p See Policy Landscape chapter.)
Agricultural PV
is rapidly emerging as
an option for addressing
concerns related to land-
use as well as for mitigating
the potential impacts of
climate change on crops
and livestock.
127
i Energy costs vary widely according to solar resource, regulatory and fiscal framework, trade policies, project size, customer type, the costs of capital, land and
labour, exchange rates and other local influences. Distributed rooftop solar PV remains more expensive than large-scale solar PV but has followed similar price
trajectories, and is competitive with (or less expensive than) retail electricity prices in many locations. In addition, price is not equal to cost and is influenced
by several factors unrelated to the costs of production including government support policies, competing technologies, level of competition, price expectations
and end-user tastes. See endnote 225 for this section.
ii Note that bid levels do not necessarily equate with costs. Bid levels differ from market to market due to varying auction designs, policies and risks, among other factors.
iii Under the auction’s rules, Portugal’s winning projects in the Fixed Premium for Flexibility remuneration modality are required to build energy storage capacity
accounting for at least 20% of tendered solar capacity to address variability, provide flexibility and other grid regulation services, and to compensate the net-
work for peaking power prices in the spot market for 15 years. See endnote 228 for this section.
RENEWABLES 2021 GLOBAL STATUS REPORT
Disrupted supply chains and other pandemic-related challenges
also elevated calls in many countries and regions for the creation
of local supply chains to reduce heavy reliance on a limited
number of manufacturers in a single region (Asia, and mostly
China).206 Governments acted through both trade policy and the
direct promotion of manufacturing in an attempt to regain some
control over the supply and price of solar products.
In the United States, tariffs on solar-related imports from China
and several other countries continued throughout 2020.207 In
November, the on-off exemption for bifacial cells and modules
was again revoked, and new duties were imposed on silicon metal
imports from Bosnia, Herzegovina, Iceland and Kazakhstan.208
India extended the safeguard duty on imported solar cells and
modules for another year and, in December 2020, imposed a
countervailing duty on solar glass imported from Malaysia.209 The
country also promoted increased self-reliance through the “Make
in India” initiative, and launched tenders and incentives linked
to the development of domestic cell and module manufacturing
capacity.210
In 2020, the European Commission began working with industry
to promote and support solar research and development, as
well as investment in manufacturing of solar technology along
the whole value chain.211 The governments of Turkey as well as
several countries in the Middle East also were encouraging the
development of domestic industries.212 In Egypt, for example, a
project was launched to develop a sand-to-cell complex to boost
local manufacturing.213 Several additional countries had measures
in place to encourage domestic production or to penalise the use
of foreign-made products.214
At the start of 2020, China announced that it would extend duties
on polysilicon from the United States and the Republic of Korea
for five more years to build a self-sufficient domestic industry.215
China accounted for about 80% of global polysilicon production as
of 2020, up from 26% in 2010.216
More than 45% of the world’s polysilicon is produced at
facilities in China’s Xinjiang province, with producers drawn to
the region by low costs of labour and energy (mostly coal-fired
generation).217 In late 2020, concerns arose among investors and
others across the industry regarding allegations of the use of
forced labour for polysilicon production in Xinjiang.218 Although
the Chinese government and China’s solar industry trade group
have denied these claims, solar industry groups in the United
States and Europe have called for increased transparency and
the upholding of human rights throughout the global supply
chain, and concerns have been raised in Australia and Japan
as well.219
In response to these concerns, the top trade group for the US
solar industry began publicly encouraging companies to move
their supply chains out of Xinjiang and, in late 2020, announced
that it was developing a supply chain traceability protocol.220 The
leading industry group in Europe called for strengthening the
EU solar industrial base to help diversify and improve Europe’s
position in the solar supply chain.221 The situation has further
highlighted the high dependence of the industry on a relatively
small number of manufacturers, located in a single region.222
Globally, average module prices fell 8% between late 2019
and the end of 2020, from an average USD 0.36 per watt-peak
(Wp) to USD 0.33 per Wp.223 This was despite shortage-induced
price increases for both polysilicon and glass, which module
manufacturers could not pass along to consumers.224 By one
estimate, the global benchmark LCOEi of utility-scale solar PV
declined 4% from the second half of 2019 until early 2020, to
USD 50 per MWh.225
In 2020, tenders and auctions again saw bid pricesii drop
to new lows.226 The lowest bid prices were seen in Portugal,
Abu Dhabi (UAE) (USD 13.5 per MWh) and Qatar (just under
USD 15.7 per MWh), for the country’s first utility-scale project.227
Portugal’s second solar auction, for a total 700 MW under three
separate remuneration categories (including a new category for
solar-plus-storage), saw a winning bid at USD 13.2 per MWh for
a 10 MW solar PV system plus storageiii.228
128
i Four additional solar PV-plus-storage plants in New Mexico, due for commissioning in mid-2022, will replace a large coal-fired generator in the US state.
The utility will pay in the range of USD 18-25 per MWh. See endnote 238 for this section.
ii Cell capacity is MW or GW of semiconductor (cell) capacity available to a manufacturer; module assembly capacity is that available to assemble cells into modules.
iii Commercial capacity is not the same as nameplate capacity of the equipment, which is the stated capacity under ideal conditions. P. Mints, SPV March
Research, The Solar Flare, 26 February 2021, p. 7.
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India set its own low bid record (USD 26.9 per MWh) in a Gujarat
auction, following a continuous decline in bid prices across the
country throughout the year.229 Average tariffs awarded during
2020 were below those in 2019 and among the lowest in the
world, driven by a mix of government support policies, bidder
assumptions about future equipment prices, and the participation
of international developers with access to low-cost financing.230
Falling bids in tenders and auctions have prompted efforts to
renegotiate prices under existing PPAs, an additional challenge to
the industry. In India, attempts to renegotiate prices in several states
have left institutions and investors reluctant to finance projects
under government PPAs.231 In South Africa, the state-owned utility
Eskom announced plans to renegotiate PPAs with renewable
independent power producers from the first two bid rounds of the
national procurement programme.232 Similar renegotiation efforts
were under way in Saudi Arabia during 2020.233
Outside of locations with a low cost of finance and excellent
solar resources, such as Abu Dhabi or Qatar, a broad range of
experts believe that very low bids, such as Portugal’s winning
price, often are driven by extreme competition and the desire
to access grid connections and markets.234 In such instances,
low bids are thought to be possible only because firms make
overly optimistic assumptions about future cost reductions
(ahead of project construction) or plan for merchant sales at
the end of the contract period, betting on the merchant price
(until the end of project lifetime) to supplement revenues.235 In
2020, manufacturers and developers across much of the solar
PV industry experienced low margins.236
Direct bilateral PPA prices saw mixed developments during
the year. In North America, average PPA prices rose throughout
2020, after falling continuously since early 2018, due to grid
connection delays, permitting challenges, the step-down of
the federal investment tax credit as of January 2020, as well as
pandemic-related challenges.237 An exception was seen in New
Mexico, with record-low prices for a solar PV plant (USD 15 per
MWh) and a solar-plus-storage facility (USD 21 per MWh), which
together will replace a natural gas steam planti due to be retired
in 2022.238 In Europe, PPA prices declined slightly, at least in the
fourth quarter, with the lowest price reported in Spain (EUR 35, or
USD 43, per MWh).239 Prices also were low in Germany, Denmark
and Sweden, due at least in part to high levels of renewable
energy penetration, which depressed electricity market prices.240
Global shipments of cells and modules were down in the first
half of the year, but for all of 2020 they increased 7% relative to
2019.241 Of the estimated 131.7 GW of cell/module volume shipped
in 2020, around 86% was shipped by Chinese firms (including
their facilities in Southeast Asia).242 The top 10 companies
accounted for 71% of shipments, and all were Chinese based
with the exception of US-based First Solar (with 4%).243 First
Solar continued to dominate global thin film shipments, which
accounted for 5% of the year’s total cell/module shipments.244
Despite the challenges in 2020, many companies achieved major
increases in production capacity during the year. Most of the
expansions occurred in China, but there was activity elsewhere
as well.245 For example, Mexican solar module manufacturer
Solarever opened the first module assembly line (500 MW per
year) of three at its third facility in Mexico, and Turkey’s Kalyon
facility (500 MW per year) came online, with processes for
manufacturing ingots, wafers, cells and modules.246
By the end of 2020, global crystalline and thin film commercial
cell production and module assembly capacitiesii were estimated
to be 203.7 GW (cell) and 248.6 GW (module), up 33% and 34%
respectively over 2019.247 An estimated 66% of commercialiii cell
production capacity and 60% of module assembly capacity was
located in China; the United States and Europe each were home
to around 1% of cell capacity and 2% of module capacity, and
most of the rest was elsewhere in Asia (particularly Malaysia and
Vietnam) with much of that owned by Chinese firms.248
Manufacturers
and developers
across much of the solar
PV industry experienced
low margins in 2020.
129
i HJT combines advantages of conventional crystalline silicon solar cells with good absorption and other benefits of amorphous silicon thin film technology.
RENEWABLES 2021 GLOBAL STATUS REPORT
Throughout the year, manufacturers announced plans to further
increase production capacity in 2021 and beyond.249 Most planned
expansion was by Chinese producers of polysilicon, wafers, cells
and modules.250 Tongwei Solar, for example, revealed plans to
expand polysilicon production and to raise its cell production
capacity from 20 GW to 30 GW in 2021, with a goal of expanding
to 60 GW by 2022.251
Elsewhere, several European manufacturers looking to regain
market share opened or announced plans for new facilities
in Europe.252 For example, Ecosolifer AG (Hungary) started
commercial production of heterojunctioni (HJT) cells at a 100 MW
factory, the Hevel Group (Russian Federation) launched HJT
cell production, and Meyer-Burger Technology (Switzerland)
announced that it would shift from merely selling its production
equipment to using its technology to manufacture HJT cells and
modules, with plans to scale up to 5 GW module production
capacity in Germany by 2026.253 In Africa, Mondragon Assembly
(Spain) provided assembly lines for new module production
facilities in Algeria and Egypt.254
The year also saw consolidation among manufacturers and
installers, driven by pandemic-related challenges as well as longer-
term concerns. In China, the pandemic resulted in the closure of
several relatively small solar manufacturers, relieving the central
government of its plans to eliminate them.255 The largest solar
PV manufacturer to fall in 2020, Yingli (China), was the world’s
biggest panel maker as recently as 2013.256 Aggressive borrowing
alongside a plunge in solar prices led to years of losses and rising
debt; the company entered restructuring in 2020 and was brought
under government control and renamed “New Yingli”.257
In addition, Panasonic (Japan) and Tesla (US) ended their
partnership and, in early 2021, Panasonic, which entered the
solar sector in 2008, announced plans to cease all production
of cells and modules by 2022, due to the pandemic and highly
competitive pricing.258 A subsidiary of Inventec (Chinese Taipei)
announced that it would end cell production in 2021, due to margin
constraints.259 SunPower (US), another long-lived manufacturer
of cells and modules, spun off its panel manufacturing and sales
to Maxeon (Singapore) and, in early 2021, announced plans to
close its remaining US panel manufacturing facility to focus on
solar and battery sales and services.260 First Solar (US) sold its
operation and maintenance business in North America due to
falling margins to focus on module manufacturing.261
Also in 2020, the leading US residential solar, battery storage and
energy services company, Sunrun, acquired Vivent (US), a leading
competitor, representing the largest rooftop solar consolidation
yet.262 In August, solar manufacturer Hanwha Q Cells (Republic
of Korea) acquired energy storage solutions company Growing
Energy Labs, Inc. (GELI, US) to expand into the US solar-plus-
storage market.263
As in the wind power industry, new actors including fossil
fuel companies continued to enter the solar sector.264 Several
European oil and gas companies are acquiring existing solar PV
projects as investments or are constructing and operating new
projects.265 In 2020, BP announced a partnership with Chinese
module manufacturer JinkoSolar to provide clean energy for
commercial and industrial customers in China, and Spanish gas
grid operator Enagás signed an agreement with Anpere Energy
(Spain) to jointly produce hydrogen with solar PV, with plans to
inject hydrogen into Spain’s gas network.266
Other fossil fuel companies are engaging in research and
development (R&D) or moving into production. US oil and gas
company Hunt Consolidated announced that its R&D work with
perovskite cells had achieved efficiency performance levels of
18%; as of late 2020, the company owned the largest portfolio
of perovskite solar patents in the United States and one of the
largest in the world.267 In India, state-owned Coal India (the
world’s largest coal producer) received approval in December
to set up an integrated solar wafer manufacturing facility.268
130
i Crystalline technologies account for nearly all cell production. Historically, monocrystalline cells have been more expensive but also more efficient
(more power per unit of area) than multi- or poly-crystalline cells, which are made of multi-faceted or multiple crystals. See endnote 271 for this section.
ii PERC is a technique that reflects solar rays to the rear of the solar cell (rather than being absorbed into the module), thereby ensuring increased efficiency
as well as improved performance in low-light environments.
iii Tunnel-oxide passivated contact (TOPCon) cells adapt a sophisticated passivation scheme to advance cell architectures for higher efficiencies.
See endnote 280 for this section.
iv Perovskite solar cells include perovskite (crystal) structured compounds that are simple to manufacture, can be made at low temperatures, and are
expected to be relatively inexpensive to produce. Perovskites can be printed onto substrates of other materials or made as thin sheets. They have achieved
considerable efficiency improvements in laboratories. See endnote 282 for this section.
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Competition and price pressures have encouraged investment
in solar PV technologies across the entire value chain,
particularly in solar cells and modules, to further improve
efficiencies and reduce the LCOE.269 As in previous years, several
new record cell and module efficiencies were achieved during
2020.270 Monocrystallinei cell technology – which lost its lead to
multicrystalline in 2002 and retook it in 2019 – continued to gain
market share (up 26 percentage points to 88% of shipments),
and it accounted for all expansions of silicon ingot crystallisation
capacity in 2020.271 As the cost differential between technologies
has fallen, a higher priority has been placed on the higher
efficiency potential of monocrystalline technology.272
Economics also have played a role in driving ever larger wafers
and modules.273 Manufacturers started enlarging wafers (used to
make solar cells) around 2017 to optimise costs, and because it
was the easiest way to increase the power of modules.274 By 2020,
most of the sector was increasing sizes again and, by year’s end,
most major module manufacturers were preparing to produce
panels based on larger wafers.275 The rapid shift has left many
smaller companies behind and has raised manufacturing costs
throughout the supply chain.276 As a result, by early 2021 Trina
and several other large module manufacturers were working to
standardise wafer sizing.277
Demand for higher-efficiency modules helped to steer a shift
towards passivated emitter rear cell (PERC)ii technology, which
accounted for the majority of cell shipments in 2020.278 Yet, while
monocrystalline PERC has been the focus of most manufacturing
capacity expansions in recent years, the industry is already
looking beyond PERC, with the first large manufacturers
starting to produce new cell technologies that promise even
higher efficiencies and output and offer the potential to improve
margins.279 Passivated contact cellsiii (TOPCon) might be the next
evolutionary step, requiring the upgrading of PERC production
lines, while HJT cell technology (which requires completely
new production lines) also offers higher efficiencies and can be
manufactured at low temperatures and with fewer production
steps than other high-efficiency cell technologies.280
Researchers also continued working to circumvent the theoretical
efficiency limits of silicon-based solar cells by stacking cells of
different types and developing more efficient cell technologies.281
Perovskitesiv, in tandem with crystalline silicon or a thin film base,
continued to attract substantial research funding in an effort
to move closer to commercialisation.282 Oxford PV (UK) set a
new record for perovskite-silicon tandem cell efficiency (29.5%)
and started ramping up production at its facility in Germany.283
Saule Technologies (Poland) began printing perovskite cells
with inkjet printers, with plans to supply a Swedish construction
company (Skanska Group) in 2021 for use on building façades.284
Researchers continued to focus on a number of challenges,
including addressing the long-term stability issues and lead
content of perovskites, developing new cell designs and
encapsulation strategies, and bringing down costs.285
Improvements in cell technology and module design have
enabled the development of modules with higher power
ratings.286 Manufacturers were pushing 400 W in 2019, and
several introduced modules with ratings of 500 W and higher
during 2020.287 Raising the power rating increases electricity
output per module, thereby reducing the number needed for a
project, reducing space requirements and associated shipping,
land, installation and other costs.288
Interest continued to increase in bifacial modules, which
capture light on both sides, and offer potential gains in output
and thus a lower LCOE.289 Power gains range from 5% to as
much as 30% depending on cell technology, system design
and location.290 Uncertainties about the performance of bifacial
systems are falling away as the increasing number of systems
in operation demonstrates the benefits.291 However, a growing
demand for bifacial modules, which generally are made with
two glass panes (unlike most traditional modules), contributed
to a shortage in solar glass supply, helping to push up prices in
the second half of 2019.292
The industry is rapidly
shifting to
new cell
technologies
to increase cell efficiencies
and output and to improve
margins.
131
i In the United States, for example, utility-scale projects generally pay for themselves in about seven years; repowering the project resets the clock on
the federal investment tax credit. See endnote 297 for this section.
ii France’s tenders for large-scale solar PV plants prioritise projects using modules with low carbon footprints.
RENEWABLES 2021 GLOBAL STATUS REPORT
The scale of manufacturing and demand is such that solar PV
has become the major driver of growth in polysilicon production
and accounts for a large and growing share of global demand for
glass and other materials and resources.293 As with other energy
technologies and electronics, solar panels are resource intensive,
relying heavily on aluminium, copper and silver, and on smaller
amounts of minerals such as zinc, indium and lead.294 Between
2010 and 2020, solar PV use of silver more than doubled, with the
industry’s share of global demand rising from 5.7% to more than
11%, even as silver use per cell declined 80%.295
Once produced, solar panels have technical lifetimes of 25-30
years or longer.296 Nonetheless many solar plants are already
being repoweredi, and the volume of decommissioned panels
in the coming decade is expected to be large.297 Repowering is
due mainly to ageing components, particularly inverters, but the
opportunity to increase output per installation (made possible by
rapid technology advances and falling prices) is leading many
developers to replace panels much earlier.298
There is a growing market for second-hand panels (which might
or might not be recycled later), but most decommissioned,
damaged or faulty solar panels go to existing waste treatment or
recycling facilities that do not yet recover many of the materials
that represent some of their potential value (e.g., silver, copper
and silicon) and environmental impact (e.g., lead).299 Nearly
95% of a solar panel is recyclable but, for now, many materials
that could be reclaimed do not cover the costs of recycling.300
It is a matter of economics and volume: finding markets for the
reclaimed materials and scaling up treatment lines to drive down
per-unit costs, both of which require a relatively high volume of
solar panels that have reached the end of life.301
Mandates on producers to collect and recycle panels (such
as takeback legislation), and required financing, can create
the guaranteed supply of panel waste that is needed to make
recycling economical.302 As of 2020, only the EU and the US states
of New York and Washington mandated solar panel recycling.303
Japan required facilities of 10 kW or larger (installed under the
FIT system) to pay into a decommissioning fund for 10 years
after 2022; some Australian states had bans on electronic waste
in landfills (and South Africa has a similar ban, due to take
effect in August 2021); and other countries were considering or
in the process of developing requirements.304
As of early 2021, only Europe had a single treatment line (in
France) that is dedicated to recycling of crystalline silicon
panels.305 Other facilities in Europe (e.g., in Belgium, Germany,
Italy and Spain) have integrated the treatment of silicon-based
solar panels into existing treatment lines (for laminated flat
glass products, for example).306 A handful of facilities operate
in other countries: Japan has at least two facilities; India has a
pilot recycling plant; and, in the United States, a small number
of industry-driven facilities can handle parts of panels, and
thin film manufacturer First Solar has in-house capabilities.307
In Australia, Reclaim PV is testing a pyrolysis process and
starting to ramp up a nationwide collection network, and other
companies in Australia are working on recycling.308 In China,
leading manufacturers have begun to research options.309
On a related note, in 2020 the Republic of Korea introduced
carbon footprint rules for solar modules – new projects will be
prioritised according to their life-cycle emissions; the rules are
similar to those applied in Franceii for large-scale tenders.310
In addition, several companies from across the solar PV value
chain launched the Ultra Low-Carbon Solar Alliance in 2020,
pledging to build market awareness and to accelerate the
deployment of solar PV modules with lower embodied carbon to
reduce the carbon footprint of solar systems.311
132
i CSP is also known as solar thermal electricity (STE).
ii These hybrid plants are integrated solar combined-cycle (ISCC) facilities, hybrid plants that use both solar energy and natural gas to produce electricity.
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CSP MARKETS
Global CSPi capacity grew just 1.6% in 2020 to 6.2 GW,
with a single 100 MW parabolic trough project coming
online in China.1 This was down from the 600 MW commissioned
in 2019 and was, along with 2017, the lowest annual market
growth in over a decade.2 (p See Figure 29 and Reference Table
R16 in GSR 2021 Data Pack.) Reduced market growth comes on
the back of several challenges faced by the CSP sector in recent
years, including increasing cost competition from solar PV, the
expiry of CSP incentive programmes and a range of operational
issues at existing facilities.3 Market growth also was impacted
by construction delays and stoppages in China, India and Chile.4
More than 1 GW of CSP projects was under construction during
2020 in the United Arab Emirates, China, Chile and India,
although no new projects commenced construction during the
year.5 This was the seventh consecutive year in which no new
CSP capacity came online in Spain, still the market leader in
cumulative operating CSP capacity. The United States, which
ranks second in cumulative capacity, has seen no new capacity
additions in five years.6
The majority of projects under construction during 2020 were
based on parabolic trough technology.7 At year’s end, the plants
under construction worldwide included just over 1 GW of trough
systems, just under 0.3 GW of tower systems and a 14 MW
Fresnel system.8 With the exception of two hybrid CSP-natural
gas plants,ii all of these plants are to include thermal energy
storage (TES).9
CSP markets grew slowly in 2020 as
a result of increasing cost competition
from solar PV, the expiry of CSP incentive
programmes and operational issues at
existing facilities. Spain and the United
States, the market leaders in cumulative
installed CSP capacity, have not added
new capacity in seven and five years,
respectively.
More than 1 GW of new capacity was
under construction in 2020 in the United
Arab Emirates, China, Chile and India,
although construction did not begin on any
new projects. China was the only country
to add new capacity during the year.
CSP costs fell 50% during the 2010s,
and there are several examples of CSP
facilities with thermal energy storage
co-located with solar PV to lower costs
and increase capacity factors.
K E Y FA C T S
CONCENTRATING SOL AR THERMAL
POWER (CSP)
133
i The total TES capacity in MWh is derived from the sum of the individual storage capacities of each CSP facility with TES operational at the end of 2019. Individual
TES capacities are calculated by multiplying the reported hours of storage for each facility by their corresponding rated (or net) power capacity in MW.
Gigawatts
0
1
2
3
4
5
7
6
2016201520142013201220112010 2017 2018 2019 2020
Rest of World
Spain
United States
China
was the only
country to add
new CSP
capacity in
2020.
5.55.5
4.84.8
4.74.74.64.6
4.34.3
3.43.4
2.52.5
1.71.7
1.21.2
6.16.1 6.26.2
RENEWABLES 2021 GLOBAL STATUS REPORT
Source: See endnote 2 for this section.
FIGURE 29.
Concentrating Solar Thermal Power Global Capacity, by Country and Region, 2010-2020
In China, the 100 MW CSNP Royal Tech Urat project commenced
operations in January 2020, bringing the country’s total installed
capacity to 520 MW.10 The project, based on parabolic trough
technology, incorporates 10 hours or around 1,000 MWhi of
thermal storage based on molten salts, and is the largest of the
country’s 10 operational CSP facilities.11 A number of CSP plants
were under construction in China during 2020, although several
were delayed or taken over by new owners and contractors due
to a range of implementation challenges.12
In the United Arab Emirates, construction continued on the
Mohammed bin Rashid Al Maktoum Solar Park, consisting of a
600 MW parabolic trough facility (11 hours; 6,600 MWh), and a
100 MW tower facility (15 hours; 1,500 MWh).13 A key milestone
was achieved with the commissioning of the 262-metre solar
tower, the highest in the world.14 Once operational, the facility will
bring cumulative CSP capacity in the United Arab Emirates to
800 MW.15 Elsewhere in the Middle East, construction continued
on the 50 MW Duba 1 Integrated Solar Combined Cycle project
in Saudi Arabia.16
Several CSP facilities totalling around 300 MW were being built
in India in recent years, although some projects faced protracted
delays, and anticipated completion dates remained unclear.17 The
country operated 225 MW of CSP capacity as of end-2020.18
Chile was the only other country with CSP capacity under
construction during the year, in the form of the 110 MW Cerro
Dominador tower project (17.5 hours; 1,925 MWh).19 The plant,
which will be the first commercial CSP facility in Latin America
The world's largest
CSP project,
at 700 MW, was under
construction in the United
Arab Emirates.
134
i More than 95% of global TES capacity in operation on CSP plants is based on molten salt technology. The remainder use steam-based storage.
Gigawatt-hours
0
5
10
15
20
4.54.5
2.0
+1.2
11.2
20.1
21.1
+0.7
+0.7
11.711.7
16.616.6
+0.5
+2.6
6. 56. 5
+2.0
9.89.8
+3.3
9.89.8
10.510.5
+4.9
+3.4
+1.0
2016201520142013201220112010 2017 20192018 2020
21.1
Gigawatt-
hours
World Total
Annual additions
Previous year‘s
capacity
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and is expected to be operational in 2021, achieved several
construction milestones in 2020 including installation of the
220-metre solar tower and the commencement of salt melting.20
While no CSP capacity was added on the African continent, the
800 MW Midelt CSP project in Morocco was approaching the
construction phase, and the tendering process for Zambia’s first
CSP project, a 200 MW parabolic trough facility, was completed
and contractors were subsequently appointed to carry out the
project’s civil construction works.21 In neighbouring Botswana, a
new integrated resource plan released in 2020 targets 200 MW
of CSP capacity by 2026.22
For cumulative capacity in operation, Spain remained the global
leader with 2.3 GW at the end of 2020.23 With no new capacity
additions in seven years, Spain’s share of global CSP capacity
in operation declined from a high of nearly 80% in 2012 to just
under 40% by the end of 2020.24 However, production from the
existing CSP fleet has increased in recent years as a result of
operational improvements, and a draft energy and climate plan
released by the Spanish government during 2020 targets the
procurement of 600 MW of new CSP capacity by 2025.25 There
were also plans to enhance the performance of several Spanish
CSP plants by retrofitting them with energy storage.26 Following
Spain in cumulative CSP capacity was the United States with just
over 1.6 GW of commercially operational CSP, or just under 30%
of global capacity.27
At the end of 2020, an estimated 21 GWh of thermal energy
storage, based almost entirely on molten saltsi, was operating
in conjunction with CSP plants across five continents.28 (p See
Figure 30.) Of the 24 CSP plants completed globally since the
end of 2014, only two do not incorporate TES: an integrated
solar combined-cycle (ISCC) facility in Saudi Arabia and the
Megalim plant in Israel.29 TES capacity, installed mainly alongside
CSP, represents a significant proportion of global non-pumped
hydropower energy storage capacity: while global installed
solar PV capacity is more than 100 times greater than CSP, the
quantity of TES installed at CSP facilities around the world is
almost double that of utility-scale batteries.30
Source: See endnote 28 for this section.
FIGURE 30.
Thermal Energy Storage Global Capacity and Annual Additions, 2010-2020
135
RENEWABLES 2021 GLOBAL STATUS REPORT
CSP INDUSTRY
After several years of diversification of the CSP industry beyond
Spain and the United States to markets across Africa, the Middle
East and Asia, the majority of construction activity in the sector
was concentrated in the United Arab Emirates and China. CSP
projects that either entered operations or were under construction
during 2020 involved lead developers and investors from Saudi
Arabia, China, India and the United States.31 Contractors were
based in China, Spain, the United States and India, with Chinese
companies involved in almost half of the completed or active
projects.32 By contrast, before 2015 most CSP companies hailed
from the United States and Spain.33
The Saudi company ACWA Power remained the leading CSP
project developer in 2020, with more than 700 MW of projects
under construction.34 Other notable developers, investors or
owners of CSP plants that either entered operations or were under
construction during the year included Royal Tech (China), EIG
Global Partners (United States) and at least six other developers
from around the world.35 Some of the leading companies involved
in the engineering, procurement and construction of CSP facilities
included Abengoa (Spain), Acciona (Spain), Brightsource (US),
China Shipbuilding New Power Company (China) and Shanghai
Electric (China).36
During the decade prior to 2020, CSP costs decreased 68%,
the largest decline for all renewable energy technologies with
the exception of solar PV, which experienced a more than 80%
cost decline over the same period.37 CSP costs have improved
as a result of multiple factors, including technological innovation,
improved supply chain competitiveness, as well as increased
growth in CSP capacity in high irradiance regions which, along
with increased TES capacity, has boosted the overall capacity
factor of the global CSP fleet.38
In many cases CSP and TES capacity are co-located with
solar PV capacity to lower costs and increase capacity values.
For example, the Cerro
Dominador plant in Chile
is being built alongside
an existing 100 MW
solar PV plant.39 Other
developments aim to
integrate CSP, TES and
solar PV more closely:
in Morocco, the Midelt
plant will be the first to
incorporate an electric
heater to allow for
storage of energy from the adjacent solar PV facility using the
molten salt storage system.40 The hybridisation of CSP with
solar PV reflects a shift away from direct competition between
CSP and other generation resources to a more integrated and
complementary approach that emphasises the unique benefits
of CSP systems that include TES, such as long-duration energy
storage.41
In some cases, older CSP plants without energy storage are
being retrofitted with TES to greatly improve their overall
functionality and economics. Some estimates indicate that
the costs of implementing new TES at existing CSP plants are
much lower than the costs of implementing equivalent battery
capacity with existing solar PV.42
Several research and development activities focused on CSP
and TES were under way in 2020. Areas of development
included the integration of CSP and TES with other generation
and storage technologies, the improved reliability of mechanical
systems, the use of alternative heat transfer mediums and the
application of more efficient power conversion cycles.43 The US
Department of Energy announced USD 39 million in funding to
support a pilot CSP project that aims to demonstrate improved
efficiencies through the application of a supercritical carbon
dioxide power cycle.44
Several
CSP plants
are being located
alongside solar PV
facilities to lower overall
costs and boost capacity
factors.
136
i Added capacity or new additions in this section are gross additions, whereas total capacity counts only net additions (replacement of decommissioned
systems is not included).
ii Annual additions for China in 2019 were revised (see endnote 1 for this section), and the assumptions for estimating new solar thermal capacity additions
beyond the largest 20 markets were adapted for 2019 and 2020 (see endnote 5 for this section), which also had an impact on estimates for total global capacity.
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The global solar thermal market continued a gradual
decline in 2020, with an estimated 25.2 GWth of
capacity addedi worldwide, down 3.6% from 26.1 GWth
in 2019.1 Most large solar thermal markets were constrained by
challenges associated with COVID-19, such as pandemic-related
restrictions and postponed investment decisions by commercial
clients, including industries and hotels. However, the reduction
was smaller than expected due to various stabilising factors.
In most of the largest solar thermal markets, continuous business
in the construction sector during the pandemic helped maintain
a steady demand for systems. In many countries, the effects of
trade and travel restrictions on the solar thermal market were
offset at least partly by higher demand from residential owners
who spent more time at home and invested in infrastructure
improvements.2 In markets that depend strongly on subsidies,
changes in policy support in 2020 had a much greater influence
(positive or negative) on solar thermal demand than did the
pandemic.3
By the end of 2020, millions of residential, commercial and
industrial clients in at least 134 countries were benefiting
from solar heating and cooling systems.4 The total operating
capacity for glazed (flat plate and vacuum tube) and unglazed
collectors (used mainly for heating swimming pools) reached an
estimated 501 GWth by year’s end, up 5% from 478 GWth in 2019ii.5
(p See Figure 31.) These collector types provided around
407 terawatt-hours (1,465 petajoules) of heat annually, equivalent
to the energy content of 239 million barrels of oil.6
An estimated 25.2 GWth of new solar thermal
capacity came online in 2020, with China,
Turkey, India, Brazil and the United States
leading in new installations.
Residential, commercial and industrial clients
in at least 134 countries operated 501 GWth,
enough to provide heat equivalent to the
energy content of 239 million barrels of oil.
China and Germany took the lead from
Denmark in solar district heating, thanks
to policy support in both countries.
A new generation of manufacturers of
innovative concentrating collectors
unveiled the first demonstration or
commercial projects.
K E Y FA C T S
SOL AR THERMAL HEATING
137
i Chinese statistics differ between standardised small residential solar water heaters and “engineered” solar thermal solutions, which are called the “large
project market” in the GSR and refer to larger systems used in, for example, industry, agriculture, public institutions and residential housing projects.
Gigawatts-thermal
Glazed
collectors
Unglazed
collectors
0
100
200
300
400
500
20192010 2011 2012 2013 2014 2015 2016 2017 2018 2020
242242
285285
330330
374374
409409
435435
456456
472472 482482 478478
501501 501
Gigawatts-
thermal
World
Total
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: Data are for glazed and unglazed solar water collectors and do not include concentrating, air or hybrid collectors. The drop in 2019 was caused by
revised annual additions for China in 2019 (see endnote 1 for this section) and new assumptions for projecting total capacity in operation for 2019 and 2020
(see endnote 5 for this section).
Source: IEA SHC. See endnote 5 for this section.
FIGURE 31.
Solar Water Heating Collectors Global Capacity, 2010-2020
In addition to the three main types of collectors, other technologies
such as hybrid, concentrating and air collectors are available to
meet specific heat needs. Because annual additions of these
technologies are small, they are not yet included in global and
national capacity statistics. By the end of 2020, hybrid – or solar
photovoltaic-thermal (PV-T) – technologies provided 635 MWth
of thermal capacity (and 232 MW of electric power capacity) for
space and water heating.7 In addition, 566 MWth of concentrating
solar thermal capacity provided hot water or steam for industrial
and commercial customers at year’s end.8 Around 1 GWth of air
collectors for drying and space heating was in operation in 2019
(latest data available).9
The leading countries for new glazed and unglazed installations
in 2020 were again China, Turkey, India, Brazil, the United States,
Germany and Australia.10 (p See Figure 32.) China dominated
the market, accounting for 71% of new global sales, followed by
Turkey and India (5% each).11 Most of the top 20 countries for
solar thermal installations (glazed and unglazed collectors) in
2019 remained on the list in 2020; the exceptions were Denmark,
the State of Palestine and Switzerland, which were replaced in
the rankings by the Netherlands, Morocco and Portugal.12 The
top 20 countries accounted for an estimated 96% of the global
market in 2020.13
In China, the solar thermal
market ended 2020 on
a high note, with sales
in the second half of the
year nearly making up for
the delays in construction
activity related to COVID-
19 during the first six
months.14 Installations
in 2020 totalled 18 GWth
(25.7 million square metres
(m2) of collector area),
resulting in a decline of only 3% from 2019 (compared with a 21%
drop in 2019 relative to 2018).15 At year’s end, China's operating
capacity was 364 GWth, or 67% of the global capacity in operation.16
The large project market in Chinai – covering a wide range of
customer groups including industry, large-scale residential
projects, agriculture, and public institutions such as hospitals and
schools – remained stable and contributed to nearly three-quarters
(74%) of total sales in 2020, while the market for small retail solar
water heaters made up the remaining 26%.17 Within the large
project market, the most dynamic growth was in the solar space
heating segment, totalling 1.7 GWth of newly added capacity, or
10% of all new installations.18 Prior to 2020, a total of only around
0.6 GWth of solar space heating projects was put online. 19
Germany’s
green heating
policy
helped drive a 26%
increase in sales in 2020.
138
Gigawatts-thermal
0
5
10
15
20
Tu
nis
ia
Po
rtu
ga
l
M
or
oc
co
Cy
pr
us
Au
str
ia
Ne
th
er
lan
ds
Ita
ly
So
ut
h A
fri
ca
Po
lan
d
Sp
ain
Gr
ee
ce
Isr
ae
l
M
ex
ico
Au
str
ali
a
Ge
rm
an
y
Un
ite
d
St
at
es
Br
az
il
In
dia
Tu
rk
ey
Ch
ina
Unglazed
collectors
Glazed – evacuated
tube collectors
Glazed – flat plate
collectors
1.5
-3%
+2%
-10%
+7%
-16%
+26%
-2% -8%
-3%
-16%
-10%
-44%
0
-19%
+7%
-17%
+7%
-6%
+1%
-19%
0.3
0.6
0.9
1.2
1.5
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Although vacuum tube collectors still accounted for 73% of
China’s newly installed capacity, the market continued to
transition from vacuum tubes to flat plate systems.20 China’s
market for new vacuum tube collectors contracted 6% in 2020
(to 13.1 GWth), while new flat plate collector area grew 6% (to
4.9 GWth).21 Sales of flat plate collectors have been driven by
building codes mandating the use of solar thermal systems (or
heat pumps) in new construction and major renovations as a
means to reduce local air pollution.22 These regulations have
increased the demand for both façade- and balcony-integrated
applications, where flat plate collectors have been the preferred
solution.23
Turkey’s solar thermal market, the second largest for new
sales worldwide, expanded slightly (up 2%) in 2020, following
stagnating sales the previous year, resulting in 1.35 GWth of newly
installed capacity.24 The 18.4 GWth of solar thermal capacity in
operation at year’s end accounted for 4% of the global total.25
The pandemic affected Turkey’s market in two opposing ways.
In the residential sector, sales of solar water heaters increased as
Turkish residents moved away from urban areas and apartment
buildings to villages and individual houses, boosting the
renovation business and the prefabricated housing market and
triggering solar thermal sales. Meanwhile, sales of solar thermal
systems for hotels and resorts declined.26
India's demand for
glazed collectors fell
10% in 2020 to 1.16 GWth
(1.66 million m2) due
to the restrictions on
production, sales and
installation during the
country’s full lockdowns
in April and May and
partial lockdowns over
several months.27 Even
so, India again ranked
third for annual additions. As in Turkey, Indian solar thermal
manufacturers reported opposing trends: for example,
precautionary health measures, such as more frequent hot baths,
increased the demand for solar water heaters, partly offsetting
the negative impact of the pandemic.28
The market share of vacuum tube collectors in India grew to
88% of newly installed capacity in 2020 (up from 85% in 2019),
mainly because flat plate collector sales declined more strongly
(down 24%) due to higher prices resulting from rising material
costs.29 Furthermore, there was a decrease in the number of
public tenders that mandated systems certified by the Bureau of
Indian Standards, which so far can be fulfilled only by flat plate
collectors.30
Note: Additions represent gross capacity added. For the Netherlands, the shares of flat plate and vacuum tube collectors were estimated based on actual
shares in 2019. For Morocco, the share of collector types was not available.
Source: See endnote 10 for this section.
FIGURE 32 .
Solar Water Heating Collector Additions, Top 20 Countries for Capacity Added, 2020
Demand from
homeowners for
solar water
heaters
increased in Turkey,
India and Brazil during
the pandemic.
139
i The restrictions affected the glazed solar thermal market more than the unglazed market because the glazed market is aligned heavily with new home builds.
RENEWABLES 2021 GLOBAL STATUS REPORT
Karnataka state again dominated capacity additions, representing
nearly 65% of India’s total market (up from 50% in 2019), followed
by Gujarat and Maharashtra.31 The driving force in Karnataka was
again a strict policy mandating use of the systems, overseen by
local electric utilities that deny grid access to households not
equipped with a solar water heater.32
Brazil continued its growth trajectory, adding 992 MWth (up 7%)
of solar thermal capacity in 2020 despite COVID-19 worries,
following a 6% increase in 2019.33 The pandemic caused demand
to fall in the first six months of the year, as commercial clients put
plans on hold and wholesalers closed their doors.34 Sales then
rose in the second half of the year, a development attributed in
part to the recovery of the residential sector as people spent more
time at home and invested in infrastructure improvements (such
as solar pool heating and solar hot water systems); commercial
clients also took advantage of the lower interest rates available for
financing to identify energy-saving solutions that could give them
a competitive edge.35
For the first time, Brazil's unglazed collector market, aimed
mainly at swimming pool heating, pulled ahead of the US market,
the long-term leader for this type of collector.36 Brazil added
498 MWth of new unglazed capacity, followed by the United
States (473 MWth) and Australia (266 MWth).37
Brazil’s strong market in 2020 resulted almost solely from the
competitiveness of domestically manufactured solar thermal
systems compared to other water heating options, as well as
the ongoing reduction in value-added tax (VAT), enjoyed by
solar thermal products but not other water heating options.38
Meanwhile, the implementation of two previously announced
policy support programmes was temporarily postponed
because of the pandemic.39 The federal government delayed
the launch of the new social housing programme Casa Verde
e Amarela, which was to succeed Minha Casa Minha Vida, the
main programme behind the increase in Brazil’s solar thermal
capacity between 2009 and 2014.40 Law PL 107 from 2019,
stipulating the use of solar energy in all municipal and federal
government institutions in the city of São Paulo, also did not
enter into force.41
The United States, the fifth largest market for the three main
types of solar thermal collectors in 2020 (with 505 MWth),
suffered a sharp decline (down 16%).42 This resulted from
a severe drop in sales of glazed collectors (down 71%) due to
COVID-19 restrictions and to the end of a major support scheme,
the California Solar Initiative, in July 2020.43 Meanwhile, demand
in the unglazed segment fell only 3%, which led its share in newly
added capacity to increase to 94% (from 81% in 2019).44 The
United States continued to rank third globally for total operating
capacity, with 18 GWth at the end of 2020.45
Australia ranked seventh, following Germany for solar thermal
sales, adding 380 MWth of new capacity in 2020, down slightly
from 2019.46 The Australian solar thermal market has been
dominated by unglazed collectors, which have fluctuated
between 260 MWth and 280 MWth each year since 2013.47
Preliminary numbers for glazed collectors suggest a decline
in 2020 (down 7%), with new installations totalling around
114 MWth.48 Sales of glazed collectors contracted, while heat
pumps gained a larger share of the residential new-build market;
in addition, restrictions on the number of workers allowed at
worksites during several months of the pandemic affected solar
thermal salesi.49
The European Union (EU-27) remained the second largest
regional market after Asia in 2020.50 However, additions
(estimated at 1.4 GWth) were down 15% from 2019.51 The total
capacity in operation in Europe at the end of 2020 was an
estimated 37.5 GWth, accounting for 7% of the global total.52 The
four leading countries in 2019 (Germany, Greece, Poland and
Spain) saw mixed results in 2020, with strong growth in Germany
and declines in Greece, Poland and Spain, resulting largely from
changing policies and the impacts of the pandemic.53
Germany extended its leading position in Europe and reversed
its decade-long market decline, ranking sixth globally for
new installations. Annual sales were up 26% in 2020, to reach
450 MWth, or around 83,000 new solar thermal systems for the
year.54 A key driver of growth was the new national support
scheme to accelerate decarbonisation of the heat sector,
launched at the start of 2020, which covers 40% of the cost of
replacing an outdated oil heater with a new solar-supported gas
condensing boiler.55
A high volume of grant applications in the last quarter of 2020
helped fuel optimism for continued growth in 2021.56 Germany
reached 13.9 GWth in operation at the end of 2020, accounting for
3% of total global capacity.57
The solar thermal market in Greece, again the second largest for
new additions in Europe, contracted significantly (16%) in 2020
(for the first time since 2013), with only 213 MWth installed.58
140
i Fourth-generation heat networks operate at lower temperatures of around 60 degrees Celsius (°C) to reduce heat losses, extend pipe lifetimes and create the
best conditions for injecting heat produced with renewable sources.
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The drop was caused by reduced sales during lockdowns in
the first half of the year, when shops were closed and internet
sales were insufficient to offset the decline in direct sales.59
Spain came in third place in Europe in 2020, ahead of Poland
(due to a large market decline in Poland, rather than to expansion
in Spain). The Spanish solar thermal market fell 10% (adding
131 MWth), in line with the year’s housing market decline, whereas
Poland’s market plunged 44%, with 113 MWth added.60 The
contraction in Poland was attributed to the pandemic and to a
phasing out of the emission reduction programme, which aimed
to improve local air quality by subsidising renewable heating
systems purchased and distributed by municipal administrators.61
Although most solar thermal capacity continued to be installed
for the purpose of water heating in individual buildings, the use of
solar thermal technology in district heating expanded further
during 2020, and in an increasing number of countries. The vast
majority of new solar district heating capacity added was again
(in descending order) in China, Germany and Denmark.
In China, the solar district heating market shifted in 2020 from
being purely state-financed to being partly commercial, with large
orders from the housing industry. Whereas in 2019, three publicly
funded solar district heating systems were commissioned in
Tibet (totalling 52 MWth), in 2020 only one such plant (7.9 MWth)
was erected, at a college in Lhasa.62 Across China, newly installed
solar thermal capacity for space heating (for both district heating
and heating of large buildings) increased by a significant 1.7 GWth,
due to green heating policies aimed at replacing coal boilers in
the country’s north to improve air quality.63 For this new capacity,
the statistics do not differentiate between central space heating
projects for blocks of flats or larger buildings (which would be
considered solar district heating) and decentralised space
heating units for rural, single-family houses.64
Germany passed Denmark for new installations of solar district
heating by bringing online six new plants (totalling 22 MWth) in 2020,
following the completion of five new systems (totalling 7.1 MWth) in
2019.65 The 2020 additions included Germany‘s then-largest solar
district heating plant, in Ludwigsburg, with a solar capacity of
10.4 MWth.66 By year’s end, the country had 41 solar district heating
plans in operation totalling 70 MWth of capacity.67 Five additional
plants, with a combined capacity of 22.5 MWth, were being planned
or in the installation phase and were expected to come online in
2021; they included a 13.1 MWth system in Greifswald that, once
operational, will overtake the Ludwigsburg plant to become the
country ś largest solar district heating plant.68
The strong market in Germany was driven by supportive
framework conditions, including grants from two programmes:
the Municipal Climate Change Showcase Programme and
Heat Networks 4.0. The Municipal Showcase Programme has
provided grants since January 2020 to cover up to 80% of the
investment cost of municipal activity in the areas of greenhouse
gas reduction, smart infrastructure and wastewater treatment.69
Heat Networks 4.0 has provided support to utilities since
mid-2017 for feasibility studies and the construction of fourth-
generation district heat networksi, where at least half of the heat
injected into the grid must come from renewables.70 Thanks in
part to these programmes, German utilities increasingly consider
solar heat to be an economically feasible alternative, promising
stable heat prices over a period of 25 years, compared to the
volatile prices of natural gas and biomass.71
Denmark continued to lead globally for total district heating
capacity, with more than 1 GWth in operation at the end of 2020.72
However, the country brought online only one small solar district
heating plant and three extensions during the year, increasing
total capacity by 10 MWth.73 This is down sharply from 2019, when
10 new district heating plants and 5 extensions were added for a
total of 134 MWth.74 The market contraction was due to increasing
competition from heat pumps, driven by policy changes.75 As
of mid-June 2019, solar heat was no longer eligible to fulfil the
energy savings mandates for utilities, whereas heat pumps were
included in the mandate until the end of 2020.76 At the beginning
of 2020, the Danish Energy Agency also began providing grants
for heat pumps, triggering additional demand.77
The top markets for
solar industrial
heat
in 2020 were China,
Mexico and Germany.
141
Number of systems added Collector area in m2
750,000
1,125,000
375,000
1,500,000
1,825,000
3,000,000
2,250,000
2,650,000
0
20
10
40
30
60
50
70
80
Number of systems
added outside Europe
Number of systems
added within Europe
Cumulative
collector area
in operation
outside
Europe
Cumulative
collector
area in
operation
in Europe
202020192010 2011 2012 2013 2014 2015 2016 2017 2018
471
Systems
World
Total
RENEWABLES 2021 GLOBAL STATUS REPORT
Demand for new solar district heating systems increased in other
existing European markets as well. In France, the market picked
up in response to an attractive investment grant for large solar
heat systems.78 At the start of 2020, France had only a handful of
solar district heating plants, with the largest commissioned in 2018
(1.6 MWth) in Châteaubriant; by the end of 2020, three additional
systems were under construction with a combined capacity of
7.4 MWth, including a 4.2 MWth field in Narbonne that will be France's
largest solar district heating plant when it comes online in 2021.79
Austria's subsidy scheme for large and innovative solar thermal
projects again saw results in 2020, with the inauguration of three
new solar district heating fields totalling a combined 4.7 MWth.80
This represented a change from 2019, when no solar district heating
plants were commissioned in Austria.81 A much higher budget for
the subsidy scheme, starting in April 2021, is expected to drive up
demand for large-scale applications in the coming years.82
Sweden also had a new plant under construction at the end of
2020. Once completed in 2023, the 1.5 MWth solar district heating
plant in Härnösand, north of Stockholm, will be the country’s
largest solar district heating field using concentrating collectors.83
The global solar district heating market also diversified into
new markets in both Europe (Croatia, Kosovo and Serbia) and
Asia (Mongolia, driven by public funding for pre-feasibility
and feasibility studies). In Mongolia, the European Bank for
Reconstruction and Development (EBRD) funded a study
on 20 different renewable and energy efficiency options for
decarbonising the district heating grid for over 1 million people in
the capital city of Ulaanbaatar; among the options is a 49 MWth
solar district heating plant.84
With support from the EU project KeepWarm, pre-feasibility
studies for the integration of solar fields in district heating networks
with a total capacity of 37.5 MWth were carried out in the Croatian
cities of Samobor, Velika Gorica and Zaprešić.85 Solar district
heating also attracted more attention in Serbia and Kosovo during
2020 because of the continued support from the EBRD for (pre-)
feasibility studies.86 In early 2021, feasibility studies were under
way in Pančevo (Serbia) and Priština (Kosovo) for at least 70 MWth
of solar district heating plants.87 The Serbian towns of Bor and
Novi Sad had completed pre-feasibility studies, and Novi Sad's
municipal council was proceeding with the next planning step.88
In addition to solar district heating, central solar hot water
systems for large residential buildings, hospitals, sport clubs
and prisons sold well in Brazil, China and Turkey during 2020.
In total, at least 57 large solar thermal systems of at least
350 kilowatts-thermal (500 m2) each, used either for district
heating or for central hot water, were added globally in 2020.89
These capacity additions of 93 MWth brought the total number
of large collector fields to at least 471 systems (1.8 GWth) by
year’s end (including glazed and concentrating solar thermal
collectors).90 (p See Figure 33).
Note: Includes large-scale solar thermal installations for residential, commercial and public buildings. Data are for solar water collectors
and concentrating collectors.
Source: See endnote 90 for this section.
FIGURE 33.
Solar District Heating, Global Annual Additions and Total Area in Operation, 2010-2020
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The additions in 2020 appear to represent a decline from the 74
large systems reported by technology suppliers as commissioned
in 2019.91 However, one large Chinese project developer, which
was responsible for 36% of the plants completed in 2019, failed
to report any large systems for 2020 despite completing several
projects; this suggests that the world market remained more or
less stable in 2020.92
Also during the year, several international organisations published
a joint report emphasising the need to decarbonise industrial
heat demand.93 However, this urgent call for carbon-free heat
solutions did not appear to stimulate demand for the use of new
solar thermal systems to provide process heat for industry. Only
74 solar heat for industrial processes (SHIP) projects, with
a total capacity of 92 MWth, came online in 2020, down from 86
projects and 251 MWth in 2019.94 Multiple factors contributed to
the relative decline: for example, the pandemic delayed the closing
of contracts and the installation of ordered projects, and India’s
SHIP market declined in 2020 following the expiry in March of the
national support programme for solar concentrating systems.95
In the United States, Glasspoint, which was responsible for a
large share of the global SHIP capacity added in 2019 (180 MWth
of solar steam capacity commissioned in Oman), closed its doors
in May 2020.96
By year's end, at least 891 SHIP systems totalling more than
792 MWth were supplying process heat to factories worldwide.97
The top markets in 2020 were again China (30 new projects),
Mexico (16) and Germany (10), followed distantly by India and Spain
(3 each).98 China's demand for solar industrial heat was triggered
by government support policies to activate the economy after the
pandemic, which helped drive an increase in the reported number
of new projects from 26 in 2019 to 30 in 2020.99
Solar industrial heat plants in Mexico are cost competitive with
fossil fuels such as liquefied petroleum gas (LPG), fuel oil and
diesel, suggesting the potential for further market growth.100
In many other countries, however, achieving competitiveness
against oil and natural gas depends on investment support
subsidies for SHIP systems or the elimination of fossil fuel
subsidies.101 In Germany, continued funding since 2012 resulted in
the commissioning of 10 new plants (totalling 1.5 MWth) in 2020.102
Only one or two industrial solar heat systems were commissioned
each in Austria, Belgium, Cyprus, Italy, Malaysia, Morocco, the
Netherlands, Niger and Turkey.103
Although many solar technology suppliers reported delays in
installation and construction, some megawatt-size plants were
successfully commissioned in 2020. The top plants for new
capacity demonstrated the variety of collector types typically
used for SHIP plants globally. The largest new installation, at
10.5 MWth, used flat plate collectors to heat the greenhouses
of a freesia farm in the Netherlands.104 The largest plant with
vacuum tube collectors (4.6 MWth) supplies heat in China to
a factory in Sanya in Hainan province.105 The largest SHIP
plant with concentrating collectors (3.9 MWth), used for drying
agricultural products, started operation in May 2020 in Ganzhou,
Tibet (China).106 Two 3.5 MWth plants also came online – one in
Tibet with vacuum tube collectors for greenhouse heating, and
one in Turkey with parabolic trough collectors providing heat to a
packaging factory.107
Hybrid or PV-T collectors, which are solar thermal collectors
mounted beneath solar PV modules to convert solar radiation into
both electrical and thermal energy, have supplied only niche markets
in recent years; thus, their capacity is not included in global and
national capacity statistics. Since PV-T collectors have begun to gain
popularity in a number of countries in recent years, market data are
included in this report for the first time.108 In 2020, 36 manufacturers
globally reported PV-T capacity of at least 60.5 MWth (connected to
24 MW-electric), up strongly from 46.6 MWth in 2019.109
The largest markets in new PV-T additions in 2020 were, in order
of capacity added, the Netherlands, China, France, Ghana and
Germany.110 Demand among residential and commercial clients in
these countries has been driven by the ability to produce both heat
and electricity from the same roof space, therefore generating a
higher yield per area.111 In the Netherlands, China and Germany,
subsidy schemes also have played a role in triggering demand.112
143
i In December 2020, Greenonetec founder re-acquired the 51% ownership stake that was sold to Chinese Haier in May 2017.
RENEWABLES 2021 GLOBAL STATUS REPORT
SOL AR THERMAL HEATING INDUSTRY
The global solar thermal industry experienced mixed results in
2020. Most large manufacturers reduced production volumes
due to disruptions in the movement of labourers and goods
during several months of the pandemic.113 However, a small
number of producers profited from growing demand triggered
by new support policies (as in Germany) and from continuously
high national demand from the construction industry and solar
mandates in some provinces (as in China).114
China’s solar thermal industry, which saw virtually no impact from
COVID-19, continued two major trends from previous years: a
high share of large systems for domestic commercial clients, and
increasing domestic sales of flat plate collectors.115 Consequently,
Chinese companies again dominated the list of the world ś largest
manufacturers of flat plate collectors, holding the top six positions:
in the lead was SunEast Group (including the Sunrain and Micoe
brands), followed by Jinheng Solar (with its export brand BTE Solar),
Haier (the majority owner of the Austrian company Greenoneteci
until December 2020), Linuo Paradigma, Sangle and Fivestar.116
Excluding Greenonetec, which had no sales in China, the other six
Chinese flat plate collector producers increased their combined
sales volume 12% in 2020, growing faster than the domestic flat
plate collector market overall (up 6%).117 Industry consolidation in
China continued, with only large solar equipment manufacturers
implementing the rising number of solar space heating projects
and responding to central procurement offers for solar water
heating equipment for big construction projects.118 Outside China,
the combined sales volumes of the 14 largest flat plate collector
manufacturers fell 9% on average in 2020, buffered slightly by
strong sales growth in Germany.119
Global leaders in large solar heat project development also were
affected by declines in the number of contracted projects and
setbacks in project development in 2020. Arcon-Sunmark, the
market leader in solar district heating from Denmark, closed
its collector factory and stopped project development in mid-
June, after several years of high fluctuations in turnover and low
margins in contracted projects.120 The company continued to
operate a small maintenance unit to fulfil its long-term service
and warranty contracts with clients.121
Despite the demise of Arcon-Sunmark’s manufacturing
and development division, the company’s know-how and
assets remained partly available in the sector. Greenonetec
(Austria) acquired the production line for large-scale collector
panels, targeting the growing solar district heating market in
Europe.122 In addition, Viessmann (Germany) engaged a team
of Arcon-Sunmark’s planners and sales experts to strengthen
its commercial solar heat project development unit, and
Solareast Group (China) bought shares in the company’s
Asian business.123
US-based Glasspoint closed its doors as well in 2020, due in
part to uncertainty resulting from the COVID-19 pandemic. In
March, the company was forced into liquidation after existing
shareholders from the oil industry decided to halt the additional
funding that was required to keep it operational.124 Glasspoint
had been in charge of installing the world’s largest solar steam-
producing plant in Oman, which reached a capacity of 360 MWth
in early 2020.125 The company’s difficulties started in 2019, when
implementation of a 850 MWth solar steam-producing project
in the Belridge oilfields of California was delayed due to a lack
of financing; this was followed by a halt in the extension of the
Oman project because the client did not approve the third phase
at the beginning of 2020.126
Medium-sized European technology suppliers signed a number
of new contracts during 2020 using improved business models
that help to reduce the risk and the heat costs for clients investing
in large-scale solar heat systems; these included solar heat
contracts and sales of complete production lines. NewHeat
(France) secured a bank loan of EUR 13 million (USD 16 million) in
September for a pool of five large commercial solar heat systems
in France, totalling 28 MWth.127 As an energy service company,
NewHeat offers solar heat contracts to two industrial sites and
three district heating utilities.128
COVID-19 restrictions
slowed
installation work
on solar industrial heat
plants already under
contract.
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In April 2021, Kyotherm (France), which specialises in financing
renewable heat projects, commissioned, together with its
subcontractors (among others NewHeat, Savosolar of Finland
and Sunoptimo of Belgium), Europe’s largest solar industrial
heat plant, a 10 MWth project for a malting facility in France.129
Kyotherm, with its network of solar thermal project developers,
continued contractual negotiations with commercial heat
consumers in the United States and India, with the first contracts
expected to be signed in 2021.130
In early 2021, Absolicon (Sweden) signed its 13th letter of interest
thus far, with a potential buyer for its complete parabolic trough
collector production line, which has a typical annual capacity of
100,000 m2.131 The purchasers intend to invest in new production
lines and are located around the globe, including in Ecuador,
Ghana, India, Kenya, Mexico, Spain, Turkey and Uruguay.132 With
this strategy, Absolicon aims to reduce technology costs by
enabling its buyers to produce solar collectors close to a large
number of potential heat customers in sun-rich countries.133
Concentrating solar heat solutions are commonly used to
produce temperatures above 100°C, even though other collector
types, such as high-vacuum flat plate collectors, are able to reach
temperatures up to 180°C.134 Such systems use concentrating
collector technologies with smaller dimensions (length and
width) than for concentrating solar thermal power plants and
provide heat for processing as well as for steam networks in
hospitals or district heating. An increasing number of collector
manufacturers have met the challenge of providing such high-
temperature solutions. By the end of 2020, 23 solar industrial heat
suppliers based in China, Europe, Mexico and North America
were producing concentrating collectors, dominated by parabolic
trough producers (14 companies) then Linear Fresnel (7) and
concentrating dish (2) producers.135
A new generation of developers and manufacturers of innovative
concentrating collector technologies established in recent years
revealed their first demonstration or commercial projects in 2020.
These technology providers rely on a wide range of concepts
aimed at further lowering the cost of energy by reducing the
quantity of material input per unit and by improving performance.
The largest new producer, established in 2016, is WuCheng
Energy based in Inner Mongolia, China, which signed contracts
in 2021 to build a commercial 82 MWth district heating plant
with parabolic trough collectors in the northern Chinese city of
Handan, slated to start construction in summer 2021.136
Solarflux Energy Technologies (US) relies on a dish receiver
that, as of early 2021, had been shipped to China, India, Mexico,
Qatar and the United States to be used in demonstration projects
(totalling 650 m2).137 Four other start-ups – Skyven Technologies
(US), True Solar Power (Spain), Umbral Energia (Mexico) and
Heliac (Denmark) – were developing new solar collectors that
consist of a heliostat array focusing on a receiver.138 Concentrating
collector companies in the technology prototype stage included
Alto Solution (France), with a new parabolic trough unit, and
Heliovis (Austria), which is developing a concentrator housed in
an inflatable cylindrical foil-walled tunnel.139
Increasing awareness of solar thermal technologies by end-
customers in the Russian Federation fuelled optimism in 2020
for investing in solar component factories. During the year, St.
Petersburg saw the ramping up of two factories by privately
owned Russian companies: the engineering firm Silagnis started
producing heat pumps and solar collectors, and Solar Fox
increased its manufacturing volume of solar air collector units.140
A strong and committed supply chain of around 80 turnkey
SHIP suppliers offered solar heat solutions to industrial clients in
2020, despite the challenges of the pandemic.141 Four out of five
companies confirmed that the pandemic delayed the closing of
SHIP contracts in 2020, because of economic uncertainty among
potential customers.142 Three out of four suppliers also confirmed
that COVID-19 restrictions slowed installation work on plants
already under contract.143 Consequently, only 15 of the around 80
SHIP suppliers commissioned at least one project during the year,
compared to 25 companies that put up at least one plant in 2019.144
Linuo Paradigma (China) was the 2020 market leader in both new
projects and newly added SHIP capacity, reporting 22 projects
totalling 58 MWth in 2020.145 High demand in China was triggered
by government support policies to activate the economy, which
helped industrial clients invest in SHIP plants.146 Modulo Solar
(Mexico) realised the second largest number of SHIP plants,
with 13 new small systems that totalled 0.8 MWth.147 The second
largest company for SHIP capacity in 2020 was SunEast Group
(China), which reported the completion of five systems with a
total of 8 MWth.148
Project developer Kyotherm had to postpone (to 2021) the
commissioning of its 10 MWth SHIP plant at a malting factory in
central France because of travel restrictions in Europe during the
pandemic.149 Similar restrictions affected other manufacturers,
such as VSM Solar (India) and Absolicon (Sweden), which were
unable to execute confirmed orders.150 Although the number
and capacity of new SHIP plants were down in 2020, the large
number of delayed plants under contract fuels hope that the
market will increase again in 2021.151
145
Gigawatts
0
100
200
300
400
500
800
700
600
198198
238238
283283
319319
370370
433433
488488
540540
591591
650650
743743
+38
+39
+41
+45
+36
+52
+64
+55
+54
+51
+61
+93
2016201520142013201220112010 2017 2018 2019 2020
Annual additions
Previous year‘s
capacity
743
Gigawatts
World
Total
RENEWABLES 2021 GLOBAL STATUS REPORT
WIND POWER MARKETS
An estimated 93 GW of wind power capacity was
installed globally in 2020 – including more than
86.9 GW onshore, the highest yet, and nearly 6.1 GW offshore.1
This record-breaking market was 45% above the previous
high, in 2015 (63.8 GW), and represents an increase of nearly
53% relative to 2019 installations.2 For several months of 2020,
pandemic-related restrictions disrupted supply chains, rendered
much of the wind energy workforce unavailable, resulted in
postponed or cancelled auctions and delayed investments, and
forced delays or cancellations to project construction in many
countries, particularly in the onshore sector.3 But even with the
global health, economic and political challenges, by year’s end
total global wind power capacity was up 14% over 2019 and
neared 743 GW (707.4 GW onshore and the rest offshore); this
was double the capacity in operation worldwide only six years
earlier, at the end of 2014.4 (p See Figure 34.)
The rapid growth in 2020 was due to a dramatic increase in China
as well as to a jump in the United States in advance of policy
changes; the rest of the world installed about the same amount of
(net) additional capacity as it did in 2019.5 The pandemic added to
previously existing financing, infrastructure, policy and regulatory
challenges in some countries, while other countries (in addition
to China and the United States) saw record installations during
2020, including Argentina, Australia, Chile, Japan, Kazakhstan,
Norway, the Russian Federation and Sri Lanka.6 New wind farms
reached full commercial operation in at least 49 countries, down
from 55 countries in 2019, and at least one country, Tanzania,
brought online its first commercial project.7 By the end of 2020,
The world added a record 93 GW of wind
power capacity in 2020, led by China and the
United States. Both countries broke national
records for new installations, driven in part by
pending policy changes. The rest of the world
commissioned about the same amount as
in 2019, but several additional countries had
record-breaking years.
For the first time, global capital expenditures
committed to offshore wind power in 2020
surpassed investments in offshore oil and gas.
The industry continued to face perennial
challenges exacerbated by the pandemic,
but maintained momentum in technology
innovation in continuous pursuit of an ever
lower levelised cost of energy.
Wind power accounted for a substantial
share of electricity generation in several
countries in 2020, including Denmark (over
58%), Uruguay (40.4%), Ireland (38%) and the
United Kingdom (24.2%).
K E Y FA C T S
WIND POWER
Note: Totals may not add up due to rounding.
Source: GWEC. See endnote 4 for this section.
FIGURE 34.
Wind Power Global Capacity and Annual Additions, 2010-2020
146
i The difference between generation (electricity produced within a country’s borders) and consumption is due to imports and exports of electricity, as well as to
transmission and distribution losses (which vary considerably across countries).
ii The top countries by additions in 2019 were China, the United States, the United Kingdom, India, Spain, Germany, Sweden, France, Mexico and Argentina. The top
10 for cumulative capacity in the years 2018-2020 were China, the United States, Germany, India, Spain, the United Kingdom, France, Brazil, Canada and Italy.
Gigawatts
20
40
60
India
Turkey
France
Norway
Germ
any
Spain
Netherlands
Brazil
+52.0+52.0
+10.8+10.8
+16.9+16.9
+2.0+2.0
+2.3+2.3
+1.7+1.7
+1.7+1.7
+1.5+1.5
+1.3+1.3
+1.2+1.2
+1.1+1.1
0
100
50
150
200
300
250 80
80
Added in 2020
2019 total
United States
Rest of W
orld
China
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more than 100 countries had some level of commercial wind
power capacity, and 37 countries – representing every region –
had more than 1 GW in operation.8
Rapidly falling costs per kilowatt-hour (both onshore and
offshore) have made wind energy ever more competitive and
allowed onshore wind power to compete head-to-head with
fossil fuel generation in a large and growing number of markets,
often without financial support.9 The economics of wind energy
have become the primary driver for new installations.10 Outside of
China (which had a feed-in tariff, or FIT) and the United States
(with tax credits and state renewable portfolio standards, or RPS),
global demand for wind power in 2020 was driven largely by other
policy mechanisms including auctions (or tendering).11 Corporate
power purchase agreements (PPAs) are playing a growing role in
some markets, particularly in the United States and Europe but
also increasingly in Latin America and Asia. In 2020, however, the
capacity contracted globally through corporate PPAs was down
29% relative to 2019, to 6.5 GW.12
Wind power provides a substantial share of electricity in a growing
number of countries. In 2020, wind energy generated enough to
provide an estimated 15% of the annual electricity consumption in
the EU-27, and much higher shares in at least five individual Member
States.13 Wind energy met an estimated 48% of Denmark’s electricity
demand in 2020 and accounted for nearly 58.6%i of the country’s
total generation.14 Other European countries with wind generation
shares of at least 20% for the year included Ireland (38%), the United
Kingdom (24.2%), Portugal (24%), Germany (23.2%) and Spain
(21.9%).15 Uruguay (40.4%) and Nicaragua (27.6%) also achieved
high shares of generation from wind energy, and shares were high
at the sub-national level in several countries.16 Globally, wind power
capacity in operation accounted for an estimated more than 6% of
total electricity generation in 2020.17
For the 12th consecutive year, Asia was the largest regional
market, representing nearly 60% of added capacity (up from
50% in 2019), with a total of nearly 348.7 GW by the end of 2020;
almost 56% of new capacity was in China alone.18 Most of the
remaining installations were in North America (18.3%), Europe
(14.8%) and Latin America and the Caribbean (5.0%).19 The only
regional markets that did not expand in 2020 were Europe, where
the pandemic pushed many installations into 2021, and Africa
and the Middle East, which remained stable.20
China widened its lead for new capacity (both onshore and
offshore) and was followed distantly by the United States, which
was well ahead of Brazil, the Netherlands and Spain; these
five countries together accounted for just over 80% of annual
installations, with China and the United States alone responsible
for nearly 74%.21 Other countries in the top 10 for total capacity
additions were Germany, Norway, France, Turkey and India.22
(p See Figure 35 and Reference Table R18 in GSR 2021 Data
Pack.) Although the list of the biggest markets changed
significantly relative to 2019, the top 10 countriesii for cumulative
capacity were unchanged from those in both 2018 and 2019.23
Note: Numbers above bars are gross additions, but bar heights reflect year-end totals. Germany's net additions were slightly below those of Norway.
Source: See endnote 22 for this section.
FIGURE 35.
Wind Power Capacity and Additions, Top 10 Countries for Capacity Added, 2020
147
i Statistics differ among Chinese organisations and agencies as a result of what they count and when. See endnote 26 for this section.
RENEWABLES 2021 GLOBAL STATUS REPORT
China had its biggest year yet for new installations, despite
pandemic-related delays to grid connections early in the year.24
The estimated 52 GW (48.9 GW onshore and 3.1 GW offshore)
added in 2020 was about what the entire world installed in 2018,
and almost double China’s 2019 installations, and brought the
country’s total wind power capacity to an estimated 288.3 GW.25
Around 72 GW (including 3.1 GW offshore) of wind power
capacity was integrated into the national grid in 2020, with
281 GWi considered officially grid-connected by year’s end.26
The Chinese market was driven primarily by a rush to install
onshore projects that had to be grid-connected before the end of
2020 to receive the expiring national feed-in tariff.27 The offshore
market also faces a FIT qualification deadline (see discussion later
in this section).28 During the year, the central government reaffirmed
plans for onshore wind power (and solar PV) to achieve grid parity
by 2021.29 The policy changes result from a mounting deficit in
China’s Renewable Energy Development Fund, which has caused
a backlog of outstanding FIT payments for existing projects (only
worsened by the pandemic), and from the central government’s
belief that wind (and solar) power is capable of competing without
subsidies with coal-fired power.30 In 2020, China accounted for
67% of the 33.7 GW onshore wind capacity awarded globally in
auctions, and most of China’s awarded capacity was based on the
grid-parity scheme.31
The majority of China’s wind power capacity continues to be
in the north and west of the country, and at the end of 2020
wind power accounted for more than 20% of total capacity in
several provinces in these regions.32 However, deployment has
continued to shift towards China’s demand centres in the more
populated regions in the central east and south, which together
accounted for 40% of newly installed capacity in 2020.33 The top
regions and provinces for official grid-connected additions during
the year were East Inner Mongolia (6.8 GW), Henan (6.6 GW),
Shanxi (5.5 GW) and Hebei (5.2 GW).34 As the main wind regions
in China approach saturation, with ongoing curtailment and
fewer sites available for deployment, the country’s wind sector
is increasingly looking to distributed options and in particular to
offshore wind along China’s extensive coastline, where economic
activity is concentrated.35
Overall, an estimated 16.6 TWh of potential wind energy was
curtailed in China during 2020 – an average of 3% for the year,
down from 4% (16.9 TWh) in 2019, and below the national
government’s targeted cap (5%).36 Curtailment remained
concentrated mainly in Xinjiang, Gansu and Western Inner
Mongolia, but all three regions continued to see reductions
relative to previous years.37 China’s generation from wind energy
was up 15% (to 466.5 TWh), and wind energy’s share of total
generation continued to rise steadily, reaching 6.1% in 2020 (up
from 5.5% in 2019).38
Elsewhere in Asia, Turkey’s annual installations nearly doubled
relative to 2019, with 1.2 GW added for a total approaching
9.3 GW (all onshore).39 For the first time since 2017, Turkey was
among the top 10 countries globally for capacity added, ranking
ninth.40 Around 5 GW of new capacity was under construction
as of early 2021.41 Turkey is working to expand its renewable
energy capacity to lessen the country’s heavy reliance on
imported energy, create jobs and reduce the national carbon
footprint.42 Wind energy accounted for 8.4% of Turkey’s
electricity generation in 2020.43
India fell from fourth to tenth place globally for additions,
experiencing its lowest annual additions since at least 2006;
however, it continued to rank fourth for total capacity at the end
of 2020.44 India added 1.1 GW for a year-end total of 38.6 GW, all
operating onshore.45 Installations peaked in 2017 (4.1 GW) and
(aside from a slight uptick in 2019) have declined since auctions
were introduced to the wind tendering process in 2017.46 The
number and diversity of local investors in India’s wind power
sector also have declined since the shift to auctions, while
installations have become more concentrated geographically.47
At the end of 2020, the top Indian states for total capacity were
Tamil Nadu (9.4 GW), Gujarat (8.2 GW) and Maharashtra (5 GW),
which together accounted for nearly 59% of the country’s total
wind power capacity.48 Across India, wind energy generated
around 5% of all electricity during 2020; despite the increase in
capacity, output fell 24% during the peak wind season (June to
September) compared to 2019, due mainly to a significant and
unusual drop in wind speeds, and it was down 5% for the year.49
The United States
added more
capacity
in the final three months of
2020 than in any previous
year except 2012.
148
i The PTC gives wind energy generators a tax credit of roughly USD 0.02 per kilowatt-hour for electricity fed into the grid. Starting in 2021, the credit was scheduled
to decline steadily and to end in 2025. In light of delays and supply chain issues caused by the pandemic, the commissioning deadline for projects that began
construction in 2016 and 2017 was extended by one year; in December 2020, the PTC was legally extended for a further year at 60% of the full credit rate.
ii Essentially, trading the monetary value of the federal PTC (the future stream of tax credits to be received upon project completion) for upfront capital in order
to develop a project.
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India’s wind sector has faced challenges associated with grid
connection and permitting, land acquisition and (during the
pandemic) significant project construction delays.50 By mid-year,
a large amount of the capacity tendered in 2017-18 was not yet
online, due to these challenges and to low winning tariffs that
some developers have deemed unviable, making it difficult to
obtain financing.51 The Indian government announced plans to
remove tariff caps from future wind (and solar) power tenders,
eliminating a key limitation on investor interest; even so, in late
2020, two European companies stated that they would not
participate in India’s auctions, despite the country’s large resource
potential, due to low tariffs combined with land acquisition and
grid connection problems.52
Japan placed fourth in Asia with record additions of almost
0.6 GW (double the country’s 2019 installations) for a total of
4.4 GW.53 The increase in projects under development both
onshore and offshore was driven by the country’s generous
feed-in tariff.54 Kazakhstan brought 0.3 GW online during the
year, as the oil-rich country looks to green its energy mix and
achieve 50% renewable electricity by 2050.55 Other countries
in the region that installed new wind power capacity in 2020
included Chinese Taipei (74 MW), Pakistan (48 MW added), the
Republic of Korea (160 MW, including 60 MW offshore), Sri Lanka
(88 MW) and Vietnam (125 MW), where the market was driven
by a planned FIT expiration, a decline in the capital cost of wind
turbines and rapid growth in electricity demand.56
The Americas added a record of nearly 22 GW (up 62% over
2019), with most (72%) installed in the United States.57 The
country commissioned 16.9 GW of new capacity in 2020, up 85%
over 2019 installations.58 US capacity brought online in the fourth
quarter alone exceeded annual additions for every preceding year
except 2012.59 For the ninth year running, the oil and gas state of
Texas was the leader in annual wind power installations (4.2 GW),
followed by Iowa (1.5 GW), Wyoming (1.1 GW), Illinois (1.1 GW)
and Missouri (1 GW).60 At year’s end, US total capacity reached
122.5 GW, enough to power more than 38 million average US
homes.61 Texas continued to lead for total capacity (33.1 GW),
with 27% of the US total; if Texas were a country, it would rank
fifth globally for cumulative installations.62
As in past years with record additions, the US market was
propelled by the impending phase-out of the 100% federal
production tax crediti (PTC) at year’s end, which was granted a
one-year extension in late 2019, and extended again at the end
of 2020.63 Demand from corporations also played a role, as did
utilities (through direct ownership and, primarily, through PPAs)
aiming to meet customer preferences, sustainability goals and
mandates under state RPS laws.64 US wind power PPAs for the
year totalled 5.4 GW, down relative to the previous two years due
at least in part to uncertainty caused by COVID-19.65
Wind energy accounted for 8.4% of US utility-scale electricity
generation in 2020, up from 7.3% in 2019 and nearly four times the
share a decade earlier.66 In Texas, the country’s largest electricity
consumer by far, wind energy passed coal for the first time and
accounted for nearly 20% of the state’s utility-scale generation.67
Wind energy saw higher shares for the year in at least 10 other
states, including Iowa (58%), Kansas (43%), Oklahoma (35%)
and North Dakota (31%).68 The Southwest Power Pool (SPP),
a regional transmission organisation, became the first US grid
operator to see wind energy become the top source of electricity,
surpassing both coal and natural gas.69 The SPP, which covers
some of the windiest states in the central plains corridor, has a
robust transmission system and relies on accurate forecasting,
a diverse mix of generators and an efficient wholesale market
to manage high shares of variable renewable energy.70
(p See Systems Integration chapter.)
Despite the many advances across the United States, developers
continued to report challenges related to raising tax equityii for
projects already in development due to economic uncertainty,
limited tax equity supply and tight lending standards.71 New projects
increasingly are facing challenges related to project siting and
resource availability, as well as grid congestion.72 Many of the best
areas for wind power projects in some states, such as California,
have already been developed or have established prohibitions on
new development, while grid congestion and related transmission
upgrade costs have led to the cancellation of several wind (and
solar) power projects – including many that had already secured
PPAs – in nearly every region of the country.73
149
i The Contracts for Difference (CfD) is the UK government’s primary mechanism for supporting renewable electricity generation. Developers that win contracts
at auction are paid the difference between the strike price (which reflects the cost of investing in the particular technology) and the reference price (a measure
of the average market price for electricity).
ii A power available signal is a live data feed available to engineers in the control room of the UK’s National Grid ESO. The data provide engineers with the
potential maximum power output of a generator (in this case a wind farm) at any given time, enabling control systems to calculate each generator’s response
and reserve capability; this in turn allows the generator to compete with other generators to provide real-time response and reserve services. See endnote 98
for this section.
iii This figure excludes the United Kingdom for the sake of comparison.
iv Note that the EU cumulative data are lower than those reported for end-2019 because they no longer include the United Kingdom, which ended 2020 with
around 24.2 GW (13.7 GW onshore and 10.4 GW offshore).
RENEWABLES 2021 GLOBAL STATUS REPORT
Canada had a relatively slow year in 2020 (adding less than
0.2 GW), and most of the remaining installations in the Americas
were in Latin America and the Caribbean.74 Even as the region
was hard-hit economically by the pandemic, a record 4.7 GW of
new capacity came online, with Brazil ranking third globally for
additions and eighth for total capacity.75 Wind power has become
the region’s fastest growing power source, with around 33.9 GW
of wind power capacity operating across at least 26 countries at
year’s end.76
Brazil added 2.3 GW, three times the country’s 2019 installations,
for a total of 17.7 GW.77 The significant increase was thanks to
capacity deployed through local PPAs, driven by wind energy’s
competitive prices in Brazil.78 The government cancelled auctions
in 2020 due to the pandemic but rescheduled them for 2021.79
Wind energy accounted for 9.7% (56.5 TWh) of the country’s total
2020 electricity generation.80
Argentina (1 GW) and Chile (0.7 GW) followed Brazil in the region,
both with record years.81 Mexico (0.6 MW), Panama (66 MW) and
Peru (38 MW) also added capacity.82 After two years of ranking
among the world’s top 10 installers, Mexico’s market declined 45%
in 2020 due to policy and regulatory changes undertaken since
a new federal administration took office in late 2018 – including
the cancellation in 2019 of government-led electricity auctions.83
The changes have eroded the competitiveness of electricity from
wind energy and other renewable sources, creating significant
uncertainty for potential private investors and developers.84
Social acceptance issues and limited grid connection availability
also have hampered Mexico’s wind energy development.85 PPAs
for corporate procurement in Mexico nearly dried up in 2020,
whereas Brazil signed a record 1 GW of corporate renewable
energy PPAs that year.86
Europe added 13.8 GW of new wind power capacity in 2020
(down nearly 7% relative to 2019), of which 21% is operating
offshore, bringing the region’s total to nearly 210.4 GW.87 Onshore
additions were below expectations due largely to commissioning
delays resulting from COVID-19-related supply chain disruptions
and restrictions on the movement of people and goods, as well
as continued permitting delays in some countries (particularly
Germany).88 As in other regions, the diversity and number of
investors has declined in recent years with the phase-out of
FITs.89 Even so, 2020 was Europe’s third biggest year for new
installations, after 2017 and 2019.90
Outside of the EU, annual additions were up the most in Norway
and the Russian Federation, both with record installations.
Norway added 1.5 GW of capacity onshore, for an onshore total
of nearly 4 GW.91 Europe’s largest wind farm (1 GW Fosen) was
completed in Norway, despite the country’s low power prices and
protests over the project’s potential impacts on local reindeer
herders.92 The Russian Federation increased its capacity more
than four-fold (adding 0.7 GW), as capacity awarded in a 2018
auction began to come online, for a year-end total of 0.9 GW.93
Although the Russian Federation remained the world’s only major
economy just beginning to develop a domestic wind market and
industry, the awarded capacity (3.3 GW in total) should continue
to come online through 2024.94
In the United Kingdom, which just a year prior was the top installer
in Europe and the third largest globally, additions fell 75% in 2020
to 0.6 GW, most of it added offshore, for a cumulative total of
24.2 GW.95 After five years with no public support for onshore wind
(or solar) power, the UK government announced in 2020 that the
technology will again be allowed to participate in the Contracts
for Difference schemei.96 Wind generation rose 18% relative to
2019 due to increased capacity and even more so to favourable
wind conditions, particularly offshore, where output increased
26% and exceeded onshore generation for the first time.97 During
the year, more than 100 wind farms across the United Kingdom
were participating in a flexibility market trial, enabling them to
provide balancing services; industry governance codes require
new UK wind farms to provide “power available” signalsii.98
Most new capacity in Europe was installed in the EU-27,
which brought online nearly 10.8 GW (8.4 GW onshore and
2.4 GW offshore), or net additions of 10.4 GW (accounting for
decommissioning).99 Across the 27 Member States, 16 added
capacity during 2020, down from 18iii in 2019.100 Annual additions
were slightly below those in 2019, with installations down in all
but a handful of countries.101 The EU ended the year with a total
of 179.3 GWiv, including 164.7 GW onshore and 14.6 offshore.102
150
i If the United Kingdom were still an EU member, the country would rank third in the EU for total capacity, and the top five list would remain unchanged from 2019.
ii New federal provisions allow states to set minimum distances between turbines and residential areas at 1,000 metres. See endnote 122 for this section.
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The EU’s annual wind power market was again fairly concentrated,
with the top five countries – the Netherlands (added 2 GW),
Spain (1.7 GW), Germany (nearly 1.7 GW), France (1.3 GW) and
Sweden (1 GW) – accounting for 70% of the total.103 Although it
was not among the top countries, Poland also saw a substantial
jump over 2019 with 0.7 GW installed (up from 0.05 GW), helping
to balance the decline in other countries.104 The leading countriesi
for cumulative capacity at year’s end were Germany, Spain,
France, Italy and Sweden.105
The Netherlands was the top installer in Europe and ranked
fourth globally, adding nearly 2 GW (up from 0.3 GW in 2019)
for a cumulative total of 6.8 GW.106 Most of the new capacity
was offshore, with the country’s largest offshore project
fully commissioned in December.107 Onshore in mid-2020, a
cooperative of 200 local residents, farmers and other investors
closed turbine supply contracts and financing for a repowering
project near Amsterdam.108 Once completed in 2021-2022, the
0.3 GW Zeewolde project is expected to be the largest onshore
wind farm in the Netherlands and the largest community-owned
wind power project in Europe.109 The community structure helped
increase social acceptance of the project, easing permitting and
reducing risk for potential financers.110 The Dutch government
aims to increase community ownership from only a small fraction
of wind power capacity in 2020 to 50% of new wind (and solar)
projects by 2030.111
Spain ranked second in the region and fifth globally for new
capacity, adding more than 1.7 GW for a total of 27.4 GW.112 While
down from the 2.2 GW brought online in 2019, and below the
government’s target (set in 2020) of 2.2 GW per year to 2030,
it is a significant increase over annual installations during the
years 2009 through 2018.113 In late 2020, Spain approved an order
that regulates a new auction mechanism for wind and other
renewable power capacity for the 2020-2025 period.114 Wind
energy accounted for 21.9% of Spain’s electricity generation
in 2020.115
Germany placed third in the EU (and all of Europe) and sixth
globally for new capacity, but total additions were the country’s
lowest in a decade.116 Germany added almost 1.7 GW (1.4 GW net)
for a total of 62.6 GW (54.9 GW onshore and 7.7 GW offshore).117
Offshore installations (0.2 GW) were down 80% relative to 2019;
onshore additions increased nearly 33% after two years of
decline following Germany’s shift from a feed-in policy to tenders,
but were at their second-lowest level since 2010.118 Even so, wind
output was up 4% and wind energy accounted for 23.6% (131
TWh) of national gross electricity consumption during 2020,
exceeding brown coal (lignite) for the second consecutive year.119
In recent years, most of Germany’s auctions for onshore capacity
have been undersubscribed (including six of seven in 2020), and
annual deployment has fallen significantly. Factors behind the drop
include restrictive siting legislation in some states, complex planning
procedures and a decline in local proponents as the number of
local investors has fallen and projects increasingly are planned
by a relatively limited number of participants (mostly larger-scale
developers); these developments together have resulted in a lack
of permitted projects eligible to compete in the tendering process.120
As of mid-2020, the onshore wind permitting process took more
than two years, compared to the historical average of 10 months.121
Uncertainty about possible changes to setback distancing rules
also has reduced investments in new onshore capacity; in mid-
2020, the federal government gave states the final authority on
distancing rulesii.122 Germany’s New Renewable Energy Sources Act
(EEG 2021), passed at the end of 2020, set a new target for a total of
71 GW of wind power onshore (and 20 GW offshore) by 2030.123
For the EU and the United Kingdom combined, wind energy
generated an estimated 458 TWh in 2020 (up from 417 TWh in
2019) and met around 16.4% of total electricity demand (13.4%
with onshore and 3% with offshore wind).124 The 1.9 percentage
point share increase relative to 2019 resulted from additional
capacity, windy conditions early in the year and a drop in
electricity demand due to COVID-related restrictions.125
The community structure
of the Dutch Zeewolde
project helped to
increase social
acceptance,
easing permitting and
reducing risk for potential
financers.
151
RENEWABLES 2021 GLOBAL STATUS REPORT
In the South Pacific, Australia continued to account for
the majority of new installations, while New Zealand added
capacity (0.1 GW) for the first time since 2015.126 For the second
consecutive year, Australia saw records for both installations and
output, with 1.1 GW brought online at 10 new wind farms for a
total approaching 7.4 GW (all onshore).127 Renewable capacity
under corporate PPAs also achieved a new capacity record, with
wind power accounting for 41% (the rest being solar PV) of the
1.3 GW contracted in 2020.128 Community engagement also is
playing a growing role in Australia, with the industry increasingly
recognising the importance of benefit sharing with the local
community for successful project development.129
Wind power again was Australia’s largest renewable source of
electricity, producing 22.6 TWh (up 16% over 2019), or 9.9% of
the country’s total generation.130 Among the individual states, the
highest local shares of generation occurred in Victoria (29.7%),
South Australia (25.9%) and New South Wales (20.4%).131 The
rapid increase in the number and capacity of large wind (and
solar) power projects and their output continued to challenge the
grid, with ongoing connection and transmission issues; several
state governments announced renewable energy zones that are
expected to ease pressure on the grid.132 (p See Solar PV section
in this chapter.)
Africa and the Middle East combined installed over 0.8 GW of
wind power capacity, nearly the same amount as in 2019, despite the
pandemic’s impact on supply chains and project installation.133South
Africa accounted for nearly 63% of these additions with more
than 0.5 GW added, followed by Senegal (0.1 GW), which fully
commissioned its first commercial wind farm, and Morocco (nearly
0.1 GW), where several additional projects were under construction.134
Jordan, Iran, Egypt and Tanzania also added capacity, with Tanzania
completing its first commercial wind project.135 At year’s end,
13 countries in Africa and 5 in the Middle East had a total of 7.3 GW
of wind power capacity (all onshore), with most of it in South Africa
(2.5 GW), Egypt (1.5 GW) and Morocco (1.3 GW).136
Countries in the region are installing wind (and solar) power to
diversify their energy mix, lower per unit electricity costs while
meeting rising demand, reduce reliance on imported electricity
and fuels, and free up more of their own oil and gas for export.137
For example, to eliminate its heavy reliance on imported
electricity from Ethiopia, Djibouti was planning its first utility-
scale wind project (59 MW) in 2020, and Ghana was planning
for 1 GW of wind capacity to reduce reliance on fossil fuels and
hydropower, which has seen output decline with reduced river
flows.138 However, both Africa and the Middle East continued
to face challenges to further wind power deployment, including
uncertain or unsupportive policy and power market frameworks,
bottlenecks in transmission infrastructure and off-taker risk.139
In the offshore wind power segment, five countries in Europe
and two in Asia, as well as the United States, connected nearly
6.1 GW in 2020, increasing cumulative global offshore capacity
to more than 35.3 GW.140 Wind turbines operating offshore
accounted for 6.5% of all newly installed global wind power
capacity in 2020 (down from 10% in 2019) and represented 4.7%
of total capacity at year’s end (down from 5% in 2019).141 China led
the sector for the second year running, accounting for just over
half of new installations, and Europe installed most of the rest.142
China added a record 3.1 GW of offshore capacity, raising the
total 44% to around 10 GW.143 More capacity might have been
commissioned in 2020, but progress was stalled by bottlenecks
including supply chain issues and a lack of offshore turbine
installation vessels.144 Developers rushed to finalise projects
before the end of 2021, when the national FIT for offshore wind
power is scheduled to end.145 Jiangsu, Fujian and Guangdong
together were home to more than 80% of China’s offshore
capacity in operation at the end of 2020.146 These and other
coastal provinces have set offshore wind capacity targets totalling
nearly 60 GW of capacity by 2030.147
Elsewhere in Asia, the Republic of Korea added 60 MW of
offshore wind power capacity; Japan launched its first offshore
wind auctions, including one for a floating wind farm; and Chinese
Taipei had three projects under construction offshore with a total
capacity of 0.7 GW.148 The Republic of Korea aims for 12 GW of
offshore capacity by 2030, and in December 2020 Japan released
a vision document that calls for 10 GW of offshore capacity by
2030 and 30-45 GW by 2040.149
In July 2020, a PPA was signed for the entire output of a 0.9 GW
wind project (the world’s largest-ever renewable energy PPA at
the time) off the west coast of Chinese Taipei that is due to begin
construction in 2025.150 To date, relatively few corporate deals
have been signed globally for offshore wind energy, but corporate
interest is increasing due to the large scale of generation, high
capacity factors, fairly uniform generation profile and falling
costs.151 Six new offshore PPAs also were signed in Europe, for
projects in Belgium, Germany and the United Kingdom, following
the first six in 2018-19.152 PPAs have become an increasingly
important means for developers to guarantee revenue over the
long term, especially in the case of exposure to wholesale market
price (as with “zero-subsidy” bids at auction).153
Europe remained home to most of the world’s offshore capacity.
The region added 2.9 GW in 2020 (down 20% from 2019) in nine
completed wind farms, bringing the regional total to 25 GW.154
The Netherlands more than doubled its offshore capacity
(adding 1.5 GW) and accounted for more than half of Europe’s
installations; it was followed by Belgium (0.7 GW), which had a
record year, the United Kingdom (0.5 GW), Germany (0.2 GW)
and Portugal (nearly 17 MW).155 UK installations were the lowest
since 2016, not because of faltering commitment but because of
152
i This proof-of-concept project was a step towards development of a 2.6 GW project in the same area, scheduled to be brought online in phases between 2024 and 2026.
Gigawatts
2016201520142013201220112010 2017 20192018 2020
Rest of World
China
Europe
0
5
10
15
25
30
20
35 35
Gigawatts
World
Total
2.92.9
3.93.9
5.25.2
6.86.8
8.58.5
11.911.9
14.214.2
18.718.7
2323
2929
3535
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a gap between government contracting rounds, and foundations
were installed to prepare sites for enormous future wind farms.156
Germany saw its lowest numbers in nearly a decade, with no
new offshore wind power projects under construction at year’s
end as all projects planned under tenders had been installed.
However, under a new offshore wind energy law that entered
into force in December 2020, Germany is set to increase offshore
tender volumes significantly.157 Portugal’s additions of two floating
turbines completed the Windfloat Atlantic wind farm.158 Europe’s
total floating capacity reached 62 MW, and the pipeline for floating
wind projects in the region for the next decade exceeds 7 GW.159
At year’s end, five countries continued to host nearly all of
Europe’s offshore capacity: the United Kingdom (42%), Germany
(31%), the Netherlands (10%), Belgium (9%) and Denmark (7%).160
The year brought a record EUR 26.3 billion (USD 32.3 billion) of
financing for 7.1 GW of future capacity (including transmission
infrastructure) off the coasts of the United Kingdom, Germany
and France; this is up from EUR 6 billion (USD 7.37 billion) in
2019.161 In 2020, several countries increased their future targets
for offshore wind power capacity, including the United Kingdom
(boosted its 2030 target from 30 GW to 40 GW) and Germany
(increased its 2030 target from 15 GW to 20 GW).162 As of early
2021, total government commitments for offshore wind power by
2030 reached 111 GW.163
Targets also were increased in the United States, with six eastern
states aiming to bring online a combined 28.1 GW of offshore
wind power capacity by the 2030-2035 period.164 By early 2020,
state procurement commitments totalled 28.9 GW, and another
55.9 GW was in interconnection queues by mid-year.165 Actual
installations remained low, however. The country’s first project
installed in federal waters, a 12 MW piloti off the coast of Virginia,
was completed during 2020, bringing total US offshore capacity
to 42 MW.166
Other US developments in 2020 included: New York state issued a
second solicitation for 2.5 GW; Rhode Island announced a request
for proposals for 0.6 GW; Massachusetts approved contracts for
the 0.8 GW Mayflower Wind project; the Icebreaker project on
Lake Erie moved forward after years of permitting battles; and
Louisiana began investigating the potential for offshore wind in
the Gulf of Mexico to create jobs and reduce greenhouse gas
emissions.167 In early 2021, the 0.8 GW Vineyard Wind project
(Massachusetts) was granted final federal approval.168
By the end of 2020, 18 countries (12 in Europe, 5 in Asia and 1 in North
America) had offshore wind capacity in operation, unchanged from
2019.169 The United Kingdom maintained its lead for total capacity
(10.4 GW), followed by China (10 GW), which overtook Germany
(7.7 GW), the Netherlands (2.6 GW) and Belgium (2.3 GW), both
of which overtook Denmark (1.7 GW) in 2020.170 Europe was home
to around 70% of global offshore capacity (down from 75% in 2019
and 79% in 2018), with Asia (mostly China) accounting for nearly
all the rest.171 (p See Figure 36.) Around the world, an additional
82 GW of offshore capacity was under construction, had been
approved through regulatory processes or had reached financial
close.172 Global capital expenditures committed to offshore wind
power surpassed investments in offshore oil and gas for the first
time in 2020.173
Note: Totals above 20 GW are rounded to nearest GW. Rest of World includes the rest of Asia as well as North America.
Source: See endnote 171 for this section.
FIGURE 36.
Wind Power Offshore Global Capacity by Region, 2010-2020
153
i Note that energy costs vary widely according to wind resource, project and turbine size, regulatory and fiscal framework, the cost of capital, land and labour,
exchange rates and other local influences.
ii Unless noted otherwise, mentions of auctions and tenders as support mechanisms presume wind technology-specific tenders or those specific to renewables in
general. Technology-neutral tenders (open to non-renewables) do not constitute a support mechanism, although such tenders can and do draw successful bids
from renewable energy developers.
iii Note that bid levels do not necessarily equate with costs. Bid levels differ from market to market due to varying auction designs, policies and risks, among
other factors.
RENEWABLES 2021 GLOBAL STATUS REPORT
The decommissioning of
wind turbines that had
reached the end of their
service life, or were
ripe for refurbishment
on economic grounds,
totalled an estimated
0.5 GW in 2020, across
10 countries.174 In Europe,
seven countries decom-
missioned almost 0.4 GW
of capacity, all of it
onshore, led by Germany (222 MW), Austria (64 MW) and
Denmark (62 MW), with smaller amounts in Belgium, France,
Luxembourg and the United Kingdom.175 The United States
decommissioned around 74 MW of capacity, with the remainder
removed from operation in Japan and the Republic of Korea.176
Decommissioning does not necessarily mean the end of a project,
but can pave the way for repowering with more advanced and
efficient technology; some of the decommissioned projects were
repowered. (p See Industry section below.)
WIND POWER INDUSTRY
Even as the global market expanded and several countries had a
strong year, the global wind industry continued to face perennial
challenges that were exacerbated by the pandemic. Nonetheless, a
number of developments fed hope for the year to come, including:
remedial policy adjustments in several countries, ongoing
technology development and innovations, growing attention to
climate change mitigation and wind energy’s potential role, and
increasing interest among industry actors and governments in
advancing floating wind technologies and green hydrogen.
Particularly early in the pandemic, the wind industry was affected
by restrictions on movement of labourers and supplies.177
Turbine assembly generally requires components produced in
numerous countries around the globe, and lockdowns disrupted
supply chains.178 Restrictions also slowed project permitting
and development (particularly onshore), which was especially
challenging for developers racing to complete projects before
support policies changed or expired at year’s end, or before fixed
commissioning deadlines.179 Short-term declines in electricity
demand and prices led asset owners to reduce operation and
maintenance (O&M) budgets; these downward trends also
adversely affected demand for turbines and new projects and
curtailed access to financing for onshore wind, which slowed the
signing of PPAs and investment in new onshore projects.180 The
result was reduced margins for turbine manufacturers (suppliers of
both machines and, increasingly, O&M).181
These troubles all added to existing challenges, including: the
lack of grid access and unreliable grid systems; poorly designed
tenders in some countries; and the lack of available land with good
wind resources.182 Permitting delays also have been prevalent, due
in some cases to local opposition as the number of participants
declines and the size of developers and the scale of projects increase;
in 2020, delays worsened as government staff was reassigned
to pandemic-related matters.183 In another ongoing challenge,
downward pressure on bid prices in some markets is affecting
manufacturers and developers, even as a lack of investment and
competition in other markets has driven bid prices up.184
In several countries, governments responded by extending
deadlines to account for pandemic-related delays.185 By the end
of 2020, new policy commitments had helped stimulate record
investments in new projects.186 The year saw new entrants
(including fossil fuel companies) to the wind power sector, and
wind turbine manufacturers and developers expanded further into
new sectors.187 The industry continued to better integrate wind
energy into existing electricity grids and to improve technologies to
increase output and further reduce the cost of energy.188
By one estimate, from the second half of 2019 to the same period
in 2020, the global benchmark levelised cost of energyi (LCOE)
from new wind power projects fell 17% onshore (to an average
USD 41 per MWh) and 1% offshore (USD 79 per MWh).189 Cost
reductions are the result of several factors, including more
powerful and efficient turbines that can capture more wind and
economies of scale with larger projects, which reduce per unit
costs of installation, operation and maintenance.190
Auctioned capacity in 2020 was down 26.5% relative to 2019 but
reached the second highest level on record, with a global total of
35 GWii (including 33.7 GW onshore).191 Activity plummeted early in
the year, due mainly to pandemic-related postponements in some
key markets, but increased over the second half of 2020 relative
to the same period in 2019.192 China accounted for two-thirds of
the total wind power capacity auctioned and awarded, with most
of this for onshore projects to be built without direct government
support.193 Thirteen other countries or regions held wind-specific
or renewable energy auctions, including several in Europe as well
as Ecuador, India and the US state of New Jersey.194
Resultsiii from auctions vary widely depending on local conditions
and costs, project scale and other factors.195 For example, Europe’s
winning onshore bids during 2020 were in the range of EUR 42.4
to EUR 69.2 (USD 52 to USD 85) per MWh, compared with
EUR 21 to EUR 67 (USD 25.8 to USD 82.3) per MWh in 2019.196
While declining costs and fierce competition in auctions and
tenders have driven down average bid prices in many markets,
bids have been stable or even rising in others. Relative to earlier
auctions, prices for onshore wind power in 2020 were down
significantly in France and Greece.197 In contrast, prices were up
in Italy, where all three auctions for solar PV and wind power
were undersubscribed, due in part to permitting challenges.198
The pandemic added to
existing challenges, but
several
developments
fed hope
for the year to come.
154
i The combined price for electricity and renewable energy credits under the Mayflower Wind project will come to USD 77.76 per MWh on a nominal levelised
basis for the two phases of the project. See American Clean Power Association, ACP Market Report – Fourth Quarter 2020 (Washington, DC: 2021), p. 16,
https://cleanpower.org/resources/american-clean-power-market-reportq4-2020.
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In Germany, winning bid levels for onshore capacity were fairly
stable through the year, but remained higher than at auctions
in 2017 and early 2018, and above the statutory tariffs under the
country’s previous Renewable Energy Act.199
In India, several wind tenders in recent years resulted in
relatively low levels of competition, as policy, regulatory and
market uncertainty have shifted the sector towards developers
with greater risk-taking capacity.200 The inconsistent regulatory
environment and lack of suitable sites in most Indian states for
wind power project development have contributed to the rise
in wind tariffs since 2017 and helped to increase the relative
attractiveness of solar PV.201
In the offshore sector, the Netherlands held its third tender for
which the winning project (due online by 2023) will receive only
the wholesale price of electricity and will pay an annual rent for
seabed rights.202 The winning consortium of Shell and Eneco
plans to build a 759 MW project that will include floating solar
PV and battery storage, and to use the electricity generated to
produce hydrogen.203 Offshore wind tenders also were held in
the US state of New Jersey (bid price pending as of early 2021)
and France, where the winner of a tender for 1 GW off the coast of
Normandy is expected to be announced in 2022.204
In some countries where auctions are putting growing price
pressure on markets, direct PPAs are becoming increasingly
important.205 In Brazil, for example, returns to developers can be
higher through PPAs than in national electricity auctions.206
PPA prices trended upwards in Europe through most of 2020
but generally declined in the fourth quarter.207 In the United
States, prices under PPAs for onshore wind power capacity rose
throughout 2020, with steeper increases starting in the second
quarter; the pandemic was among the factors driving up prices,
in addition to grid connection delays, permitting challenges and
the fact that the windiest sites with easy grid access have already
been developed.208 This increase followed a steady decline in US
average PPA prices since 2009.209 In the offshore segment, in
early 2020 developers signed PPAs with six utilities in the US
state of Massachusetts for electricity from the 0.8 GW Mayflower
Wind project, due for commissioning in 2025; the levelised price
over 20 years was USD 58.47 per MWhi (13% below the levelised
price of the relatively nearby Vineyard Wind project in 2018),
setting a new benchmark for US offshore wind.210
The wind industry has seen more than 100 turbine suppliers
over the years, with a peak of 63 suppliers reporting installations
during 2013; the number has declined rapidly since 2015, with 33
in 2019, but might have climbed slightly in 2020, due to the rush of
installations in China.211 The six leading manufacturers captured
75% of the capacity installed in 2020 (up from 64% in 2017).212
The top six turbine suppliers in 2020 were Vestas (Denmark), GE
Renewable Energy (GE, US), Goldwind, Envision (both China),
Siemens Gamesa (Spain) and Mingyang (China), together
accounting for more than 63 GW of installations.213 Vestas stayed
on top for the fifth consecutive year, GE delivered record global
volumes and benefited from a strong home market – as did
Goldwind (which also suppled more than 1 GW of turbines for
overseas markets for the first time), Envision and Mingyang – and
Siemens Gamesa dropped from third in 2019 to fifth in 2020, but
led the offshore market.214 Chinese manufacturers took 10 of the
top 15 places, thanks to the dramatic increase in China’s onshore
installations; the role of most Chinese firms beyond the domestic
market remains limited.215
Senvion (Germany) and Suzlon (India), both among the top 10 in
2017, and Germany’s Enercon (eighth in 2019), all continued to
struggle due to declining sales in their home markets.216 Even top
manufacturers suffered losses for the year, closed factories and
laid off workers, despite selling more turbines (by capacity), as
the highly competitive market combined with pandemic-related
costs and delays to further squeeze profit margins.217 Both Vestas
and GE reported that their orders for new turbines had fallen
slightly relative to 2019.218 Legal battles among manufacturers
escalated in 2020 and into 2021 over intellectual property as they
sought to maintain or gain control over key markets.219
To further diversify their portfolios in key markets, wind power
developers and turbine manufacturers continued expanding
into new sectors during 2020.220 Ørsted (Denmark), the largest
In some countries where
auctions put growing price
pressure on markets,
direct PPAs
are becoming increasingly
important.
155
https://cleanpower.org/resources/american-clean-power-market-reportq4-2020
i Note that Vestas acquired Mitsubishi Heavy Industry’s (MHI) shares in MHI Vestas in late 2020, and the company was integrated back into Vestas.
See endnote 238 for this section.
RENEWABLES 2021 GLOBAL STATUS REPORT
offshore wind developer and operator, took the final investment
decision in late 2020 to develop a large solar PV project in the US
state of Texas under a long-term PPA, bringing the company’s
solar portfolio to 1.1 GW under construction.221 Chinese turbine
manufacturers are turning to solar PV and other avenues to
diversify their business as national subsidies are phased out.
Mingyang, for example, has developed a solar and financing lease
business, while Goldwind has expanded into water treatment,
and Envision acquired Automotive Energy Supply Corporation
(Japan) to move into energy storage and batteries.222
Manufacturers also focused on technology innovation, building
largely on existing concepts.223 The fact that nearly all major
wind power markets are auction driven (including new, emerging
markets) has pressured the industry to continuously reduce costs
and achieve the lowest possible levelised cost of energy.224 One
ensuing trend in recent years has been a move to turbines with
lower specific power (the ratio of capacity to rotor swept area). This
results in less energy production per square metre of rotor area
but offers several benefits that help reduce the LCOE, including
lower generator costs and savings on other components, as well
as higher capacity factor and reduced variability of output, which
lowers balancing costs and can increase the value of the turbine’s
generation to the grid system.225
Turbines for use onshore and offshore continued to get larger
and taller during 2020, enabling them to capture more energy
from the wind to make wind-generated electricity economical in
more locations.226 Onshore turbines in the 5 to 6-plus MW range
were introduced by GE, Nordex (Germany), Siemens Gamesa,
and Vestas, and Mingyang launched a 6.25 MW machine.227
Several companies also launched new smaller machines for low-
wind sites, including those targeted to wind conditions in specific
markets.228 Goldwind was working on new turbines for low- and
medium-wind speeds (both onshore and offshore) and new
hybrid tower concepts to further reduce the LCOE as China’s
FITs come to an end.229
Taller turbine towers and longer blades have affected everything
from design to manufacture, transport and installation (and related
costs).230 To address the challenges associated with transporting
taller towers, Nordex launched a facility in Spain (the company’s
12th such factory) based on a mobile concept that enables
concrete towers to be produced and assembled locally, reducing
logistics costs as well as transport distances. The facility can be
dismantled and reassembled in new locations.231 GE announced
a partnership with a robotics firm and a building manufacturer
to develop 3-D printed
concrete bases for on-site
production of turbine
towers. The process
should allow for larger bases and thus taller hub heights to
capture stronger winds, while also reducing transport-related
costs and challenges.232
The world’s then-longest blade – LM Wind Power’s 107 metre
blade – was certified for use in November 2020.233 The move
towards ever-longer blades for use onshore and offshore has
affected supply chain strategies, including the increasing
outsourcing of production.234 Even so, the number of blade
suppliers declined by about one-third from 2016 to 2020 as small-
and medium-sized manufacturers were unable to compete on
R&D investment, costs and global presence.235 In 2020, both
GE and Siemens Gamesa closed blade manufacturing facilities
to cut costs and because of the facilities’ inability to handle
larger blades and the falling demand for the smaller blades they
produced.236
In 2020, the average size of turbines delivered to market was 2%
larger than in 2019 (2.76 MW), at 2.81 MW (2.7 MW onshore and
6.0 MW offshore).237 In late November, the last of 77 MHI Vestasi
9.5 MW turbines – the largest turbines installed thus far – was
installed at a site off the Dutch coast.238 Just one of these turbines
has nearly as much power capacity as the combined total of the
first two offshore wind farms, off the coast of Denmark.239
Turbines are set to get only larger as manufacturers race to build
the biggest and most powerful units, especially for offshore use.
In 2020, GE increased the power rating of its Haliade-X prototype
to 13 MW, and later boosted it to 14 MW for use in the UK’s Dogger
Bank wind farm, with installation set to begin in 2025.240 Siemens
Gamesa released a 14 MW turbine that can be boosted to 15 MW
and should be commercially available starting in 2024.241 By mid-
2020, several Chinese manufacturers had entered the fray, with
Dongfang commissioning a 10 MW prototype and Mingyang
announcing an 11 MW hybrid drive (the world’s largest), which
it expects will be commercially available in 2022.242 Not to be
left behind, Vestas became the first to launch a 15 MW turbine
(upgradable to 17 MW) in early 2021.243
Larger, taller wind turbines
are able to capture more
energy, making wind-
generated electricity
economical
in more locations.
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i Excludes Shell, which did not have a stated target as of early 2021.
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Offshore developers are taking advantage of larger turbines as
soon as they become available, with several orders placed for
these mega-turbines during 2020.244 Larger, higher-efficiency
turbines mean that fewer turbines, foundations, converters,
cables, less labour and other resources are required for the same
output, translating into faster project development, reduced risk,
lower grid-connection and O&M costs, and overall greater yield,
all particularly important for the offshore sector.245
Floating turbines offer the potential to expand the areas where
offshore wind energy is viable and economically attractive
because they can be placed where winds are strongest and
most consistent, rather than where the sea-floor topography is
suitable.246 Costs are about double those of fixed bottom turbines
but continue to fall as technologies advance, and the sector is
ready for full commercialisation.247 In late 2020, an MHI Vestas
(now Vestas) 9.5 MW turbine became the largest yet installed for
use in a floating project, off the coast of Scotland.248
Throughout 2020, several major wind power developers –
including Enel (Italy), Equinor (Norway), Ørsted, RWE (Germany)
and Vattenfall (Sweden) – unveiled plans to produce hydrogen
or methane with wind energy.249 In addition, Siemens Gamesa
and spin-off Siemens Energy were developing an offshore
turbine with a fully integrated electrolyser to produce hydrogen
directly.250 Several oil and gas companies also announced plans
or launched partnerships to develop hydrogen projects linked to
offshore wind power.251
As offshore wind power has advanced (and particularly floating
technologies), major oil companies have begun investing large
and growing amounts of money into the sector, which is one
of the areas (in addition to geothermal) where the skill and
knowledge transfer from oil to renewable energy is most clear.252
As of early 2021, oil majors accounted for only 5% of offshore
capacity in operation, but from early 2019 to March 2021 they won
about half of offshore wind power tenders awarded outside of
China.253 European oil majorsi have a combined target of at least
125 GW of renewables capacity by 2030, with much of this being
offshore wind power.254
Among developments in 2020, Total (France) made its first major
investments in offshore wind power, acquiring stakes in projects
in UK waters and announcing plans to develop a 2.3 GW floating
project off the Republic of Korea, and Eni (Italy) also entered the
UK market, acquiring 20% of the UK Dogger Bank project.255
Both Equinor (Norway), a pioneer in floating wind technology, and
Neoenergia (Spain) were looking at the possibility of developing
offshore wind projects in Brazil, and Equinor and BP (UK) partnered
to develop offshore wind capacity in the United States.256 Shell
(Netherlands) is partnering on several offshore projects, and
(along with German utility Innogy) is a major backer of the Steisdal
TetraSpar, a new floating foundation that promises easier assembly
and installation, and thus lower costs.257 Also, Australian oil and gas
explorer Pilot Energy announced plans to undertake a feasibility
study into a 1.1 GW project off the coast of Western Australia as
part of its effort to diversify beyond fossil fuels.258
Several Asian and European utility companies have begun
moving into offshore wind power technology and project
development, especially in the floating sector.259 In 2020, two of
India’s largest fossil fuel and electricity companies partnered to
develop renewable energy projects, including offshore wind.260
Offshore wind is not without its challenges. There are concerns
that the offshore sector is growing so quickly – in the number
of projects and the scale of turbines – that it will outpace the
number, size and ability of installation vessels to transport and
lift large components.261 As of late 2020, only four vessels were
capable of handling the next generation of offshore turbines,
such as GE’s Haliade-X.262 In addition, new offshore markets still
face challenges that Europe and China have addressed, including
developing supply chains, a trained workforce and associated
infrastructure such as ports, rail links and grid infrastructure.263
The United States, for example, had no offshore wind factories
as of 2020; however, at least six states were competing during
157
i Repowering refers to the process of replacing turbines within an existing wind farm with newer turbines. If the majority of components (including foundation)
are replaced, a project is considered repowering; replacement of only specific components is consider partial repowering. See endnote 265 for this section.
ii Repowering a project enables owners to reset the clock on 10 years’ worth of US federal tax credits, encouraging the replacement of parts of existing turbines
well ahead of the end of their original life expectancies. Looming expiration of the tax credit drove increased activity. See endnote 269 for this section.
RENEWABLES 2021 GLOBAL STATUS REPORT
the year to host them, announcing plans to build manufacturing
facilities and to transform ports and marine terminals into hubs
for an offshore wind industry, and some states announced plans
to start training workers.264
Around the world, and particularly onshore, major manufacturers
are focused increasingly on the repoweringi segment.265
Historically, repowering has involved the replacement of old
turbines with fewer, larger, taller, and more efficient and reliable
machines at the same site, but increasingly operators are
switching even relatively new machines for larger and upgraded
turbines (including software improvements) or are replacing
specific components (partial repowering).266 Bigger blades,
new rotors and improved mechanics all can boost efficiency
and provide better monitoring of wind speed and direction,
increasing output by 10% or more, and without the challenges of
interconnection and permitting hurdles.267
In the United States, project owners partially repowered 2.9 GW
at existing projects in 2020, slightly below 2019 levels but 130%
above 2018 levels.268 Repowering in the country was driven by the
looming expiration of the federal PTCii at year’s end (later extended
in December) and by the significant technology improvements
of recent years.269 Repowering increased somewhat in Europe
(345 MW) through projects in Germany (339 MW) and smaller
amounts in Greece, Luxembourg and the United Kingdom.270
Repowering in China has been limited to date.271
As the earliest fleets of wind turbines reach retirement age, and
components are replaced, concerns are increasing about what
to do with turbines and components at the end of their life.
Although most of a turbine can be used on another wind farm
or recycled, blades are made of complex composite materials
that are difficult and expensive to recycle.272 Efforts have focused
on repurposing old blades (e.g., as sound barriers) or developing
solutions for recycling and reusing their composite materials,
and on developing blades with entirely different materials.273
Related developments in 2020 and early 2021 included: GE signed
a contract with Veolia North America to use decommissioned
blades as raw material in place of coal, sand and clay for cement
production; the DecomBlades consortium (Denmark) launched
to find sustainable recycling solutions for composite materials
in blades; a consortium of 10 companies and technical centres
launched the Zero wastE Blade ReseArch (ZEBRA) project
in Europe to develop the world’s first fully recyclable blade of
thermoplastic resin; and US researchers validated the structural
integrity of thermoplastic composite blades, determining that
they could be more efficient and robust, manufactured on site,
and the material could be melted and reused.274
An increasing number of manufacturers also are focused on
making wind turbines sustainable in their production as well as
at end of life, and trying to do so in a way that is cost effective in
order to remain competitive.275 After achieving its 2019 goal to
become carbon-neutral in early 2020, Siemens Gamesa turned
its attention to its international supply chain.276 Also in 2020,
Vestas (which achieved 100% renewable electricity in 2013)
joined RE100 and set a target to become carbon neutral by 2030
through its own corporate actions; Vestas also announced plans
to eliminate non-recyclable waste from manufacturing, operating
and decommissioning of its wind turbines by 2040.277 Early in
2021, Envision committed to achieving carbon neutrality for its
operations by 2022 and for its value chain by 2028.278
p See Box 7 for developments in the small-scale wind power
sector.279 Also see Sidebar 6 on the following pages for a summary
of the main renewable energy technologies and their characteristics
and costs.280
An increasing number of
manufacturers are focused on
making wind
turbines
sustainable
in production as well as at
end of life.
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BOX 7. Small-scale Wind Power
Small-scalei (up to 100 kW) wind turbines are used for a
variety of on- and off-grid applications, including defence,
rural electrification, water pumping and desalination,
battery charging, telecommunications and to displace diesel
in remote locations. The annual global market continued
to shrink in 2019 (latest data available) in response to
onerous local permitting and planning laws, inconsistent
policy support as well as unfavourable policy changes (e.g.,
introduction of market caps, removal of incentives), and
ongoing competition from relatively low-cost solar PV.
By one estimate, 42.5 MW of new small-scale wind power
capacity was installed in six countries during 2019, down from
an estimated 47 MW in 2018 and 114 MW in 2017. Due to a lack
of data, these estimates do not include off-grid systems even
in large markets, or installations in additional countries. At the
end of 2019, more than 1 million small-scale turbines (totalling
at least 1.7 GW) were estimated to be in operation worldwide.
China continued to be the largest market with an estimated
23 MW installed in 2019, down from 30.7 MW in 2018. Japan
added 17 MW, followed distantly by the United States with
1.4 MW, a 7% annual reduction that continued the country’s
downwards trend in small-scale turbines; much of the new
US capacity was for retrofit projects. Other important markets
included Germany (0.5 MW), the United Kingdom (0.4 MW)
and Denmark (0.2 MW).
Markets declined during 2019 in all of these countries except
Japan, where installations were up nearly 32% over the
previous year. By June 2020, Japan had more than 5,000
projects (108 MW) approved under a new FIT system, and
only a small portion of these was already in operation.
In response to shrinking domestic markets, the number of
producers of small-scale wind turbines in China and the
United States has declined sharply in recent years, with
manufacturers relying heavily on export markets, which also
have been in decline. US-manufactured exports, for example,
fell below 0.5 MW in 2019, down from 2015 (21.4 MW), as
key export markets largely dried up due to reduced or
discontinued feed-in tariff programmes. US domestic sales
rose slightly in 2019 (from 1.1 MW in 2018 to 1.2 MW in 2019)
as imports fell; but domestic small-scale turbine sales were
well below their annual totals early in the decade.
At least in the United States, however, things were looking up
in 2019 and early 2020 with evidence that a 2018 extension of
the federal investment tax credit for small-scale wind power,
combined with public research and development (R&D)
funding to improve competitiveness, could enable small and
distributed wind power to turn the corner in the country.
US R&D efforts also were under way to make wind power
technology a plug-and-play component in hybrid systems
and microgrids, among other options.
Italy, which has been an important market in past years, also
received a boost from a new FIT incentive that was enacted
in mid-2019. Following a decline in total capacity due to
decommissioning (8.2 MW in 2018 and 2.6 MW in 2019), an
estimated 8 MW of new small-scale wind power capacity
was installed in the first half of 2020.
Elsewhere, the small-scale wind sector is seeing the
emergence of several start-up companies, including
Diffuse Energy (Australia) and Alpha 311 Ltd (UK), which
manufactures vertical-axis turbines that are attached to
existing light posts located near roads or rail lines. New uses
for small-scale turbines under consideration or development
include mining, small microgrids and data centres.
i Small-scale wind systems generally are considered to include turbines
that produce enough power for a single home, farm or small business
(keeping in mind that consumption levels vary considerably across
countries). The International Electrotechnical Commission sets a limit
at around 50 kW, and the World Wind Energy Association and the
American Wind Energy Association as well as the US government
define “small scale” as up to 100 kW, which is the range also used in
the GSR; however, size varies according to the needs and/or laws
of a country or state/province, and there is no globally recognised
definition or size limit.
Source: See endnote 279 for this section.
159
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 6. Renewable Electricity Generation Costs in 2020
Renewable power costs continued to decline in 2020, keeping
with trends from the past decade. The mature technologies
such as hydropower, bio-power and geothermal, typically are
dispatchable and low-cost power sources, and are competitive
in regions where unexploited resources exist. However,
the decade was notable for the rapid improvements in the
competitiveness of solar and wind power technologies.
The levelised cost of electricity (LCOE)i of utility-scale solar PV
fell 85% between 2010 and 2020, from USD 0.381 per kWh to
USD 0.057 per kWh. (p See Figure 37.) Over the decade, utility-
scale solar PV became competitive with the lowest-cost new
fossil fuel-fired capacityii. Cost declines were driven primarily by
falling module prices and reductions in balance-of-systemiii costs,
which tumbled between 2010 and 2020 as module efficiency
improved and manufacturing was scaled up and optimised. As
a result, the total installed cost of utility-scale solar PV fell 81%
over the decade.
The LCOE of onshore wind power fell 54% between 2010 and
2020, from USD 0.089 per kWh to USD 0.041 per kWh. The total
installed cost of newly commissioned onshore wind projects fell
from USD 1,970 per kW to USD 1,355 per kW during the decade.
Cost reductions for onshore wind were driven by declining
turbine prices and by reductions in balance-of-plant costs and
operation and maintenance costs. At the same time, costs have
been reduced through continued improvements in wind turbine
technology (e.g., larger turbines, higher hub heights and larger
swept blade areas), wind farm siting and reliability that have
led to an increase in average capacity factors, with the global
weighted average rising from 27% in 2010 to 36% in 2020iv.
For offshore wind, the LCOE of newly commissioned projects
fell 48% from USD 0.162 per kWh in 2010 to USD 0.084 per kWh
in 2020. Annual values for the global weighted average total
installed costs, capacity factors and LCOE are relatively volatile
given the small number of projects added in some yearsv.
From 2010 to 2020, total installed costs fell around 32%, while
capacity factors increased from 38% in 2010 to 42% in 2019,
before dropping back to 40% in 2020. The drop in the global
weighted average capacity factor in 2020 was driven by new
plants being commissioned mainly in China, where offshore
wind farms still predominantly use smaller offshore wind turbine
designs and are in areas with lower-quality wind resources (e.g.,
inter-tidal or near shore).
i All references to LCOE and total installed costs in this sidebar are global weighted averages. Note also that costs are very location- and project-specific,
and cost ranges can be substantial; the LCOEs presented here should be considered in the context of the country- and region-specific project cost ranges
outlined in International Renewable Energy Agency (IRENA), Renewable Power Generation Costs in 2020 (Abu Dhabi: 2021), which provides further details
on the LCOE methodology.
ii The fossil fuel-fired power generation cost range varies by country and fuel, but overall is estimated at between USD 0.055 per kWh and USD 0.148 per kWh.
The lower bound represents new coal-fired plants in China.
iii Balance-of-system and balance-of-plant costs encompass the full project costs, including labour, hardware, permitting, grid interconnection, etc.
iv The global weighted average capacity factor for newly commissioned onshore wind projects in 2020 reported here is uncertain given that the geographic
distribution of new capacity connected to the grid in China in 2020 was not available when the analysis was undertaken.
v The growth in new markets in recent years, both within Europe (where offshore wind's first markets developed) and globally, have made year-on-year cost
comparisons difficult.
160
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The LCOE of concentrating solar thermal power (CSP) fell 68%
from USD 0.340 per kWh to USD 0.108 per kWh between 2010
and 2020. These costs declined into the middle of the range of
the cost of new capacity from fossil fuels despite only several
projects being commissioned in recent years. Similar to solar PV,
the decline in the cost of electricity from CSP has been driven by
reductions in total installed costs. Yet, technology improvements
that have spurred improved economics of thermal energy
storage also have played a role in increasing capacity factors.
For bio-power, geothermal and hydropower, the installed
costs and capacity factors tend to be project specific. This,
coupled with different cost structures in different markets,
results in considerable year-to-year variability in global
weighted average values, particularly when deployment is
relatively thin and the share of different countries or regions
in new deployment varies significantly.
Between 2010 and 2020, the LCOE of bio-power projects was
volatile. By the end of the decade, it had remained at around
the same level as in 2010 at USD 0.076 per kWh – still at the
lower end of the cost of electricity from new fossil fuel-fired
projects.
For the same period, the LCOE of hydropower rose 16%, from
USD 0.038 per kWh to USD 0.044 per kWh. This was still
lower than the cheapest new fossil fuel-fired electricity option,
despite the 10% year-on-year increase in costs in 2020.
The global weighted average LCOE of geothermal has ranged
between USD 0.071 per kWh and USD 0.075 per kWh since
2016. The LCOE of newly commissioned plants ended up at
the lower end of this range in 2020 at USD 0.071 per kWh,
having declined 4% year-on-year.
20
20
U
S
D
/k
W
h
������
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�����
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0
0.1
0.4
0.2
0.3
0.057
0.381
�����
0.108
�����
0.084
�����
0.039
2010 20202010 20202010 20202010 2020
�����������
������� �������������������
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95th percentile
5th percentile
Average cost
-68 %- 85% -54% -48 %
Source: IRENA. See endnote 280 for this chapter.
FIGURE 37.
Global Levelised Costs of Electricity from Newly Commissioned Utility-scale Renewable Power Generation
Technologies, 2010 and 2020
161
Oorja – a company working at the intersection between agriculture and clean energy –
finances and installs distributed solar energy systems for farming purposes.
04
i See Sidebar 9 in GSR 2014 for more on the definition and conceptualisation
of DREA. Note that since 2018 the GSR has used the terminology “distributed
renewables for energy access” to distinguish from “distributed renewable
energy” (DRE) that has no link to providing energy access.
04
istributed renewables for energy accessi (DREA) play
an increasingly important role in delivering energy
access in developing countries, providing electricity
to between 5% and 10% of the population in several countries.1
(p See Figure 38.) These systems deliver a wide range of
services, including electricity for lighting, appliances, productive
uses, cooling, irrigation and water pumping, as well as energy for
cooking and heating.
Renewables-based electric power systems have proven
valuable in rural and peri-urban communities that are difficult
or costly to reach through grid electrification programmes.
Distributed renewables can provide affordable electricity access
that can be scaled up over time, powering not only households
but also businesses and community services, such as health
care and education. In recent years, solar photovoltaics (PV) has
become the technology of choice for off-grid electricity access,
but many other renewable access solutions are in place (for
example, mini-grids based on mini-hydropower or small wind
turbines to power households).
DISTRIBUTED
RENEWABLES FOR
ENERGY ACCESS
K E Y FA C T S
04
D
By the end of 2019, 90% of the global population
had access to electricity, although one-third
still had to cook with polluting fuels. Only 4%
of people living in rural sub-Saharan Africa had
access to clean cooking solutions.
Sales of off-grid solar systems fell 22% in 2020,
as businesses were affected by the effects of
the COVID-19 pandemic such as lockdowns,
supply chain issues and economic downturn.
Sales improved in the second half of the year.
Financing for off-grid solar companies increased
slightly by around 1%, with a much larger shift
from equity finance to debt and grant funding.
While many mini-grid projects were delayed, in
several countries new solar mini-grids were
commissioned specifically to power healthcare
facilities as an emergency response to COVID-19.
Overall, clean cooking continues to attract
only a fraction of the estimated funding needed
to achieve universal access; however, 25 clean
cooking companies were able to raise
USD 70 million in 2019, a 63% increase
compared to the 32 companies that raised
USD 43 million in 2018.
INTRODUCTION
163
i As per the guidelines of the World Health Organisation for indoor air quality linked to household fuel combustion, access to clean cooking facilities means access
to (and primary use of ) modern fuels and technologies, including natural gas, liquefied petroleum gas (LPG), electricity and biogas, or improved biomass cook
stoves that have considerably lower emissions and higher efficiencies than traditional three-stone fires for cooking.
ii Sustainable cooling includes efficient fans, air conditioners, refrigerators and other cold storage, ideally run on renewable electricity. In addition, it covers
measures to reduce the need for cooling through insulation, shading, reflectivity or ventilation.
Nepal
Rwanda
Mongolia
Kenya
Vanuatu
Fiji
Bangladesh
...connected to
hydropower mini-grids
Share of population...
...connected to
solar PV mini-grids
...using solar home systems
(11-50 W)
...using solar home systems
(>50 W)
2% 4% 6% 8% 10%0%
5.0%5.0%
6.1%6.1%
6.2%6.2%
6.8%6.8%
7.7%7.7%
9.0%9.0%
9.7%9.7%
RENEWABLES 2021 GLOBAL STATUS REPORT
Providing clean cookingi remains the biggest energy access
challenge and has seen the least progress in recent years. Many
people in the developing world have little choice than to cook
using traditional biomass systems, such as indoor open fires or
inefficient cook stoves. This results in high levels of household air
pollution with serious health impacts that fall disproportionately
on women.2 Clean cooking solutions exist but are not always
available or affordable.3 In off-grid settings, renewables such
as biogas and improved biomass cook stoves can play a role,
whereas in urban areas, electricity, liquefied petroleum gas (LPG)
and ethanol are most frequently used. While a switch to LPG
has improved health outcomes in many countries, clean cooking
ultimately needs to align with decarbonisation objectives.4
Cooling is a critical aspect of the provision of modern energy
services. Without access to sustainable coolingii, labour
productivity often remains low, agricultural produce goes to
waste, and health care is compromised (for example, vaccine
storage is not possible).5 In the rural areas of many developing
countries, lack of electricity access is the main reason for the
lack of cooling, whereas in urban areas the key factors are a poor
standard of housing and the intermittency of electricity supply.6
Distributed renewables can enable the use of cooling, especially
when combined with efficient appliances.
The coronavirus pandemic has led to renewed focus on the
importance of energy access. Evidence has emerged about the
links between long-term exposure to particulate matter from
air pollution and the risk of mortality from COVID-19.7 As the
crisis has progressed, the challenges of health care and vaccine
roll-out in the absence of reliable access to electricity have
become increasingly clear.8 (p See Box 8.) Renewables-based
energy systems have been highlighted as offering solutions to
these energy access problems, as well as providing economic
opportunities during the recovery phase.9
Note: Data in figure include solar home systems and mini-grids but exclude solar lights.
Source: See endnote 1 for this chapter.
FIGURE 38.
Top 7 Countries with the Highest Electricity Access Rate from Distributed Renewable Energy Solutions, 2019
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BOX 8. Energy Access, Health and COVID-19
A lack of access to modern energy services has implications
for health and the provision of medical services. Cooking
with polluting fuels has been linked to 4 million premature
deaths from illnesses such as chronic obstructive pulmonary
disease, and people with these diseases also are at higher
risk of severe cases of COVID-19. At the same time, a lack
of electricity access greatly restricts the available treatment
options for COVID-19 and other diseases. Crucial equipment
such as ventilators and oxygen generators require constant
electricity to function, but 60% of healthcare facilities in 46
middle- and low-income countries lack a reliable power
supply. In rural areas of sub-Saharan Africa, there is often no
electricity at all.
Reliable electricity is essential for vaccine storage, and
all of the COVID-19 vaccines that are approved or under
development require refrigeration, some as low as minus 70
degrees Celsius. Solar-powered vaccine refrigerators have
been available since the 1980s but often fail due to short
battery lifetimes or lack of regular maintenance. The global
vaccine alliance GAVI has been investing in solar direct-
drive refrigerators, which can store vaccines at constant
temperatures using ice banks instead of batteries. These
refrigerators have already been transformative in remote and
under-immunised areas. While they are not able to operate
at the very low temperatures that some COVID-19 vaccines
require, they are suitable for vaccines that only need to be
stored at ordinary fridge temperatures. Cold storage during
transport is also crucial, and innovations such as cool boxes
with solar-powered batteries can provide a solution for
transport to remote locations.
In response to the COVID-19 pandemic, many donor
programmes have allocated funds to support the
electrification of health services. For examples, Power
Africa, funded by the US Agency for International
Development (USAID), redirected programme funds to
provide USD 2.6 million in grants to off-grid companies for
electrification of rural and peri-urban health clinics.
Source: See endnote 8 for this chapter.
OVERVIEW OF ENERGY ACCESS
Globally, billions of people continue to lack access to modern
energy services. The biggest deficit is in clean cooking, with a
third of the world’s population, or 2.6 billion people, still relying
on polluting fuels (mostly traditional use of biomass) in 2019.10
The trend for electricity access has been more positive, with
90% of people globally having access to electricity in 2019, up
from 80% in 2010.11 However, modelling data for 2020 suggest
that this trend may have reversed due to the pandemic; in Africa,
2% fewer people had access to electricity in 2020.12
Progress in clean cooking remains slow and is focused on
relatively few countries. Although more than 1 billion people
gained access to clean cooking between 2010 and 2018, most
of this improvement was in Asia.13 In China and India, more
than 450 million people achieved clean cooking access, but
these two countries still account for nearly half of the global
population without access.14 Many countries in Latin America
and the Caribbean have high rates of access to clean cooking,
but notable exceptions include Haiti (only 6% access), Guatemala
(46%), Honduras and Nicaragua (both 55%).15
Sub-Saharan Africa continues to lag, with the number of people
gaining access to clean cooking not keeping up with population
growth.16 Large differences exist between rural and urban areas:
the average access rate in rural sub-Saharan Africa is only 4%,
whereas in urban areas it reaches 31%.17 Nigeria and Ethiopia
have the largest populations in the region without access to clean
cooking, a total of 275 million people in 2018.18 In Ethiopia, the
problem is primarily rural, whereas Nigeria has large urban and
rural deficits, with only 21% of its urban population able to access
clean cooking options.19
The assessment of clean
cooking progress is
constrained by data lim-
itations.20 In September
2020, new data on the
state of access to modern
energy cooking services
provided a more granular
assessment than was
available previously.21
These data suggest an even higher deficit in access, with an
estimated 4 billion people out of a sample of 5.3 billion people
across 71 countries lacking access to modern energy cooking
services in 2020.22 Only 12% of rural households had access to
such services, compared to 38% in urban areas.23 Sub-Saharan
Africa had the smallest share of the population with access,
at 10%, whereas Latin America and the Caribbean and East
Asia had the highest shares, at 56% and 36% respectively.24
(p See Figure 39.)
The electricity access deficit has improved for some years,
with the number of people lacking access decreasing from 801
million in 2018 to 759 million in 2019.25 However, large variations
persist among and within regions. Sub-Saharan Africa lags
the most, accounting for three-quarters (570 million) of people
globally without electricity access.26 Although access in urban
areas of sub-Saharan Africa reached 78% by 2019, access in
rural areas was only 25%.27 In some African countries – such
as Chad, Congo and Djibouti – rural electricity access rates are
as low as 1%.28
After seven consecutive
years of improvements,
the number of people
without access
to electricity in Africa
was estimated to have
increased in 2020.
165
No modern energy
cooking services
Transition
(Tiers 2 and 3)
Modern energy
cooking services
(Tier 4 and above)
South-East Asia
Latin America and
the Caribbean Sub-Saharan Africa South Asia East Asia
15 %15 %
17%17%
56 %56 %
10%10%
27%27%
29 %29 % 73 %73 % 19 %19 %
54 %54 %
21%21%
24 %24 %
55 %55 %
36 %36 %
31%31%
33 %33 %
South-east AsiaLatin America and
the Caribbean
Sub-Saharan Africa South Asia East Asia
15%15%
15%15%56%56%
17%17% 27%27%
29%29% 73%73% 19%19% 54%54%
21%21%
24%24% 55%55%
36%36%
31%31%
33%33%
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: Data based on a 71-country sample of 5.3 billion people representing 90% of lower- and lower-middle-income countries. Modern energy cooking
services refers to a household context that has met the standards of Tier 4 or higher across all six measurement attributes of the Multi-Tier Framework (MTF).
The MTF for cooking includes six attributes: exposure, efficiency, convenience, safety, affordability and fuel availability. To measure progress, each attribute
has six tiers, ranging from 0 to 5.
Source: ESMAP. See endnote 24 for this chapter.
FIGURE 39.
Population with Access to Modern Energy Cooking Services, by Region, 2020
In developing Asia, urban electricity access rates were 99% in
2019, with rural areas close behind at 94%.29 The access rate
in Cambodia increased the most, from 23% in 2010 to 75% in
2019.30 India and Indonesia also made big improvements, with
their rates rising from 67% (Indonesia) and 68% (India) in 2010
to near-universal access in 2019.31 The People’s Democratic
Republic of Korea was the only country in the region with
access rates below 50% (reaching only 26% in 2019).32
Central and South America reached very high average electricity
access rates (97%) in 2019.33 Haiti again was an exception, with
only 39% access overall and a mere 12% in rural areas.34 Bolivia,
Honduras and Panama had rural access rates below 80%.35
In the Middle East, Yemen remained the only country with a
significant electricity access deficit (53%) in 2019.36
In many countries, renewables (both on-grid and off-grid) have
played an important role in enabling greater electricity access,
especially in rural areas.37 However, in several countries the recent
successes have been based mostly on grid expansion using
fossil fuels. Indonesia’s move to universal energy access was
accompanied by a 155% increase in coal consumption, whereas
renewables have increased very little and contributed only 16% of
national electricity generation in 2019, up slightly since 2010.38 In
India, electricity access rose from 68% to almost 100% during this
period, while coal’s share of electricity generation increased from
67% to 71%.39 Bangladesh’s electricity access improvement (from
46% to 83%) was accompanied by large increases in natural gas
and oil generation.40
In Cambodia, on the other hand, hydropower has played a
major role in the country’s improved energy access. Electricity
access jumped from 23% in 2010 to 75% in 2019, while at the
same time hydropower generation increased from 32 gigawatt-
hours (GWh) to 4,370 GWh.41 Ethiopia’s more than doubling in
electricity access since 2010 also is based mostly on hydropower
(with some additional wind generation in recent years), whereas
in Kenya geothermal has played a big role.42 Electricity access in
Kenya increased from 18% in 2010 to 85% in 2019, and renewable
energy generation doubled over the same period, with its share
increasing from 69% to 82%.43
166
i Solar home systems are off-grid solar systems, rated at 11 watts (W) and above, that can be used for lighting and to power small electrical appliances.
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Although much of this renewables-focused expansion has been
driven by larger-scale, grid-connected systems, distributed
renewables increasingly play a role in providing electricity
access. In 2019, solar home systemsi supplied electricity to nearly
8 million people in Bangladesh, 4.4 million people in India and
3.4 million people in Kenya.44
Despite overall progress in electricity access, the trend is currently
measured based on household consumption levels, which masks
the ongoing lack of sufficient electricity for other activities, such
as productive uses that can allow people to get out of poverty.45
In addition, unreliable connections remain a significant problem.
Across Africa, only two-thirds of people connected to the grid
have electricity most of the time.46
Worldwide, the provision of cooling is affected by low, unreliable
or unaffordable electricity supply. In 2021, more than 1 billion
people – two-thirds of them in urban areas – were considered at
“high risk” because of no access to electricity, low incomes, and
other factors, with a lack of cooling threatening their health and
safety.47 In Asia, the highest risk populations are predominantly
the urban poor, whereas in sub-Saharan Africa the rural poor are
affected most.48 This reflects both different population dynamics
as well as varying levels of electricity access.49
Between 2020 and 2021, the number of people in rural areas at
high risk from a lack of cooling is estimated to have increased
faster than those at risk in urban areas, primarily due to the poverty
impact of the COVID-19 pandemic.50 India, Indonesia, Nigeria,
Bangladesh and Pakistan were among the top 10 countries for
both rural and urban poor at risk.51 India saw the fastest rise (13%)
in people at risk in rural areas, affecting an additional 14 million
people.52 China and India accounted for 36% of the growth in poor
urban settings, with an additional 6.8 million people at risk.53 In
rural areas, distributed renewables can provide cooling needs, from
simple fans connected to solar home systems to sophisticated
refrigeration units based on solar PV.
TECHNOLOGIES AND MARKETS
Renewables-based systems have enabled greater energy access
in many countries and often represent the most cost-effective
solution, especially when solar systems are used to provide
electricity in low-density rural areas.54 For access to clean
cooking, renewable options such as improved biomass stoves,
biogas, ethanol and solar cookers already make a contribution,
and renewables-enabled electric cooking has begun to play a
role as well.
Renewables deployment for energy access has grown strongly
in recent years, although the COVID-19 pandemic had an
impact in 2020.55 As lockdowns spread across countries, energy
access companies initially struggled to maintain operations, and
the resulting economic crisis affected people’s ability to make
payments for their existing power supply or to purchase new
systems.56 In August 2020, of 600 energy access companies
surveyed in 44 countries, 70% reported significant disruptions
from the pandemic, with 30% having to either pause all activity or
cease operations entirely.57 in several countries, however, the off-
grid sector was recognised as providing essential services and
was allowed some degree of continued operation.58 Investment
also picked up later in the year, and some sectors such as off-grid
solar proved surprisingly resilient.59
CLEAN COOKING
The global clean cooking market is dominated by liquefied
petroleum gas, with almost 2 billion people cooking with LPG.60
In the 71 countries with a clean cooking deficit in 2019, 37% of
people overall used LPG as a cooking fuel; however, LPG shares
exceeded 70% in urban areas of South Asia, South-East Asia
and Latin America and the Caribbean.61 Electricity also was used
increasingly for cooking, with its share more than doubling from
4% in 2010 to 10% in 2019.62
Renewables-based clean cooking solutions include improved
biomass cook stoves and more efficient fuels (for example,
pellets and briquettes), biogas, ethanol, solar cookers and electric
cooking linked to renewables-based electricity such as solar
or hydropower mini-grids. These options are being promoted
mostly through national and donor-funded programmes and
tend to involve some form of performance-based incentive or
A lack of access to
cooling threatens the
health and
safety
of at least 1 billion
people worldwide.
167
i An improved cook stove is a biomass stove that is more efficient and emits less emissions than a traditional stove or three-stone fire. An array of diverse
technologies exist, which vary considerably in terms of efficiency and emissions.
2015 2020
Cubic metres per capita
10
8
6
4
2
0
0.4
0.3
0.2
0.1
0
0.5
0.5
Vietnam
Nepal
China
India
Rwanda
Bangladesh
Kenya
Burkina Faso
Senegal
Ethiopia
Uganda
Tanzania
RENEWABLES 2021 GLOBAL STATUS REPORT
subsidy.63 Even where clean cooking solutions are prevalent,
households commonly practice “fuel stacking” and continue
to use some traditional cooking methods, often to meet socio-
cultural expectations.64
With traditional uses of biomass still dominant in cooking in
most of the developing world, improved biomass cook stovesi
have been a focus of donor, non-governmental and government
programmes for several decades.65 Of the many types of
improved cook stoves, very few meet World Health Organization
guidelines for emissions.66 However, no comprehensive data
are available on distribution of the stoves, and data for 2020 are
particularly scarce.
Recent programmes include the Bangladesh Improved Cookstove
Programme, initiated jointly by Bangladesh’s Infrastructure
Development Company Limited (IDCOL) and the World Bank
in 2013; by the end of 2020, the programme had distributed
2.4 million improved cook stoves, with a target of 5 million by the
end of 2023.67 On a smaller scale, in Kenya, the Results-Based
Finance programme of the Energising Development (EnDev)
multi-donor partnership delivered around 80,000 improved
biomass and ethanol cook stoves (as well as 21,000 LPG stoves)
between 2016 and 2019, reaching half a million people.68 A new
phase starting in January 2020 aimed to deliver 40,000 additional
highly performing cook stoves by March 2021.69
Biogas can be a solution in areas where agricultural residues,
animal or human wastes are locally available.70 An estimated
125 million people use biogas for cooking globally, a figure that
has been broadly constant over the last decade.71 Most people
cooking with biogas live in Asia (99.7%), with the bulk of the
production per capita occurring in China, Nepal, Vietnam, India
and Bangladesh.72 (p See Figure 40.)
Source: IRENA. See endnote 72 for this chapter.
FIGURE 40.
Per Capita Production of Biogas for Cooking, Selected Countries, 2015 and 2020
168
i Pico solar systems/products refer to off-grid systems rated up to 10 W, used
primarily for basic lighting and mobile phone charging.
ii Affiliated products are those sold by companies that are connected to any of the partner organisations involved in the semi-annual GOGLA sales data
reporting process.
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In Africa, production
remains small but
increased 28% between
2015 and 2020.73 This
occurred mostly in
Rwanda, Senegal and
the five countries covered
by the Africa Biogas
Partnership Programme
(Burkina Faso, Ethiopia,
Kenya, Tanzania and
Uganda). More than
38,000 biogas digesters were installed during Phase II of the
programme, implemented by Hivos and SNV between 2014 and
2019 with funding from EnDev and the Netherlands Directorate-
General for International Cooperation.74 Although well below the
targeted 100,000 installations, the programme was successful
in establishing markets for private sector biogas companies.75
Funding was approved for a follow-up biogas programme funded
by the Dutch government through EnDev, expected to start
during 2021.76
Electric cooking is already cost effective for many people
connected to national grids or off-grid small-scale hydropower,
and battery-supported electric cooking linked to solar-hybrid
mini-grids is expected to become cost effective by 2025.77 To
achieve this, the focus has been on linking renewables-based
solutions to efficient cooking appliances such as electric pressure
cookers (which greatly reduce the cost of electric cooking
compared to traditional electric hotplates) and on reducing
the demand on the system during peak times.78 However, high
upfront equipment costs remain a challenge, which could be
addressed by “Pay-As-You-Go” (PAYGo) providers adding these
cookers to the services they offer.79
The electric cooking market is in the early stages of development,
especially for the direct current appliances required for off-grid
settings.80 In 2020, the Global LEAP Awards launched the first-
ever competition for highly energy-efficient electric pressure
cookers suitable for use in both off-grid and weak-grid settings.81
Solar cookers (such as parabolic cookers and solar ovens) offer
another clean cooking solution. Globally, more than 4 million
solar cookers had been distributed by early 2021, providing clean
cooking solutions to an estimated 14.3 million people.82
DISTRIBUTED RENEWABLES FOR ELECTRICIT Y ACCESS
Pico solari and solar home systems have played a growing
role in the provision of energy access, with more than 180 million
units sold over the last decade.83 Apart from bringing electricity
to the homes of over 100 million people, these units allow some
2.6 million people to run a business.84 During the COVID-19
pandemic, many countries officially designated off-grid solar
companies as “essential services”, enabling them to operate at
least partly during lockdowns.85
The global market for off-grid solar systems grew a record 13%
in 2019, the highest increase of the preceding five-year period.86
Similar, if not higher, expansion had been expected by the industry
in 2020, but the pandemic led to a significant slowdown.87 Sales
of affiliatedii systems fell 22% compared to 2019, with cash sales
(especially of solar lanterns) experiencing the biggest reductions
(30%), while PAYGo sales declined only 1.7%.88 The business
operations of off-grid solar companies were disrupted because
of lockdown measures that restricted the movement of goods
and sales staff, as well as supply chain issues.89 While businesses
were affected mainly during the early months of the crisis, two-
thirds of off-grid companies still reported lower sales in the
second half of 2020 compared to 2019.90
Around 6.6 million affiliated off-grid lighting products were sold
during 2020.91 Portable solar lanterns (up to 3 W) accounted for
64% of this, with another 18% of sales for larger light systems
of up to 10 W.92 In addition, 1.2 million solar home systems were
sold, with all but 49,000 systems having an output smaller
than 100 W.93 Appliance sales linked to off-grid solar products
also decreased, with a total of 946,000 appliances sold in 2020
compared to almost 1.2 million in 2020.94 Television sales proved
more resilient than fan sales, with decreases of 3% and 31%
While most of the 125 million
people who cook with
biogas live in Asia,
African biogas
production has increased
28% in the last five years.
169
Million units
2019
2020
0
1
2
3
4
5
W
es
t A
fri
ca
Ea
st
Af
ric
a
Ce
nt
ra
l A
fri
ca
So
ut
he
rn
A
fri
ca
So
ut
h
As
ia
Ea
st
As
ia
&
Pa
cif
ic
M
idd
le
Ea
st
&
No
rth
A
fri
ca
La
tin
A
m
er
ica
&
Ca
rib
be
an
Change in %
-10%
-51%
+9%
– 41% – 44% – 53%+22% +6%
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: Affiliated products are those sold by companies that are connected to any of the partner organisations involved in the semi-annual GOGLA sales data
reporting process, including GOGLA members and companies selling products that meet Lighting Global Quality Standards.
Source: GOGLA. See endnote 99 for this chapter.
FIGURE 41.
Sales Volumes of Affiliated Off-Grid Solar Systems, Selected Regions, 2019 and 2020
respectively.95 Solar water pump sales plunged more than 60%,
although this was due at least in part to bulk procurement in 2019,
which did not happen in 2020.96
Regionally, the biggest reduction in off-grid solar product sales
in 2020 occurred in South Asia, with a 51% drop compared to
2019.97 East Africa, which remained by far the largest market,
saw a dip of 10% (mostly in cash sales), whereas sales in Central
Africa and West Africa increased despite the pandemic, up 22%
and 9% respectively.98 West Africa experienced a small reduction
(3.6%) in cash sales, but PAYGo sales increased 23%, while in
Central Africa both segments increased (up 8% for cash sales
and 71% for PAYGo sales).99 (p See Figure 41.)
Kenya, India, Ethiopia, Uganda and Nigeria were the top five
off-grid solar markets globally by sales volumes.100 The largest
reductions occurred in India, where sales dropped 54% in 2020
(the country had already experienced a 31% reduction in 2019).101
In Ethiopia, where off-grid solar sales had more than doubled in
2019 to just over 1 million products, sales dropped 40% in 2020.102
Nigeria was the only one of the top five markets where sales
increased in 2020, although by less than 1% (compared to a 5%
increase in 2019).103
In addition to stand-alone solar systems, renewables-based
mini-grids are recognised increasingly as an important facilitator
of energy access.104 Of the identified 5,544 mini-grids operating
in energy access settings in March 2020 (with a total capacity
of 2.37 GW), 87% were renewables-based.105 Solar PV has been
the fastest growing mini-grid technology, incorporated into
55% of mini-grids in 2019 compared to only 10% in 2009.106
(p See Figure 42.)
Mini-grid development used to be driven by utilities and non-
governmental organisations (NGOs), but in recent years
private developers also have entered the space.107 In 12 sub-
Saharan African countries with high electricity access deficits,
renewables-based mini-grid connections installed by private
developers increased from just 2,000 in 2016 to more than 41,000
in 2019, mostly in East Africa.108 Over 200,000 people, as well as
businesses, schools and health facilities, have been connected
through these mini-grids.109 The rapid growth has been linked to
policy and regulatory changes, as well as to donor programmes
that have provided incentives to developers.110
While most mini-grid developers are small-scale companies or
start-ups, some are beginning to reach scale; in late 2020, Husk
Power became the first company globally to install 100 community
mini-grids, which also serve 5,000 business customers.111 In recent
years, large and international corporations such as EDF, Enel,
ENGIE, Iberdrola, Shell and Tokyo Electric also have joined the
mini-grid market, generally by taking over or investing in smaller
170
Solar PV 50%
Solar hybrid13%
Biomass3.2%
Other
2%
Hydropower
21%
Diesel / Heavy fuel oil
11%
Solar PV
50%
Solar hybrid13%
Biomass
3.2%
Other
2%
Hydropower21%
Diesel / Heavy fuel oil11%
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Note: Figure refers to currently operational (functioning) mini-grids in energy access settings. Solar hybrid mini-grids combine solar PV with other power
sources such has hydropower or wind power but most frequently with diesel generators. Where totals do not add up, the difference is due to rounding.
Source: Mini-Grids Partnership. See endnote 106 for this chapter.
FIGURE 42 .
Shares of Installed Mini-Grids by Technology, March 2020
companies.112 Although private sector interest in mini-grids has
grown, most developers have relied on public funding such as
grants or results-based financing from donors, although some
form of subsidy is also common for grid-based electricity.113
In Africa, the COVID-19 pandemic impacted the mini-grid sector
more than the rest of the solar industry in 2020 due to complex
logistics and difficulty accessing remote areas.114 Many projects
under development or being tendered were slowed or put on
hold.115 However, some progress occurred. Nigeria, which has one
of the largest mini-grid support programmes under its National
Electrification Project, aims to electrify 300,000 households and
30,000 local enterprises through private sector-driven solar-
hybrid mini-grids by 2023.116 With funding from the World Bank
and the African Development Bank, it offers minimum subsidy
tenders and performance-based grants.117 In 2020, Nigeria’s Rural
Electrification Authority (REA) commissioned several installations
under the project, including two solar hybrid mini-grids with a
combined capacity of 135 kW developed by Renewvia Energy
and a 234 kW solar hybrid mini-grid installed by local developer
GVE Projects Limited that will power nearly 2,000 households.118
Nigeria’s REA also developed several solar mini-grids for use
at hospitals and other healthcare facilities as an emergency
response to COVID-19.119 Health facilities were a focus of
several other donor-driven mini-grid initiatives as well. Power
Africa, funded by USAID, redirected USD 4.1 million in grants
to off-grid companies in 2020 for rural and peri-urban health
clinic electrification, including through mini-grids.120 In Lesotho,
OnePower together with SustainSolar aim to supply seven
containerised solar mini-grids under Power Africa to electrify
several clinics.121 Recent mini-grid activity has occurred in several
countries of francophone West Africa. Benin in 2020 selected
11 companies to construct solar mini-grids serving 128 localities
under its Off-Grid Clean Energy Facility.122 In early 2021, Togo’s
Rural Electrification and Renewable Energy Agency announced
the first 129 localities to be electrified by its mini-grid programme,
and Senegal’s Rural Electrification Agency launched a tender for
the electrification of 117 villages through solar mini-grids.123
In East Africa, Kenya has been the most active mini-grid market
with almost 200 sites in operation in 2019.124 Renewvia Energy
commissioned another three solar mini grids in 2020, with a total
capacity of 87.6 kW in Kenya’s Turkana and Marsabit counties,
serving two communities and a refugee camp in an electrification
project supported through the EnDev RBF facility.125 Meanwhile
Kenya Power launched a tendering process in early 2021 to
hybridise 23 older diesel mini-grids, mostly with solar.126 In
Central Africa, a 1.3 MW solar-hybrid mini-grid installed by Nuru
in the city of Goma, in the Democratic Republic of Congo, was
put into service in February 2020.127
In Asia, Bangladesh’s 170 kW BREL solar mini-grid project came
online in early 2020, financed by IDCOL as part of its solar mini-
grids initiative for islands and other remote areas.128 This brought
the total under this initiative to 27 projects, with a combined
capacity of 5.6 MW.129 In the Americas, in late 2020, the national
Rural Electrification Program (PERMER) in Argentina’s remote
Rio Negro province repowered two mini-grids (22 kW and
40 kW), which previously ran on LPG, with solar PV and wind
power as well as storage; this increased electricity access for
100 families from 16 to 24 hours.130
171
RENEWABLES 2021 GLOBAL STATUS REPORT
BUSINESS MODEL INNOVATIONS
In most developing countries, grid-based electricity access is
the domain of state-owned electric utilities. In contrast, off-grid
renewables are much more reliant on the private sector and
on innovative business models. Business models vary greatly
among off-grid renewables providers. Over the last decade,
PAYGo systems have enabled energy access for millions of off-
grid consumers, mostly through solar home systems, although
PAYGo also has made inroads into productive uses such as
solar water pumping and even clean cooking. PAYGo companies
typically provide either a “lease-to-own” or a “usage-based”
payment model.131
In 2020, 84% of affiliated solar home systems were sold on a
PAYGo basis.132 Traditionally, many PAYGo companies providing
solar home systems focused on basic services such as lighting
and phone charging, or possibly a small television. Increasingly,
companies have expanded their offerings to bigger systems
that power a broader range of appliances, such as fans and
refrigerators, as well as bundling in other services.
For example, the product range of M-Kopa, which operates in
Kenya, Nigeria and Uganda, includes three sizes of solar home
systems, solar fridges for small businesses and smartphones.
For customers who have made reliable payments on a PAYGo
product, the company also offers services such as clean biomass
cook stoves, entertainment packages and even financial services
such as loans (for example, for hospital stays).133 Bboxx (UK) also
has branched out into home entertainment and joined forces in
2020 with the French media company Canal+ to sell televisions
and decoders with its solar home systems in Togo and the
Democratic Republic of the Congo.134
While many companies have offered higher-value services for
better-off customer segments, affordability remains a major
problem for many communities, especially in more-remote rural
areas with high levels of poverty. In August 2020, Bboxx launched
a new product (bPower20) – a package of 20 W solar panels
and new improved batteries – targeted specifically at low-income
rural households; with it, the company aims to reach a wider
segment of the global market.135 The initial target markets are the
Democratic Republic of the Congo, Kenya, Rwanda and Togo,
but Bboxx aims to expand into further markets in 2021.136
Pico solar and solar home systems remain the most common
renewables-based electricity access solutions using PAYGo
models, with 2.2 million affiliated systems sold worldwide in
2020.137 In Rwanda, a new pilot PAYGo solution was launched
in October 2020 when ENGIE Energy Access teamed up with
OffGridBox to deploy containerised solar PAYGo.138 This supplies
clean drinking water, electricity for recharging and Wi-Fi from
solar-powered containers equipped with electricity storage,
water purification systems and a WI-FI hotspot.139 Customers get
a battery, LED (light-emitting diode) lights, phone chargers and
a water canister and pay a small fee for recharging and refilling
from the system.140
Beyond households, a number of PAYGo solutions exist in
agriculture, particularly for solar irrigation. SunCulture, which
already offered solar irrigation kits on a “pay-as-you-grow” basis
in Kenya, announced a new partnership in December 2020 with
Bboxx and EDF to bring solar irrigation to 5,000 farmers in Togo
using the PAYGo model.141 The government of Togo will provide
a subsidy to halve the costs of the systems to make them more
affordable for farmers.142
PAYGo also has advanced in the clean cooking sector, for
example for ethanol, a renewable cooking fuel that is relatively
easy to distribute.143 The traditional model has been centralised
bottling and bulk distribution, but in 2019 KOKO Networks
launched a new decentralised distribution model with the
fuel infrastructure company Vivo Energy in Nairobi, Kenya.144
Customers pay digitally for the fuel, which is then dispensed by
700 ethanol vending machines (Koko Points) in corner shops
across the city.145 KOKO Networks also sells its own ethanol
stoves, and by August 2020 it was serving 50,000 households.146
In June 2020, the company was rewarded a results-based
finance project for a further 250,000 connections under the
Dutch SDG 7 programme.147
172
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Most clean cooking PAYGo is dominated by small LPG start-ups
– such as KopaGas and PayGo Energy – but in July 2020 ENGIE
Africa, a major player, announced a new partnership with the
PAYGo gas company PayGas in South Africa to support two new
LPG refilling stations that can service 4,000 homes.148 PayGas
plans to scale its operations to other African countries.149
Similar to the solar irrigation sector, public funding is often
needed to support private sector business models that operate
in the clean cooking sector. To drive further innovation in clean
cooking, in 2020 the Clean Cooking Alliance launched the
Cooking Industry Catalyst, which aims to demonstrate new
viable and scalable business models.150
Business models for mini-grids for rural electrification vary,
with different combinations and approaches to ownership and
operation, service delivery and billing. Many mini-grids are owned
by national utilities, whereas others are under private, community
or hybrid ownership.151 There is no proven business model that
works everywhere, and as of late 2020 no private mini-grid
company was profitable.152 In general, revenues per customer
remain low, and low consumption is a systemic problem.153
Expanding consumption is critical to the success of mini-grid
business models, with many companies focusing on developing
productive uses, which also are increasingly supported through
donor funding.
In 2020, the Energy and Environment Partnership Trust Fund
(EEP Africa) approved funding to support several innovative
mini-grid business models that include productive uses. In
Rwanda, EEP is supporting East African Power in developing
a hydropower plant and mini-grid that will service not only
households but also community buildings and an agricultural
centre of excellence, as well as a women’s aquaculture business
to improve socio-economic development.154 In Uganda, ENGIE
Equatorial is receiving EEP support to deploy four solar-hybrid
mini-grids, with an industrial park as an anchor client.155 The
project also includes an incubation programme that enables local
women entrepreneurs to access asset financing for productive
use appliances.156
Some companies involve communities to identify needs and
how to grow demand. Miowna SA, a joint venture of PowerGen
and Sunkofa Energy, won a competitive tender run by the Benin
Off-Grid Clean Energy Facility in 2020 to electrify 40 villages in
the country.157 Miowna worked with communities and other local
stakeholders to identify innovative value propositions through
productive uses that will help increase local incomes and make
the mini-grids viable.158
FINANCING FOR RENEWABLES-
BASED ENERGY ACCESS
With less than a decade left before 2030, even prior to the COVID-
19 pandemic the total investment in energy access was far below
what has been estimated as needed to achieve SDG 7.159 The
energy access finance that was available mostly bypassed the
countries with the greatest access deficit, and very little of the
already small amount of finance was dedicated specifically to
renewables-based energy access systems.160
Clean cooking suffers from the largest investment gap overall
and remains well below the estimated annual USD 4.5 billion
required to achieve universal access by 2030.161 However, positive
developments have occurred, with overall finance for clean
cooking tripling from USD 48 million in 2017 to USD 131 million
in 2018 (most recent data available).162 Most clean cooking
funding comes from the public sector, with international donor
and development finance institutions providing two-thirds of
financing in 2018, nearly half of it as grants.163 The public sector is
also very active in the delivery of the funded activities, with 44%
of the funding passing through public channels (compared to
only 14% for electricity access).164 Private finance plays a relatively
small role, with just under one-quarter of funding in 2018, while
carbon markets provided another 16%.165
Finance for electricity access in the 20 countries with the
highest access deficit increased 25% between 2017 and 2018 to
reach USD 43.6 billion.166 In some countries, more than 95% of
electricity finance went to grid-connected renewables, mini-grids
and off-grid solutions; however, these accounted for only 14% of
the total energy access funding in 2018, and, overall, renewables-
based systems received only around 1.5% of the total.167
Unlike in clean cooking, private investment has been a key driver
of off-grid electricity access, accounting for 78% of funding in
2019.168 While public financing halved compared to the previous
year, major increases in funding occurred from several types of
private investors. Private equity, venture capital, infrastructure
fund and institutional investors increased their off-grid funding
from USD 193 million in 2018 to USD 290 million in 2019, while
corporations more than tripled their investment during this
period, from USD 22 million to USD 68 million.169 The latter
focused mostly on East Africa and South-East Asia.170 (p See
Figure 43.)
More than
2 million solar
products
were sold on a pay-as-
you-go basis in 2020.
173
USD million
Others
Undisclosed
Government agencies and
intergovernmental institutions
Commercial finance institutions
Individuals
Corporations and business
associations
Development finance institutions
Institutional investors
Private equity, venture capital
and infrastructure funds
460
429
391
300
243
101
21
500
400
300
200
100
0
2013 2014 2015 2016 2017 2018 2019
RENEWABLES 2021 GLOBAL STATUS REPORT
Source: IRENA and CPI. See endnote 170 for this chapter.
FIGURE 43.
Annual Commitments to Off-Grid Renewable Energy, by Type of Investor, 2013-2019
The COVID-19 pandemic affected finance flows to the energy
access sector, particularly mini-grids.171 Some attempts have
been made to help companies struggling with these effects. The
Energy Access Relief Fund was established with the aim of raising
USD 100 million to provide unsecured, low-cost, subsidised
loans, with funding from donors including the Green Climate
Fund.172 In late 2020, the African Development Bank launched
the USD 50 million COVID-19 Off-Grid Recovery Platform to
provide relief and recovery capital to energy access businesses.173
Additionally, the Shine Campaign made available grants of
between USD 3,000 and USD 10,000 to smaller players.174
CLEAN COOKING SECTOR FINANCING
In 2019, 25 clean cooking companies were able to raise
USD 70 million, a 63% increase compared to the 32 companies
that raised USD 43 million in 2018.175 Around three-quarters
of the funding went to companies offering renewables-based
solutions, with biomass stoves and biogas accounting for 25%
and 19% respectively of the capital raised.176
In 2020 and early 2021, several renewables-focused clean cooking
companies managed to raise new capital. Improved cook stove
manufacturer BURN (Kenya) partnered with the crowdfunding
platform Bettervest (Germany) in an attempt to raise more than
EUR 1 million (USD 1.2 million) in working capital.177 Bettervest
also raised over EUR 300,000 (USD 360,000) for Kenyan
biomass briquette company Sanergy in early 2021.178 One of
the companies involved in the African Biogas Partnership
Investment in the
largest clean
cooking
companies
increased 63% in 2019.
174
USD million
Others
Undisclosed
Government agencies and
intergovernmental institutions
Commercial finance institutions
Individuals
Corporations and business
associations
Development finance institutions
Institutional investors
Private equity, venture capital
and infrastructure funds
460
429
391
300
243
101
21
500
400
300
200
100
0
2013 2014 2015 2016 2017 2018 2019
%
Debt
Equity
Grant
0
10
20
30
40
50
60
70
80
90
100
2012 2013 2014 2015 2016 2017 2018 2019 2020
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Programme, Sistema.bio, received a USD 1.35 million loan facility
from the Dutch Development Bank FMO in late 2020 to scale up
its operations in Kenya.179 In addition, Connected Energy, which
offers a smart meter specifically for biogas systems, attracted
USD 1.25 million in funding.180
Although sales revenues provided 80% of the total revenues of
clean cooking companies in 2019, this was being supplemented
by grants and results-based finance, as well as carbon offset
revenues.181 The latter experienced a five-fold increase between
2018 and 2019 to USD 5.2 million, with almost all of the carbon
offset funding going to biomass stove manufacturers.182
OFF-GRID ELECTRICIT Y ACCESS SECTOR FINANCING
The COVID-19 pandemic impacted financing for off-grid
companies in 2020, but not to the extent that was initially
feared. In the case of off-grid solar, the overall volume of funding
for affiliated companies was up slightly at USD 316 million
compared to USD 312 million in 2019.183 The main impact
has been a reduction in equity funding of 46%, due mainly
to problems in carrying out on-the-ground diligence, which
made it difficult to complete equity transactions.184 Most of
this reduction was due to strategic corporate deals falling
from USD 76 million in 2019 to USD 8.5 million in 2020.185 The
reduction in equity funding was compensated by an increase
in both debt and grant funding, mostly from governments and
development finance institutions.186 (p See Figure 44.)
Much of the 2020 off-grid solar funding flowed to Africa. Lumos
received USD 35 million in financing from the US International
Development Finance Corporation to further expand in
Nigeria.187 Bboxx secured a USD 4 million loan from the Off-
Grid Energy Access Fund of the Energy Inclusion Facility to
expand in the Democratic Republic of the Congo.188 Oolu closed
a USD 8.5 million Series B investment round involving several
impact investors to further develop its operations in West Africa.189
UpOwa signed a EUR 3 million (USD 3.6 million) debt facility
with EDFI ElectriFI to enable expansion in Cameroon.190 Easy
Solar, which operates in Sierra Leone and Liberia, announced
a USD 5 million round of funding including a USD 3 million
Series A Equity led by global impact investor Acumen and
Dutch development FMO, in addition to a USD 2 million debt
facility from investment platform Trine.191 Fenix International,
a subsidiary of ENGIE, secured a USD 12.5 million loan from
the European Investment Bank to support the deployment of
240,000 solar home systems in Uganda.192
Energy+, a less well-established Malian-owned and managed off-
grid solar company, secured USD 1 million through a combination
of debt, equity and grant financing from Venturebuilder, Cordaid
and the US African Development Foundation.193 Easy Solar,
together with Altech of the Democratic Republic of the Congo
and Deevabits of Kenya, also received unspecified loans from
the newly established Sima Angaza Distributor Finance Fund,
which aims to provide capital for the last-mile distribution
sector.194 In addition to the finance provided to companies
Note: The data cover financing for off-grid solar such as solar home systems, solar lanterns and solar-powered appliances (e.g., water pumps) but exclude
solar mini-grids.
Source: GOGLA. See endnote 186 for this chapter.
FIGURE 44.
Shares of Off-Grid Solar Financing, by Type of Funding, 2012-2020
175
RENEWABLES 2021 GLOBAL STATUS REPORT
focused on household solar systems, solar-powered irrigation
supplier SunCulture closed a Series A investment round of
USD 14 million in late 2020; investors included Energy Access
Ventures, Électricité de France, Acumen Capital Partners and
Dream Project Incubators.195
Crowdfunding continued to play an important role for off-grid solar
companies. In the first half of 2020, crowdfunding transactions
were mostly refinancing of earlier loans.196 For example, the
initial response of UK crowdfunding platform Energise Africa to
the pandemic focused on refinancing the existing debt of seven
companies, raising just over GBP 1.5 million (USD 2.0 million).197
By late 2020, the platform had not only resumed its normal
lending activities but also launched its first funding campaigns
both for solar projects in the small and medium-sized enterprise
sector and outside of Africa, raising a total of GBP 1.9 million
(USD 2.6 million) for Candi Solar to provide solar energy to such
enterprises in South Africa and India.198
While funding for the off-grid solar sector has held up during
the COVID crisis, funding for the mini-grid sector dropped by
almost a third, with the biggest reduction occurring in equity
finance.199 However, by late 2020 some activity had resumed,
with, for example, Dutch development bank FMO investing
USD 5 million in Husk Power in October 2020.200 Winch Energy
in early 2021 mobilised USD 16 million for 49 mini-grids in Sierra
Leone and Uganda through NEoT Off-grid Africa, a platform
developed by Électricité de France, Mitsubishi and Meridiam.201
The funding includes some grants through development
aid from Germany, the European Union (EU) and the United
Kingdom.202 Also in early 2021, Nigerian start-up Havenhill
Synergy obtained USD 4.6 million local currency funding
for 22 solar mini-grids from the Chapel Hill Denham Nigeria
Infrastructure Debt Fund.203
Funding in 2020 was not just limited to companies supplying
renewables equipment but also those providing enabling
services. For example, Angaza, which sells software for solar
PAYGo solutions, raised USD 13.5 million from East African
energy impact fund KawiSafi Ventures and Total Carbon
Neutrality Ventures, the venture capital arm of energy company
Total (France).204 Total was also one of several investors providing
USD 12 million Series A financing to SparkMeter, a provider of
grid management services to hard-to-reach communities.205
Acumen invested an unspecified amount in Solaris Offgrid, a
social enterprise providing PAYGo software.206
A new innovative financing instrument was launched in early 2021
by South Pole and Positive.Capital Partners with the support of
several foundations.207
The D-REC Initiative
will provide funding
for renewables-based
energy access projects
by selling third-party-
certified renewable energy
certificates to companies
interested in going beyond
their corporate renewables
commitments.208
PUBLIC FUNDING AND INITIATIVES
While the private sector has been driving much of electricity
access funding, development finance institutions (DFIs), bilateral
donors and other funders such as philanthropic foundations
continue to commit funding to energy access. This funding takes
various forms including grants, results-based finance, guarantees,
loans and other debt facilities and can be used to support
governments, development partners such as NGOs, or private
sector companies in implementing energy access programmes.
Off-grid energy access funding by DFIs has consistently
lagged behind funding for on-grid electrification.209 In 2019,
DFIs committed an estimated USD 1 billion – around 12% of
their total energy funding commitments – to off-grid electricity
access.210 DFI funding for clean cooking, meanwhile, totalled only
USD 78 million in 2018, even though the lack of access to clean
cooking affects many more people than the lack of electricity
access.211 In 2020, most of the significant new energy access
commitments from DFIs were again focused on electricity
access, with a few exceptions as set out below.
The World Bank approved USD 150 million in financing to improve
access to modern energy for households, enterprises and public
institutions in Rwanda, both on- and off-grid.212 Although the
majority of the funding will go to electricity access, the project
includes the Bank’s largest clean cooking commitment in Africa,
and the first project co-financed by the recently launched Clean
Cooking Fund (CCF).213 The CCF will provide USD 20 million for
clean cooking, with USD 10 million as grants and USD 10 million
as loans.214 The project targets 2.15 million people, leveraging
an additional USD 30 million in public and private sector
investments.215
In Burundi, the World Bank agreed to provide USD 100 million
in grants for the Solar Energy in Local Communities programme
(SOLEIL), which will double the rate of electricity access in the
country, with a focus on rural areas.216 The World Bank also
approved USD 52.9 million in financing for the Lesotho Renewable
Energy and Energy Access Project, aimed at expanding electricity
access in remote areas of the country.217 In Haiti, the World Bank
approved USD 6.9 million additional financing for the Haiti:
The Green Climate Fund
committed
USD 300 million
to renewables-based
energy access projects
in 2020.
176
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Renewable Energy for All project, specifically to provide
renewable energy solutions for at least four priority healthcare
facilities involved in the response to COVID-19.218
The African Development Bank (AfDB) made its first significant
investment in clean cooking in late 2020 with a USD 5 million
commitment to the SPARK+ Africa Fund, with another
USD 10 million for the Fund coming from the European
Commission.219 SPARK+ Africa, which targets total investment of
USD 50-70 million, is a new impact investment fund launched by
Enabling Qapital and the Clean Cooking Alliance to provide debt
and equity financing to enterprises that manufacture, distribute
and finance clean cooking solutions across sub-Saharan Africa.220
The AfDB, jointly with the European Commission, KfW, the Clean
Technology Fund, Norfund and other investors, also committed a
total of USD 160 million to the first close of the Facility for Energy
Inclusion, a fund to improve electricity access across Africa
through small-scale renewable energy and mini-grid projects.221
To further support mini-grids, the AfDB approved a USD 7 million
grant from the Sustainable Energy Fund for Africa (SEFA) for
technical assistance.222
The European Union provided a EUR 62 million (USD 76 million)
de-risking guarantee to COFIDES, the Spanish development
finance institution, and AECID, the Spanish development
agency, for their renewable energy support programme for rural
sub-Saharan Africa.223 The guarantee will help generate a total
investment of more than EUR 800 million (USD 983 million) and
is expected to provide electricity to at least 180,000 new people
in rural areas.224 A EUR 62 million (USD 76 million) guarantee
agreement with France’s Agence Française de Développement
in partnership with Italy’s Cassa Depositi e Prestiti is expected to
provide electricity access to another more than 1 million people.225
Sweden’s Beyond the Grid Fund for Africa (BGFA) expanded to
Uganda, with initial funding of EUR 11.8 million (USD 14.5 million)
for a six-year programme.226 The Fund now operates in five
countries, with total funding of EUR 59 million (USD 73 million).227
Sweden’s SIDA together with the Nordic Environment Finance
Corporation announced in September 2020 the allocation of
SEK 5 million (USD 0.6 million) for a new Scaling of Clean Cooking
Solutions programme in Zambia. The aim is to accelerate the use
of higher-tier cooking solutions.228
Climate finance has become a significant funding source for
energy access, and the Green Climate Fund (GCF) approved
three projects in 2020 for just over USD 300 million.229 Although
the GCF provided funding in 2019 for clean cooking projects
in Bangladesh, Kenya and Senegal, in 2020 the main energy
access projects were focused on mini-grids. They included: a
USD 45.7 million project to develop 22 community-scale solar
plus battery storage micro-grids in southern Haiti to provide an
alternative to diesel generators; a USD 235.5 million project in
Senegal to mobilise private sector participation in solar-powered
mini-grids for 1,000 remote villages; and USD 21.4 million to
kickstart a renewable energy market in rural Afghanistan and lay
the groundwork for developing a mini-grid sector (including three
solar mini-grids).230 In addition, the GCF approved USD 60 million
for equity and co-financing of the Energy Access Relief Fund,
open to both electricity and clean cooking enterprises.231
PHIL ANTHROPIC AND INNOVATION FUNDING
Significant announce ments in philanthropic funding in 2020
included the Rockefeller Foundation committing USD 1 billion
over a three-year period to catalyse a green recovery from
COVID-19, building on Rockefeller’s existing work on mini-
grids.232 A key focal area is scaling distributed renewable energy
across developing countries, in addition to equitable access to
COVID-19 tests and vaccines.233
The IKEA Foundation, jointly with UK Aid, launched the Powering
Renewable Energy Opportunities (PREO) programme in June
2020 to support productive use of energy projects in rural areas,
with a focus on grants of up to EUR 300,000 (USD 368,473)
for action learning and supply chain innovation.234 The aim is to
deliver a project portfolio of EUR 20 million (USD 24.6 million).235
Several foundations (Rockefeller Foundation, Shell Foundation
and Good Energies) supported Sustainable Energy for All
(SEforALL) in establishing the Universal Energy Facility to
provide results-based finance. Other donors and partners
include UK Aid, Power Africa, Carbon Trust and the
Africa Minigrid Developers Association. In the first phase,
USD 6 million in grant payments are available for mini-grid
projects in Benin, Madagascar and Sierra Leone to deliver
around 14,000 electricity connections.236
While renewables-based energy access solutions are already
well developed and commercially available for many applications,
funding also has been allocated to support research and
innovation. In 2020, the Fair Cooling Fund, administered by
Ashden and launched in November with USD 580,000 in funding
from the philanthropic collaborative K-CEP, awarded grants of
between USD 40,000 and USD 100,000 to seven innovators for
the development of sustainable cooling options, including in off-
grid areas.237 Engineers Without Borders USA awarded seven
grants in May 2020 of between USD 30,000 and USD 50,000
for its Chill Challenge to catalyse innovative solutions for off-
grid refrigeration; projects included innovative solar chilling
refrigeration and an icemaker powered by farm waste.238
To support innovation in clean cooking, the UK Aid-funded
modern energy cooking services (MECS) programme awarded a
total of GBP 826,000 (more than USD 1 million) to 14 community-
scale pilots and market assessments to advance efficient electric
cooking.239 Renewables-focused pilots include funding for
PowerCorner Zambia, which will explore powering rural electric
cooking with solar mini-grids.240
177
100
80
60
40
20
100
80
60
40
20
100
80
60
40
20
0 0 0
Latin America &
Caribbean
East Asia &
Pacific
South Asia
Sub-Saharan
Africa
Latin America &
Caribbean
East Asia &
Pacific
South Asia
Sub-Saharan
Africa
Latin America &
Caribbean
East Asia &
Pacific
South Asia
Sub-Saharan
Africa
Inclusion of o�-grid solutions
in electricity plan
Framework for mini-grids
Framework for stand-alone
solutions
2010 2015 2019
RENEWABLES 2021 GLOBAL STATUS REPORT
NATIONAL POLICY
DEVELOPMENTS
The scale-up of renewables-based systems for energy access
requires conducive policy, regulatory and fiscal environments.
This means national targets and plans that include off-grid
renewables, combined with a variety of specific measures to
support renewables – such as fiscal incentives (for example,
lower VAT rates, import duty exemptions) and subsidies, quality
standards for solar systems and cook stoves, and tariff regulations
for mini-grids.241 (p See Tables 7 and 8.)
While many countries had electricity access targets in 2020,
out of 64 selected countries with electricity access deficits, just
under half had renewables-focused energy access targets.242
(p See Table 7.) Several countries also have included off-grid
renewables targets for electricity access in their Nationally
Determined Contributions (NDCs) towards reducing emissions
under the Paris Agreement.243 Some countries have adopted
new off-grid energy access targets linked to economic recovery
plans in response to the COVID-19 pandemic. For example,
Nigeria announced that it would support 5 million new solar
home systems or mini-grid connections serving up to 25 million
customers under the Solar Power Naija Initiative.244 As part of the
Nigerian Economic Stability Plan, the initiative also aims to create
up to 250,000 jobs in the energy sector.245
Over the last decade, policy frameworks benefiting renewables
for electricity access have made major advances, especially in
sub-Saharan Africa where most countries had few relevant
policies in 2010 or even as recently as 2015.246 By 2019, policies
such as the inclusion of off-grid solutions in electricity planning,
regulatory and fiscal frameworks to promote mini-grids and
stand-alone renewables had been implemented in many more
countries.247 (p See Figure 45.)
Developments in 2020 include the Ethiopian Energy Authority’s
new directive to establish procedures for mini-grid licencing and
tariff regulations.248 Benin and Mali introduced VAT and import
duty exemptions for solar.249 Kenya, on the other hand, removed
a VAT exemption for solar and wind power, including batteries, in
Note: RISE (Regulatory Indicators for Sustainable Energy) provides a set of indicators to help
compare national policy and regulatory frameworks for sustainable energy. Indicators in the
Figure assess average countries’ policy and regulatory support for access to electricity across
selected regions. RISE classifies countries into strong performers in the top third of the 0-100
score range, middle third performers, and weaker performers in the bottom third.
Source: ESMAP. See endnote 247 for this chapter.
FIGURE 45.
Key Improvements in RISE Indicators, Selected Regions, 2010, 2015 and 2019
178
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its 2020 Finance Bill (although there were suggestions that this
removal would be repealed in 2021).250
Solar irrigation received support in India, where the Kusum
Yojana scheme offers farmers a 60% subsidy for installing solar
pumps.251 Togo announced that it would provide 50% subsidies
for solar water pumps.252
Several donor programmes aim to further support off-grid
renewables policy development, especially to improve the
regulatory environment for mini-grids. In 2020, the Global
Environment Facility, with the United Nations Development
Programme as the lead agency, launched its new Africa Mini-
grids Programme.253 The programme focuses on policy de-risking
to reduce costs and will initially support 11 African countries in
addressing the key risks and underlying barriers holding back
investment.254
Clean cooking tends to receive less attention from policy
makers, as half of the population without access to clean cooking
lives in countries that lack advanced policy frameworks (such as
plans, standards and financial incentives) for clean cooking.255
However, some countries have implemented these type of policy
measures during the last decade, especially in Latin America, the
Caribbean and South Asia.256 In Africa, Benin, Kenya, Nigeria and
Tanzania also have been catching up.257 Clean cooking policies
generally do not focus on renewables but support clean cooking
solutions more broadly.
Several countries have covered clean cooking in their NDCs to
address the significant climate impacts of deforestation from
inefficient biomass cooking.258 (p See Table 8.) For example,
the Nepalese government included new clean cooking
targets in its second NDC submitted in December 2020.259
In addition to 500,000 additional improved cook stoves and
200,000 household biogas systems, the NDC aims for 25% of
households to cook with electricity by 2030, in tandem with
targets to increase electricity generation from renewables.260 To
support a shift to electric cooking, the government decided in
2020 to waive the 15% customs duty for induction stoves and
to introduce a 20% discount on electricity bills for induction
stove users.261
India has supported major growth in clean cooking with LPG
and in 2020 expanded the Pradhan Mantri Ujjwala Yojana
scheme to provide subsidised LPG connections to 10 million
additional poor households.262 As part of the country’s March
2020 COVID relief package, up to three free-of-cost LPG refills
were provided to scheme recipients.263 By contrast, in Kenya
fiscal responses to the pandemic resulted in clean cook stoves
and fuels losing the VAT exemption in place since 2016.264
This was denounced by the clean cooking industry as a major
setback in a country that had strongly supported growth in
the sector.265
Half of the population without
access to clean cooking lives
in countries that
lack policy
frameworks
for this.
179
Country National Plans and Targets Regulatory Policies Non-Regulatory Policies
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si
on
s
(c
on
n
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–
ti
on
c
od
es
, t
ar
iff
,
lic
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ci
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tc
.)
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n
d
er
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g
, c
al
l
fo
r
p
ro
p
os
al
s
or
c
om
p
et
it
iv
e
p
ro
ce
ss
Q
ua
lit
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Te
ch
ni
ca
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fr
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n
d
st
an
d
ar
d
s
P
ub
lic
fi
na
n
ci
ng
(l
oa
ns
, g
ra
nt
s,
su
b
si
d
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s,
g
ua
ra
nt
ee
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tc
.)
Fi
sc
al
in
ce
nt
iv
es
(i
m
p
or
t d
ut
y,
V
A
T,
e
tc
.)
Africa
Angola
Benin
Botswana
Burkina Faso
Burundi
Cameroon
Central African Republic
Chad
Comoros
Congo, Democratic
Republic of the
Congo, Republic of the
Côte d’Ivoire
Djibouti
Equatorial Guinea
Eritrea
Eswatini
Ethiopia
Gabon
Gambia
Ghana
Guinea
Guinea-Bissau
Kenya
Lesotho
Liberia
Madagascar
Malawi
Mali
Mauritania
Mozambique
Namibia
Niger
Nigeria
Rwanda
São Tomé and Príncipe
Senegal
Sierra Leone
Somalia
South Africa
South Sudan
Sudan
Tanzania
Togo
Uganda
Zambia
Zimbabwe
Asia
Bangladesh
Cambodia
India
Korea, Democratic
People’s Republic
Mongolia
Myanmar
Nepal
Pakistan
Philippines
RENEWABLES 2021 GLOBAL STATUS REPORT
TABLE 7.
Distributed Renewables Policies for Electricity Access, Selected Countries, 2020
Note: Please see key on the next page.
180
Country National Plans and Targets Regulatory Policies Non-Regulatory Policies
D
is
tr
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n
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g
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al
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os
al
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om
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sc
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Central and South America
Guatemala
Haiti
Honduras
Panama
Middle East
Syria
Yemen
Country National Plans and Targets Regulatory Policies Non-Regulatory Policies
C
le
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c
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s
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sc
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nt
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es
(i
m
p
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A
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Africa
Ethiopia
Ghana
Kenya
Rwanda
Uganda
Asia
Bangladesh
China
India
Nepal
Central and South America
Guatemala
DI
ST
RI
BU
TE
D
RE
NE
W
AB
LE
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R
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04
TABLE 8.
Distributed Renewables Policies for Clean Cooking Access, Selected Countries, 2020
Existing national policy or tender framework (could include sub-national)
New (one or more policies of this type)
National tender held in 2020
Removed
Top 20 access-deficit countries
Existing national policy or tender framework (could include sub-national)
New (one or more policies of this type)
National tender held in 2020
Removed
Top 20 access-deficit countries
TABLE 7.
Distributed Renewables Policies for Electricity Access, Selected Countries, 2020 (continued)
Note: The list includes only countries that have an electrification rate below 95% according to the IEA World Energy Outlook 2020 Electricity Access Database
(except for India and the Philippines). The top 20 access-deficit countries are the 20 countries with the highest electricity access-deficit populations. These are
Angola, Bangladesh, Burkina Faso, Chad, the Democratic Republic of the Congo, Ethiopia, India, Kenya, the Democratic People’s Republic of Korea, Madagascar,
Malawi, Mozambique, Myanmar, Niger, Nigeria, Pakistan, Sudan, Tanzania, Uganda and Yemen.
INDC and NDC refers to countries’ (Intended) Nationally Determined Contributions towards reducing greenhouse gas emissions under the United Nations
Framework Convention on Climate Change; VAT = value-added tax.
Source: See endnote 241 for this chapter.
Note: The top 20 access-deficit countries are the 20 countries with the highest clean cooking access-deficit populations. These are Afghanistan, Bangladesh,
China, the Democratic Republic of the Congo, Ethiopia, Ghana, India, Indonesia, Kenya, the Democratic People’s Republic of Korea, Madagascar, Mozambique,
Myanmar, Nigeria, Pakistan, Philippines, Sudan, Uganda, Tanzania and Vietnam.
INDC and NDC refers to countries’ (Intended) Nationally Determined Contributions towards reducing greenhouse gas emissions under the United Nations
Framework Convention on Climate Change; VAT = value-added tax.
Source: See endnote 241 for this chapter.
181
In 2020, Banco do Brasil committed to expanding renewables in its energy matrix up to
90% by 2024 and inaugurated its first solar power plant in March.
0505
i Renewable energy includes onshore and offshore wind, large- and small-
scale solar, biofuels, biomass and waste, marine, geothermal and small
hydropower.
ii These estimates are for capacity investment and exclude capital invested in
companies and money spent on research, development and manufacturing.
iii The final investment decision marks the point in the capital project
planning process when the decision to make major financial commitments
is taken. At that point, major equipment orders are placed and engineering,
procurement and construction contracts are signed.
05
lobal investment in new renewable energy capacity
(excluding large hydropower)i withstood the economic
crisis triggered by the COVID-19 pandemic and
totalled USD 303.5 billionii in 2020.1 This 2% increase over 2019
marks a significant rebound, particularly during the second half
of the year.2 With lockdowns and mobility restrictions affecting
the entire renewables production and construction chain in the
first half of 2020, new renewable capacity was expected to fall
10% for the year.3 In the first quarter of 2020, final investment
decisionsiii on solar and wind projects dropped to their 2017 levels
(USD 10 billion for solar and USD 23 billion for wind).4
However, government recovery packages increased the flow of
renewable energy finance.5 (p See Sidebar 3 in Policy Landscape
chapter, and Figure 5 in Global Overview chapter.) Private
initiatives also contributed to the resilience of renewables, with
continued development aimed at boosting investor interest in
renewable energy – including through climate-related financial
disclosure, green standards and taxonomies, and (to a certain
extent) divestment campaigns. (p See Feature chapter.)
INVESTMENT
FLOWS05
G Global investment in new renewable
energy capacity totalled USD 303.5 billion
in 2020, up 2% from 2019.
Developing and emerging economies
surpassed developed countries in
renewable energy capacity investment
for the sixth year running, although by
a smaller margin than in previous years,
reaching USD 153.4 billion.
Recovery packages from January 2020 to
April 2021 allocated at least USD 53.1 billion
in direct support for renewable energy,
nearly six times less than for fossil fuels.
Renewable energy projects represented
nearly 60% of all climate finance during
2017 and 2018, averaging USD 337 billion.
The divestment movement continued its
upward trend in 2020, with more than
1,300 institutional investors and institutions
worth nearly USD 15 trillion committing
to divesting partially or fully from fossil
fuel-related assets.
K E Y FA C T S
INVESTMENT IN RENEWABLE
ENERGY CAPACIT Y
183
Billion USD
China
Other
developing
and
emerging
countries
European
Union and
United
Kingdom
United
States
Other
developed
countries
0
50
100
150
200
250
300
350
2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2 %
increase
from 2019
to 2020304
40
.7
12
3.
0
44
.2
42
.6
83
.8
35
.0
32
.8
47
.6
29
.1
40
.2
43
.4
58
.3
31
.6
47
.6
50
.2
53
.0
37
.6
40
.4
57
.1
40
.8
32
.2 54
.2
40
.4
45
.7
32
.2 6
6.
6
47
.5
42
.8
31
.9 6
9.
8
70
.3
42
.9
61
.7
28
.5
69
.4
49
.3
31
.446
.2
39
.5 53
.9
60
.6
86
.2 1
15
.8 14
0.
9
94
.4
95
.0
83
.6
10
0.
7
World Total
18 2
4
RENEWABLES 2021 GLOBAL STATUS REPORT
INVESTMENT BY ECONOMY
For the sixth consecutive year, renewable energy capacity
investments by developing and emerging countries (excluding
hydropower projects larger than 50 megawatts, MW) exceeded
those of developed countries, although by a smaller margin
than in previous years, accounting for 50.5% of the 2020 total.6
(p See Figure 46.) Investments for the year rose 13% in developed
countries and fell 7% in developing and emerging countries.7
The drop in developing countries was due mainly to declining
capacity investment in China (down 12%), India (down 36%) and
developing countries in the Americas (down 33%).8 Investment
also fell in Sub-Saharan Africa (down 14%), further diminishing
the low investment in new renewable capacity in the region
(USD 2.8 billion).9 In contrast, investment growth continued for the
seventh consecutive year in developing countries outside of those
areas, including in Brazil (up 23%), the Middle East and North
Africa (up 22%), and Asia and Oceania (up 13%).10 (p See Figure 47).
Note: Figure includes utility-scale renewable energy and small-scale solar projects and excludes large hydropower projects of more than 50 MW.
Source: BloombergNEF. See endnote 6 for this chapter.
FIGURE 46.
Global Investment in Renewable Power Capacity in Developed, Emerging and Developing Countries, 2010-2020
Renewable energy
capacity
investments
in developing and
emerging countries
exceeded those in
developed countries.
184
i Chinese participation in these power plants includes foreign direct investment, mergers and acquisitions, greenfield investments and debt finance.
See Global Development Policy Center, Boston University, “China’s Global Power Database”, http://www.bu.edu/cgp.
ii The China Development Bank and the Export-Import Bank of China.
Billion USD
China
Other
developing
and
emerging
countries
European
Union and
United
Kingdom
United
States
Other
developed
countries
0
50
100
150
200
250
300
350
2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2 %
increase
from 2019
to 2020304
40
.7
12
3.
0
44
.2
42
.6
83
.8
35
.0
32
.8
47
.6
29
.1
40
.2
43
.4
58
.3
31
.6
47
.6
50
.2
53
.0
37
.6
40
.4
57
.1
40
.8
32
.2 54
.2
40
.4
45
.7
32
.2 6
6.
6
47
.5
42
.8
31
.9 6
9.
8
70
.3
42
.9
61
.7
28
.5
69
.4
49
.3
31
.446
.2
39
.5 53
.9
60
.6
86
.2 1
15
.8 14
0.
9
94
.4
95
.0
83
.6
10
0.
7
World Total
18 2
4
IN
VE
ST
M
EN
T
FL
OW
S
05
Although capacity investment in China fell 12% compared to
2019, the country continued to lead in overall renewable energy
capacity investment, accounting for 27.5% of the global total.11
The European Union (EU) was next, with 22.9%, followed by
Asia-Oceania (16.9%, excluding China and India) and the United
States (16.2%).12 Africa and the Middle East accounted for 4.5%,
non-EU Europe for 4.1%, the Americas (excluding Brazil and the
United States) for 3%, Brazil for 2.9% and India for 2%.13
Overall capacity investment in China totalled USD 83.6 billion in
2020.14 Around 65.5% of these investments were in the wind sector
(onshore and offshore), followed by solar PV (30%), biomass and
waste (4.2%) and small hydropower (0.5%).15 In parallel, China’s
foreign investments in solar PV, wind power and hydropower
represented for the first time more than half of the country’s total
overseas energy investments under the Belt and Road Initiative
– China’s main international co-operation and economic strategy
– increasing from 38% in 2019 to 57% in 2020.16 This was due
mainly to the steady decline in coal investments since 2015
(although they resurged in 2020) and to the sharp decrease in
natural gas investment, which represented only 2.4% of the total
2020 investment, compared with 23.7% in 2019.17 The majority
of renewable energy investment was in hydropower (35%), while
solar and wind represented 23%.18
Qatar and Oman received 100% of the renewable energy
investments from China in 2020.19 However, most of the power
plants financedi during the year by foreign direct investment
from Chinese companies and China’s two global policy banksii
were coal-fired plants (around 39% of the capacity), followed by
hydropower (27%).20 Wind and solar projects constituted a higher
share of total projects than coal, gas and hydropower plants,
but due to their smaller capacity they accounted for only 11% of
Chinese investment overseas.21
After hitting a record high in 2019, US investment in renewable
energy capacity fell 20% in 2020, to USD 49.3 billion.22
Investments were mainly in solar PV (USD 31.3 billion, or 63.5%
of the total) and onshore wind (USD 17.7 billion, 36%).23 The EU
was the main driver of increased renewable energy capacity
investment in 2020, totalling USD 69.4 billion in 2020, led by the
United Kingdom and the Netherlands (due to investments in
large offshore wind projects), followed by Spain.24
185
http://www.bu.edu/cgp
RENEWABLES 2021 GLOBAL STATUS REPORT
Billion USD
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
Billion USDBillion USD
Billion USD
United States Europe
Americas (excl. United States & Brazil)
Brazil
Billion USD
Billion USD
Middle East & North Africa
China
Asia & Oceania (excl. China & India)
India
Billion USD
Billion USD
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
Billion USD
Sub-Saharan Africa
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
0
5
10
15
0
5
10
15
0
5
10
0
10
20
5
15
0
5
10
15
0
20
40
60
0
30
60
90
120
150
0
20
40
60
80
10
30
50
0
30
60
90
120
150
26
.1
26
.1
44
.2
44
.2
35
.0
35
.0
29
.1
29
.1
31
.6
31
.6 37
.6
37
.6 40
.8
40
.8 45
.7
45
.7
42
.8
42
.8 49
.3
11
.1
11
.1
9.
1
9.
1
10
.0
10
.0 12
.0
12
.0 14
.6
14
.6
11
.5
11
.5
6.
6
6.
6
13
.1
13
.1
13
.5
13
.5
9.
8
9.
8
9.
1
8.
7
6.
4
6.
4 9
.7 9.
7
7.
6
7.
6
3.
4
3.
4 5.
4
5.
4 6.
7
6.
7
5.
1
5.
1 6.
0
6.
0
3.
9
3.
9 7
.17.
1
2.
2
2.
2
2.
1
2.
1 3.
3
3.
3
2.
2
2.
2
5.
6
5.
6
6.
0
6.
0
5.
2
5.
2 8
.3 8.
3 10
.0
10
.0
8.
9
8.
9 10
.9
2.
0
2.
0
1.
3
1.
3
6.
6
6.
6
5.
0
5.
0
3.
2
3.
2 5
.4 5.
4
2.
6
2.
6
2.
4
2.
4
6.
9
6.
9
3.
3
3.
3
2.
8 6.
3
6.
3
11
.2
11
.2
6.
4
6.
4
4.
7
4.
7 6.
1
6.
1
7.
5
7.
5
12
.9
12
.9
13
.5
13
.5
10
.7
10
.7
9.
7
9.
7
6.
2
15
.0
15
.0 20
.2
20
.2
41
.1
41
.1
50
.8
50
.8
48
.0
48
.0
38
.2
38
.2
37
.2
37
.2 4
5.
4
45
.4
45
.3
45
.3 5
1.
2
27
.1
27
.1
10
6.
7
10
6.
7 1
27
.6
12
7.
6
52
.2
52
.2 6
3.
6
63
.6
58
.5
58
.5 64
.9
64
.9
46
.3
46
.3 5
9.
3
59
.3
54
.0
54
.0
81
.8
89
.0
89
.0
61
.7
61
.7
34
.8
34
.8
39
.5
39
.5
60
.6
60
.6
86
.2
86
.2
11
5.
8
11
5.
8
10
0.
7
10
0.
7
14
0.
9
14
0.
9
94
.4
94
.4
95
.0
95
.0
83
.6
53
.9
53
.9
United States
Americas
(excl. United States & Brazil)
Brazil
Middle East & North Africa
Europe
China
India
OceaniaAsia &
Sub-Saharan Africa
& India)(excl. China
Note: Figures include utility-scale renewable energy and small-scale solar projects and exclude large hydropower projects of more than 50 MW. The regions in
this chapter follow those presented in the BNEF Energy Transition Investment 2021 report and differ from the regional definitions included elsewhere in the GSR.
Source: BloombergNEF. See endnote 10 for this chapter.
INVESTMENT BY TECHNOLOGY
Solar power represented nearly
half of global renewable energy
capacity investment in 2020, at
USD 148.6 billion.25 It was the only
renewable energy technology
to increase for the year, up 12%
from 2019.26 Although wind
power capacity installations
grew during the year, investment
FIGURE 47.
Global Investment in Renewable Energy Capacity, by Country and Region, 2010-2020
In 2020, solar power was
the only renewable energy
technology to experience an
increase in
investments.
186
i Although the energy produced from solid waste combustion is efficient, it cannot be considered entirely renewable as solid waste also contains inorganic
material. Generally, around 50% of energy from municipal solid waste is classified as renewable. (p See Glossary.)
IN
VE
ST
M
EN
T
FL
OW
S
05
Billion USD
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
Billion USDBillion USD
Billion USD
United States Europe
Americas (excl. United States & Brazil)
Brazil
Billion USD
Billion USD
Middle East & North Africa
China
Asia & Oceania (excl. China & India)
India
Billion USD
Billion USD
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
Billion USD
Sub-Saharan Africa
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
0
5
10
15
0
5
10
15
0
5
10
0
10
20
5
15
0
5
10
15
0
20
40
60
0
30
60
90
120
150
0
20
40
60
80
10
30
50
0
30
60
90
120
150
26
.1
26
.1
44
.2
44
.2
35
.0
35
.0
29
.1
29
.1
31
.6
31
.6 37
.6
37
.6 40
.8
40
.8 45
.7
45
.7
42
.8
42
.8 49
.3
11
.1
11
.1
9.
1
9.
1
10
.0
10
.0 12
.0
12
.0 14
.6
14
.6
11
.5
11
.5
6.
6
6.
6
13
.1
13
.1
13
.5
13
.5
9.
8
9.
8
9.
1
8.
7
6.
4
6.
4 9
.7 9.
7
7.
6
7.
6
3.
4
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94
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.0
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.6
53
.9
53
.9
United States
Americas
(excl. United States & Brazil)
Brazil
Middle East & North Africa
Europe
China
India
OceaniaAsia &
Sub-Saharan Africa
& India)(excl. China
in wind power fell 6% to USD 142.7 billion, representing 47% of the
total.27 (p See Market and Industry chapter.)
Biomass and waste-to-energyi investment was down 3% to
USD 10 billion.28 The remaining technologies continued their
downward trend in 2020, with investment in small hydropower
reaching USD 0.9, geothermal USD 0.7 billion and biofuels
USD 0.6 billion – each dropping more than 70% since 2010.29
(p See Figure 48.)
The factors behind these trends vary by technology. Common
barriers to investment in small hydropower projects include the
high upfront cost, the lack of a regulatory framework encouraging
deployment of the technology, and a high degree of risk and
uncertainty in the different development stages.30 For geothermal
projects, high risks and expensive early-stage development (test
drilling) have impeded further participation from private investors
in the last two decades.31
187
i Advanced biofuels, or second-generation biofuels, are made of “lignocellulosic feedstock such as corn stover, straw, wood waste, rapidly growing grasses and
short-rotation trees, municipal waste, and waste oils, fats or algae, all of which have few non-energy uses, and some of which can be grown on less productive
and degraded lands or in seawater (algae), thus involving a smaller impact in terms of land-use.” See International Renewable Energy Agency, Advanced
Biofuels: What Holds Them Back? (Abu Dhabi: 2019), https://irena.org/publications/2019/Nov/Advanced-biofuels-What-holds-them-back.
Change
relative
to 2010
Change
relative
to 2019Technology New Annual Investment (Billion USD)
2010
2019
2020
+64%
+60%
+12%
-6%
Solar
power
Wind
power
Solar
power
Wind
power
0 4 8 12 16
0 40 60 80 100 120 140 160
Geothermal
power-73%
Ocean
power-100%
Small-scale
hydropower-82%
Biomass
and waste-39%
-91%
-30%
–
-48%
-3%
-65% Biofuels
20
20
90.990.9
Geothermal
power
Ocean
power
Small-scale
hydropower
Biomass
and waste
Biofuels
132.4132.4
148.6148.6
89.089.0
151.3151.3
142.7142.7
16.316.3
10.310.3
10.010.0
5.05.0
1.71.7
0.90.9
1.71.7
0.60.6
2.52.5
1.01.0
0.70.7
0.030.03
0.00.0
0.00.0
6.96.9
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: Figure includes utility-scale renewable energy and small-scale solar projects and excludes large hydropower projects of more than 50 MW.
Source: BloombergNEF. See endnote 29 for this chapter.
FIGURE 48.
Global Investment in Renewable Energy Capacity by Technology, 2010, 2019 and 2020
The declining investment in first-generation biofuels started
in 2007, amid growing concern about the impacts of the fuels
on food security and prices and on land use (also affecting
greenhouse gas emissions).32 In contrast, investment in second-
generation biofuelsi grew starting in 2007, but the growth lasted
only until 2011.33 The main barriers to further investment in the
sector include the regulatory uncertainty regarding sustainability
criteria (especially in Europe), low subsidy levels, high financing
costs and doubts regarding technological readiness.34
Marine power received no capacity investment in 2020, mainly
because of technology challenges and a lack of specific policy
support in the key markets.35
Other investments that are relevant (indirectly) to the uptake
of renewables include spending on electric vehicles (EVs),
heat pumps and energy storage.36 (p See Systems Integration
chapter.) In 2020, investment in EVs and associated charging
infrastructure was up 28% to USD 139 billion, and investment in
domestic installation of energy-efficient heat pumps was up 12%
to USD 50.8 billion; meanwhile, investment in batteries and other
energy storage technologies (excluding pumped hydropower,
compressed air and hydrogen) was unchanged from 2019,
despite lower unit prices, for a total of USD 3.6 billion.37 Hydrogen
investment fell 20% in 2020, due to lower investment in fuel cell
buses and commercial fuel cell vehicles, while investment in the
electrolysis process rose 12.5% to USD 189 million due to the
increased attractiveness of renewable hydrogen production.38
188
https://irena.org/publications/2019/Nov/Advanced-biofuels-What-holds-them-back
i This refers to policies supporting the production or consumption of low-carbon energy and the energy transition, including: energy efficiency and renewable
energy (solar, wind, small hydropower, rain, tides and geothermal heat, large hydropower); renewable hydrogen; active transport (cycling and walking), rail, public
transport and EVs (electric cars, bicycles, scooters and boats) using multiple types of energy; smart grids and technologies that better integrate renewables;
hydrogen in the case of mixed, but predominantly clean, sources (e.g., as under Germany’s hydrogen strategy); and biofuels, biomass and biogas with a proven
minimum negative impact on the environment. For details, see EnergyPolicyTracker.org, “Methodology”, https://www.energypolicytracker.org/methodology.
42%
Fossil fuels
29%
Enabling
technologies
and energy
e�iciency
22%
Clean mobility
22%
Other
7% Renewables
Enabling
technologies
and energy
e�iciency
1.2%
Renewable hydrogen
5.0%
Energy e�iciency
0.8%
Energy e�iciency in
clean mobility
0.3%
Hydropower
(small and large)
0.3%
Solar
0.2%
Wind
4.0%
Biofuels and waste
2.5%
Multiple renewable
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COVID-19’S IMPACT ON INVESTMENT
In addition to the resilience of renewable energy investments
to the COVID-19 crisis, economic recovery packages in 2020
included significant spending to stimulate further investment
in renewables, both to address climate change and to deploy
specific renewable energy projects.
By September 2020, governments had announced
USD 11.8 trillion in fiscal assistance in response to the
pandemic-induced economic crisis, more than three times the
amount spent to respond to the financial crisis of 2008.39 While
most of the funding prioritised supporting health and reducing
unemployment, around 30% was allocated to sectors with an
impact on the energy transition, with the aim of creating jobs
and boosting economies.40 Globally, investment in the solar PV
sector in 2020 created an estimated 13 jobs per USD 1 million
invested, or twice as many jobs as in the coal or gas industry.41
Wind and hydropower projects generated as many jobs as
nuclear power projects.42
As of April 2021, 31 governments had announced a combined
USD 732.5 billion in spending to support all types of energy through
new or amended policies.43 Of this total, 42% (USD 309.9 billion) was
allocated to fossil fuel-intensive sectors, 37% (USD 264.2 billion) to
“clean energy”i and 21% (USD 152.9 billion) to other energy sources
(including nuclear, first-generation biofuels, biomass and biogas,
and hydrogen from unspecified sources).44 (p See Figure 49.)
Note: Although the energy produced from solid waste combustion is efficient, it cannot be considered entirely renewable as solid waste also contains
inorganic material. Generally, about 50% of energy from municipal solid waste is classified as renewable. (p See Municipal solid waste in Glossary.). Multiple
renewables include geothermal and ocean power. Enabling technologies include e-mobility and renewable hydrogen. The “Other” category refers to other
types of energy-related policies including, among others, nuclear energy, incineration, hydrogen from unspecified sources, and multiple energy types (for
example intertwined fossil fuels and clean energy). Where totals do not add up, the difference is due to rounding.
Source: EnergyPolicyTracker.org. See endnote 44 for this chapter.
FIGURE 49.
Energy Investments in COVID-19 Recovery Packages of 31 Countries, January 2020 to April 2021
Renewable energy
investments in COVID-19
recovery packages were
nearly
six times less
than those for fossil fuels.
189
i The term “clean hydrogen” refers to renewable and low-carbon hydrogen in the Hydrogen Strategy for a Climate-neutral Europe elaborated by the European
Commission. See https://ec.europa.eu/energy/sites/ener/files/hydrogen_strategy .
ii The WilderHill New Energy Global Innovation Index tracks the performance of around 100 companies focusing on clean energy, renewables, decarbonisation
and efficiency worldwide.
iii The S&P Global Clean Energy Index is designed to measure the performance of 30 companies from around the world that are involved in clean energy-related
businesses, comprising a diversified mix of clean energy production and clean energy equipment and technology companies.
RENEWABLES 2021 GLOBAL STATUS REPORT
Of the clean energy spending, around 20.1% (USD 53.1 billion)
was allocated directly to policies to support the production or
consumption of renewables (including solar and wind power,
small and large hydropower, rain and tidal energy, geothermal
heat, and biofuels and waste energy).45 The amount for biofuels
and waste energy covers mainly investments in India, where
nearly USD 27 billion was allocated to set up 5,000 compressed
biogas plants.46 However, 67 of the 199 policies related to clean
energy sources did not specify an amount, making the actual total
allocation much higher.47
Investment in enabling technologies associated with renewable
energy use (such as e-mobility and renewable hydrogen) and
energy efficiency comprised an additional USD 204 billion in
renewable energy-related stimulus.48
Regionally, the EU led in environmental investments as of April
2021, allocating 30% (around EUR 550 billion, or USD 660 billion)
of its overall recovery package and its long-term 2021-2027
budget solely to climate-related projects.49 These projects
included scaling up renewable energy (mainly wind and
solar), launching a European “clean hydrogen economy”i and
developing clean mobility (including EVs).50 However, many of
the clean energy policies that could strengthen the deployment
of renewables had not yet been translated into legislation, and
allocation amounts had not been determined as of April 2021.51
Within the EU, the leaders in renewable energy measures and
allocations were Germany (at least USD 12.6 billion) and France
(at least USD 3.9 billion).52
By early 2021, the United States had pledged only around
USD 459.5 million to support renewable energy and
USD 26.8 billion to support mobility, including EVs; this was
less than 40% of the amount that was allocated to fossil fuel
energy, without establishing climate targets or additional
pollution reduction requirements (at least USD 72 billion).53
The administration’s proposed clean energy and sustainable
infrastructure plan released in early 2021 favoured investment in
renewable energy, although the US Congress still needed to pass
legislation and allocate proper funding.54
Other economies that announced investments in renewables
(as well as fossil fuels) included the Republic of Korea, which
allocated USD 984 million for solar and offshore wind generation;
China (at least USD 217 million in biofuels and waste and
multiple renewables) and India (at least USD 30 billion, including
USD 27 billion to biofuels and waste projects).55 However, these
economic recovery plans also include coal (USD 2.5 billion in the
Republic of Korea, USD 1.07 billion in China and USD 15.5 billion
in India).56
Several countries focused on electricity decarbonisation, with the
Republic of Korea, France and Italy increasing their subsidies for
rooftop solar PV.57 Nigeria, Africa’s largest oil and gas producer,
aimed to use 10% of its stimulus funds (USD 620 million) to
install solar systems for up to 5 million households.58 Colombia
allocated USD 4 billion to renewable energy and transmission
projects, including wind (nine projects), solar (five), geothermal
(three) and hydropower (one).59
With calls for a “green recovery” following the COVID recession,
combined with the expectation that the new US administration
would implement low-carbon measures, renewables became
more attractive to investors, who increased investments in wind
and solar power, batteries and EVs.60 The decreasing cost of
these technologies compared to fossil fuels also was key to their
greater appeal.61
Several indices that track the performance of renewable energy
companies surged in 2020. For example, the WilderHill New Energy
Global Innovation Index (NEX)ii gained 142% and the S&P Global
Clean Energy Indexiii gained 138%.62 By contrast, the NYSE Arca
Oil Index and the S&P 500 Energy Index – both of which follow the
performance of fossil fuel-linked companies – fell 38% and 37%,
respectively.63 The solar equipment manufacturer Enphase Energy
was among the three best performers on the NEX.64
Overall, the stock prices of solar power manufacturers and
distributors rose sharply in 2020. For example, the company
SunPower tripled its value, and the Invesco solar index increased
66% between January and September.65 However, growth in
these indices must be viewed with caution as market prices
fluctuate widely: the S&P Global Clean Energy Index fell 30%
between early January and mid-March 2021.66
190
https://ec.europa.eu/energy/sites/ener/files/hydrogen_strategy
i Latest data available. The estimation for 2020 was expected to be ready in 2022.
ii Climate-related export credits refer to government financial support to foreign buyers to help finance the purchase of goods from national exporters, such as
direct financing, guarantees, insurance or interest rate support.
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DEPLOYING RENEWABLE ENERGY
THROUGH CLIMATE FINANCE
Climate finance is the finance channelled to support mitigation
actions that seek to reduce greenhouse gas emissions –
including developing renewable energy, implementing energy
efficiency and promoting sustainable transport – as well as
adaptation actions that address the impacts of climate change.
The renewable energy capacity investment described earlier
does not include all renewables-related spending channelled
through climate finance, as the latter may include, for example,
finance for renewable energy companies in addition to support
for new renewable energy capacity.67
Preliminary data indicate that in 2019, climate finance totalled
between USD 608 billion and USD 622 billion, or a 6% to 8%
increase over the annual average in 2017 and 2018 (USD 574 billion
per year).68 The latest breakdown of climate finance (available
only for those two years and updated at year-end 2020) shows
that renewable energy projects received USD 337 billion on
average, representing almost 60% of all climate finance.69
The investment picture for developing countries is different. The
2015 Paris Agreement underscored the importance of addressing
those countries’ needs, setting a USD 100 billion annual target
to be met jointly by developed countries by 2020.70 Climate finance
from developed to developing countries rose from USD 52.2 billion
in 2013, to USD 58.6 billion in 2016, to USD 78.9 billion in 2018i.71
Initial data indicate that this trend continued in 2019 but did not
meet the USD 100 billion annual target in 2020.72
During the three years between 2016 and 2018, the energy
sector received the largest share of total climate finance:
USD 23.8 billion per year on average, representing 34% of total
climate finance mobilised by developed countries.73 Of that total,
53% (USD 12.5 billion) supported projects targeting energy
generation from renewable sources, including solar (23%),
hydropower (19%), wind (15%), geothermal (5%) and biofuels
(4%), with the rest (34%) from multiple sources or unspecified.74
For developing countries, the sources of global climate finance
are divided equally between private and public, whereas for
developed countries public sources constituted more than
80%.75 Public sources mobilised by developed countries include
bilateral development agencies and institutions (the annual
financial commitments from developed countries to developing
country governments, non-governmental organisations (NGOs)
and civil society, research institutes and the private sector),
multilateral development banks and climate funds, and providers
of climate-related export creditsii.76 Export credits, which totalled
USD 2.1 billion in 2018, covered mainly renewable energy projects,
while the remaining USD 62.2 billion was allocated to a variety of
mitigation and adaptation actions.77
MULTIL ATERAL CLIMATE FUNDS AND DEVELOPMENT BANKS
The major multilateral climate funds include, in order of
investment pledged, the Green Climate Fund (GCF), the Climate
Investment Funds (CIF) and the Global Environment Facility
(GEF).78 Multilateral climate funds and multilateral development
banks play an important role in providing direct support to
developing countries, as they are the principal interface between
the public and private sectors.79
Replenishing these funds is important for the future of climate
finance; they are central to climate funding for developing countries
and determine the amount of investment in addressing climate
mitigation and adaptation challenges in these countries.80
As of year-end 2020, the GCF had received pledges totalling
USD 10.3 billion from 49 countries and regions for the 2020-2023
period, thus succeeding in its first replenishment campaign.81 Of
that total, USD 8.3 billion was secured.82 As of October 2020, 32%
of the GCF’s portfolio comprised energy generation and access
projects, driven mainly by private funding (USD 1,422 million,
compared to USD 589 million in public funding).83 The energy
area represented half of the funding for mitigation actions,
although the amount fell 40% between 2019 and 2020.84
60% of
climate finance
is directed at renewable
energy projects, reaching an
average of USD 337 billion
during 2017 and 2018.
191
Funding in billion USD Share in %
Share of renewable
energy funding in
climate mitigation
funding
Other mitigation
funding
Renewable energy
funding
0
10
20
30
40
50
60
80
70
0%
5%
10%
15%
20%
25%
30%
35%
2015 2016 2017 2018 2019
– 6%
from 2015
to 201930%30%
6.0 6.2
9.2 8.6
11.4
29%29%
33%33%
29%29%
24%24%
RENEWABLES 2021 GLOBAL STATUS REPORT
As of early 2021, the GEF had invested more than USD 1.1 billion
in 249 stand-alone renewable energy projects, as well as
USD 277 million in 54 mixed projects with renewable energy
components in 160 developing and transition countries.85
The CIF and two of its programmes, the Clean Technology Fund
(CTF) and the Scaling Up Renewable Energy Program, also
pledged funding for renewable energy projects (respectively,
USD 5.4 billion as of early 2020, including for renewable
energy deployment projects, and USD 744 million).86 Of the
CTF portfolio, 68% was allocated to renewable energy projects
in reporting year (RY) 2020, resulting in installed capacity of
7.9 gigawatts (GW).87 All CIF projects are implemented by partner
multilateral development banks.88 For example, the Renewable
Energy Financing Facility in Kazakhstan, implemented by the
European Bank for Reconstruction and Development, accounted
for the largest share of the CTF portfolio’s new capacity (21% of
the RY 2020 total), with 104 MW installed.89
In 2019, multilateral development banks allocated USD 11.4 billion
to renewable energy projects, including electricity generation,
heat production and other applications, as well as measures to
facilitate the integration of renewables into grids.90 Of this total,
67% was allocated to low- and middle-income countries and 33%
to high-income countries.91 The regions that received most of the
funding were the EU (30.2%), followed by Sub-Saharan Africa
(16.4%), East Asia and the Pacific (9.9%), multi-regional (9.1%)
and Latin America (8.8%).92 Additional funding for renewables
may have been allocated to research and development or policy
support, but is tracked under other categories and thus is not
included in the USD 11.4 total.93
Multilateral development bank investments in renewable energy
projects have increased since 2014 (up 89% between 2015 and
2019).94 However, their total investments (including non-renewable
energy-specific funding)
rose 132% over the same
period.95 Consequently,
the share of renewable
energy funding in total
funding decreased during
the five-year period,
falling from 30% in 2015
to 24.4% in 2019.96 (p See
Figure 50.)
Source: See endnote 96 for this chapter.
FIGURE 50.
Share of Renewable Energy Funding in Climate Mitigation Finance from Multilateral Development Banks, 2015-2019
Multilateral
development
banks’ investments in
renewable energy projects
have increased since 2014,
reaching USD 11.4 billion
in 2020.
192
i See Glossary for definition. The majority of the green bonds issued are green “use of proceeds” or asset-linked bonds. Proceeds from these bonds are
earmarked for green projects but are backed by the issuer’s entire balance sheet. To qualify for green bond status, they are often verified by a third party,
such as the Climate Bond Standard Board, which certifies that the bond will fund projects that include benefits to the environment. See Socialfintech.org,
“Capital markets and climate change: The green bond”, https://socialfintech.org/capital-markets-and-climate-change-the-green-bond.
ii Securitisation is “the process whereby illiquid assets or rights are pooled and transformed into tradeable and interest-bearing financial instruments that are sold
to capital market investors. These illiquid assets/claims may include bank or car loans, lease contracts, trade receivables, and insurance premiums, among others.
Securitization acts not only as a means to raise cash on the capital markets, but also as a credit risk transfer tool.” See Deloitte, Securitization: Structured Finance
Solutions (Luxembourg: 2018), https://www2.deloitte.com/content/dam/Deloitte/lu/Documents/financialservices/lu_securitization-finance-solutions .
iii Data are not available for 2020; in 2019, the total amount divested was over USD 11 trillion. See Gofossilfree.org, “Commitments”, https://gofossilfree.org/divestment/
commitments.
iv Climate Action 100+ is now the largest ever investor engagement initiative on climate change. The numbers of focus companies, by sector, are: 39 oil and gas
companies, 31 utility companies, 26 transport companies, 26 industrial companies, 23 mining and metals companies and 14 consumer products companies.
See Climate Action 100+ , “Companies”, https://www.climateaction100.org/whos-involved/companies.
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CLIMATE FINANCE INSTRUMENTS
In 2018, loans and grants made up the key public finance
instruments (84% and 13%, respectively) used in the energy sector
overall.97 Guarantees and equity investments also were used but
represented only a very small share (3%).98 Loans more than
doubled from USD 19.8 billion in 2013 to USD 46.3 billion in 2018,
increasing their share of total public finance from 52% to 74%.99
Grants fluctuated between USD 10 billion and USD 12 billion, and
their share fell from 27% to 20%.100
One loan instrument in particular contributed to this trend:
green bondsi, which are designed to fund projects with positive
environmental or climate benefits.101 Green bonds hit record
levels for a second consecutive year, up 1.1% in 2020 to reach
USD 269.5 billion.102 Rebounding in the second half of the year
amid the COVID-19 crisis, the green bonds market hit a milestone,
exceeding a cumulative USD 1 trillion in issuance since this
mechanism was created.103
Investment in the energy sector represented the largest share of
green bonds in 2020, at USD 93.6 billion (34.7%).104 More than
half of this (USD 55.9 billion) was allocated to renewable energy
projects.105 The share of renewable energy bonds in total green
bonds issued rose for the third straight year, from 17% in 2018 to
21% in 2020.106 The United States was the leading issuer (20%
of green bonds issued), followed by China (10%), Germany (9%),
France (8%), the Netherlands (8%) and Spain (7%).107
In developing countries, particularly least-developed countries
and small-island developing states, the market for green bonds
remains small, due in part to these countries’ lower credit ratings or
lack of appropriate institutional arrangements.108 Innovation in the
securitisingii green bonds, aggregating loans for small-scale low-
carbon projects that, individually, are too small for the bond market,
can help promote the issuance of green bonds in these countries.109
Green securitisation has grown in recent years, with more than
USD 25 billion of the green bonds issued in 2019 estimated to be
asset-backed securities, up from USD 1.9 billion in 2015.110
Growth in the renewable energy sector has led to the creation of
solar asset-backed securities, which are securities backed by
consumer receivables originated by solar energy companies, and
used to finance PV systems.111 While still an emerging sector, solar
asset-backed security issuance grew to over USD 2 billion in 2018,
with seven active issuers.112
DIVESTMENT
The movement to pressure institutional investors to divest from
financial assets related to fossil fuel companies has gained steam
in recent years.113 As of April 2021, more than 1,300 institutional
investors and institutions worth nearly USD 15 trillion had
committed to divest partially or fully from fossil fuel-related assets,
up 36% from USD 11 trillion in 2019.114 Faith organisations were the
largest group of institutions divesting, accounting for almost 35%
of the total number of commitments.115 In 2020, 42 faith institutions
from 14 countries announced the largest ever joint fossil fuel
divestment by those institutions.116 This commitment was echoed
later by the Vatican’s call for Catholics to divest from polluting
industries and to shift to sustainable energy investments.117
Educational and philanthropic institutions accounted for another
30% of total commitments as of April 2021, while governments and
pension funds represented 25% (large insurance companies and
pension funds had contributed the highest share to divestments in
2019iii), and corporations and NGOs accounted for the remainder.118
More than 58,000 individuals joined these institutions in the trend,
divesting around USD 5.2 billion in 2020.119
The divestment movement focused initially on coal and expanded
to include oil and natural gas. Since 2015, 135 banks and insurers
with more than USD 10 billion in assets under management or
loans have restricted their investments in coal (from mining to
new coal-fired power plants), with 47 institutions joining in 2020
alone.120 As of 2021, only 24 asset managers and owners with more
than USD 50 billion in assets under management had done that,
and more than half of those were announced in 2020.121 The share
of members from the 160 focus companies of Climate Action 100+iv
– an investor-led initiative to address climate change – that are
now planning a full phase-out of coal doubled between 2019 and
2020 (from 13% to 26%); meanwhile the share of companies with a
partial phase-out plan rose from 35% to 48%, reflecting significant
progress considering that those 160 companies represent over
80% of global industrial emissions.122
Investors have increasingly aligned their portfolios with the
emission reduction goals of the Paris Agreement. Some,
including the Bank of England, seek to reduce the financial
risks of climate change, such as economic losses generated
by extreme or chronic climate events, increased environmental
regulations that negatively impact asset value, technological and
demand changes, and litigation arising from inaction.123 Global
initiatives, including the Task Force on Climate-related Financial
Disclosures, help the financial sector appropriately assess and
price those climate-related risks and identify opportunities.124
193
https://socialfintech.org/capital-markets-and-climate-change-the-green-bond
https://www2.deloitte.com/content/dam/Deloitte/lu/Documents/financialservices/lu_securitization-finance-solutions
https://gofossilfree.org/divestment/commitments
https://gofossilfree.org/divestment/commitments
https://www.climateaction100.org/whos-involved/companies
i Oil sands extraction is among the world’s most carbon-intensive, large-scale crude oil operations. Carbon emissions are reported to be 31% higher than from
conventional oil. Arctic drilling to extract natural gas and oil is more costly and technologically complicated than drilling for oil on land. Large amounts of water
are consumed in the process, and the ability to respond to oil spills is highly limited. See Institute for Energy Economics and Financial Analysis, “Finance is
leaving oil and gas”, https://ieefa.org/finance-exiting-oil-and-gas.
RENEWABLES 2021 GLOBAL STATUS REPORT
As of early 2021, 71 financial institutions had announced their
divestment from oil and gas, particularly from oil sands extraction
and Arctic drillingi; 36 of these institutions joined the movement
in 2020 alone.125
A survey of institutional investors representing USD 6.9 trillion under
management showed that the COVID-19 economic crisis slowed
planned divestments from fossil fuels, with investors divesting
4.5%, on average, of their overall portfolio in 2020, compared to
5.7% planned in the previous year’s survey.126 Respondents now
expect to divest 5.2% over the next five years and 8.6% over
10 years, down from forecasts of 14.4% and 15.6%.127
DOES DIVESTMENT REDUCE GLOBAL FOSSIL FUEL INVESTMENT?
Although divestment is growing, investment in fossil fuel-related
companies among 35 private global banks has increased since
the signing of the Paris Agreement, from USD 640 billion in 2016
to USD 736 billion in 2019.128 This is because while some bank
policies exclude financing for fossil fuel projects, they still allow
lending to the corporate entity that engages in these projects.129
Evidence also shows that other investors end up purchasing
the divested stocks and that declining stock prices in fossil fuel
company cannot be linked specifically to divestment.130
Divestment, per se, generally does not affect either the
production costs of fossil fuel energy or consumers’ willingness
to buy.131 Consequently, the profits of oil and gas company owners
are not decreasing.132 Furthermore, research has found that
although increased oil and gas divestment pledges in a country
are associated with lower capital flows to domestic oil and gas
companies, this may not affect global investment, as national
banks in countries with stricter exclusion policies seem to provide
more funding to oil and gas companies abroad.133
However, some countries and some industry sectors have
made progress in the sense that some companies now face
new challenges in their development of fossil fuel projects.134
In South Africa, the restrictive lending policies of two banks
increased the cost of capital for fossil fuel projects.135 Similarly,
an estimated 85% of the banks in the global market have
expressed unwillingness to invest in coal power plants.136 As a
result, 72% of the plants under construction outside of China
have come to rely on Chinese financing.137 As of July 2020, most
public finance for coal worldwide came from China’s financial
institutions, which allocated USD 50 billion to 53,129 MW of
installed capacity.138
When considering the impact on global greenhouse gas
emissions, studies conclude that investment in innovative and
environmentally friendly companies has a greater impact than
divestment.139
DOES DIVESTMENT ATTRACT INVESTMENT IN RENEWABLES?
In 2020, the estimated global investment in new renewable power
and fuel capacity was more than twice that in coal, natural gas or
nuclear power generating plants combined.140 Nearly 70% of the
estimated global investment was allocated to renewable energy
power plants, while only 31% went to coal, gas and nuclear
plants.141 (p See Figure 51.) Renewable energy projects have
become more appealing, particularly in light of the COVID-19
crisis. A 2020 survey of institutional investors with USD 6.9 trillion
under management found that investors planned to nearly
double their allocation to renewable energy infrastructure in the
near term, from 4.2% in 2020 to 10.8% in 2030.142
However, it is hard to establish a direct link between divesting
from fossil fuels and investing in renewable energy. One study
General
guidance on
reinvestment
appears to be lacking for
institutions and companies
engaged in divestment.
194
https://ieefa.org/finance-exiting-oil-and-gas
i The 12 cities are Berlin, Bristol, Cape Town, Durban, London, Los Angeles, Milan, New Orleans, New York City, Oslo, Pittsburgh and Vancouver.
27%
24%
13 % 5 %
Wind
Solar PV
Hydropower
10 %
12%
9 %
Coal
Gas
Nuclear
Other
renewables
69 %
Renewable
energy
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suggests that between 2001 and 2018, more than half of
energy utilities that prioritise growth in renewables over other
technologies continued investing in natural gas and/or coal.143
Of these utilities, 34% posted negative growth in coal and gas,
and just 15% divested from both in their portfolios.144 Two-thirds
of the utilities prioritising renewable energy were located mainly
in the United States and Europe (particularly Germany), while
10% were in China.145
A few concrete examples of “divest-invest” exist, including the
pledge by 12 major citiesi to divest from fossil fuel companies
while investing in a “green and just recovery” from the COVID-19
crisis.146 This commitment – “Divesting from Fossil Fuels, Investing
in a Sustainable Future” – made by cities across three continents
recognises the potential to create jobs, limit climate risk and
facilitate the energy transition.147 In another example, the Catholic
Impact Investing Pledge represents 28 Catholic organisations with
USD 40 billion in assets under management that have committed
to invest in environmental and justice issues.148
In 2014, the Rockefeller Brothers Fund pledged to divest from
fossil fuels. As of December 2020, the Fund’s total fossil fuel
exposure was an estimated 0.3% of its total portfolio, down
from 6.6% in April 2014.149 The Fund also has set a target to
allocate 20% of its portfolio to “impact” investments, prioritising
investments in support of the United Nations Sustainable
Development Goals, including clean energy development.150
The apparent impact of divestment campaigns lies in their
ability to raise consciousness and change public attitudes
about the fossil fuel industry and investments in fossil fuels.151
However, general guidance still appears to be lacking regarding
reinvestment for institutions and companies engaged in
divestment.152
Note: Hydropower includes pumped storage. Other renewables include bio-power, geothermal power, concentrating solar power (CSP) and ocean power.
Source: IEA. See endnote 141 for this chapter.
FIGURE 51.
Estimated Global Investment in New Power Capacity, by Type, 2020
Almost 70% of the
global investment in new
renew able power and
fuel capacity went to
renewable power plants,
while only 31% went
to coal, gas and nuclear
plants.
195
A new energy storage project marks the next frontier of Apple’s efforts to become carbon
neutral for its supply chain and products by 2030.
0606
i The word “conventional” is used here to describe non-renewable energy
resources or large hydropower. In the context of the power sector, the
term “conventional generators” describes fossil fuel, nuclear and large
hydropower generators.
06
Energy systems integration involves the co-ordinated
design, implementation, operation, planning and
adaptation of energy systems with the objective of
delivering reliable, safe, cost-effective energy services with
minimal environmental impact.1 Here, it is addressed with a
specific focus on the integration of higher levels of renewable
energy in power grids, heating and cooling systems, and transport
fuelling systems.
Renewable energy can lead to more sustainable and economical
operation of energy systems.2 However, as shares of renewable
energy grow, the systems that have evolved or been designed
around conventionali energy sources require adaptation efforts to
maintain or improve the services that they deliver.3 These efforts
include top-down integration measures such as the planning and
design of infrastructure, markets and regulatory frameworks, as
well as the bottom-up development and advancement of supply-
and demand-side technologies. To this end, governments,
regulators, energy utilities, technology companies and energy
consumers have been addressing barriers that may slow or halt
the growth of renewables, working to expand existing end-uses
of renewables, and creating new markets for renewable energy
technologies and services.4
In the power sector in particular, rapid growth in the installed
capacity and penetration of variable renewable electricity (VRE)
sources – such as solar photovoltaic (PV) and wind power – has
occurred in many countries.5 VRE achieved unprecedented
penetration levels during 2020 due to cost reductions and
ENERGY SYSTEMS
INTEGRATION
AND ENABLING
TECHNOLOGIES06
E
K E Y FA C T S
Several power systems saw record levels
of variable renewable electricity (VRE)
penetration in 2020.
Digital technologies were used to
modernise grid monitoring and control,
improve forecasting, and optimise the
flexibility and capacity of existing grid
infrastructure.
Wholesale electricity market design
enabled more participation for VRE power
plants, energy storage and flexible demand
in certain markets.
In 2020, the heat pump market was up in
North America and Europe but slowed in
the Asia-Pacific region. Electric car sales
rose 41%, a significant increase considering
that global car sales overall were down for
the year. New battery storage projects
increased 62% compared to 2019.
197
i Technologies such as solar panels, wind turbines and batteries use power inverters to convert direct current (DC) into alternating current (AC) to allow them
to interface with AC-based power systems. Resources that require the use of inverters do not have the rotational characteristics of conventional gas, steam or
hydro generators, and impose different stability requirements on power systems as they become more prevalent.
ii Distributed energy resources include generators such as solar PV and wind plants, energy storage facilities and sources of demand.
RENEWABLES 2021 GLOBAL STATUS REPORT
subsequent demand.6 In addition, COVID-19 containment
measures that depressed electricity demand resulted in
increased VRE shares due to preferential dispatch protocols and
marginal cost advantages.7
Several power systems reached record-high instantaneous
VRE shares in 2020, forcing grid operators to apply a range of
new and existing measures to ensure ongoing service.8 Some
power systems, for example in South Australia, reached such
high VRE penetration levels that electricity supply routinely
exceeded demand.9 During the year, consumption of electricity
from renewable sources surpassed that from coal in the United
States for the first time in 130 years, while the United Kingdom’s
power system operated without coal power for 18 consecutive
days – the longest period in nearly 140 years.10
At the end of 2020, renewables represented around 29% of global
electricity generation, and more than 9% of the total generation was
estimated to be from solar PV and wind power.11 The penetration
of modern renewables in transport and in the heating and cooling
sector was much lower than this. (p See Global Overview chapter.)
Many examples of renewables integration in 2020 occurred in the
power sector (or involved the electrification of end-uses in other
sectors), particularly in countries and regions with supportive
policy environments or energy markets such as Australia, China,
Europe and North America. (p See Policy Landscape chapter.)
In recent years, the growing shares of variable energy resources
that require the use of power invertersi, and the corresponding
decentralisation of power systems, have created new
requirements for control and monitoring systems.12 These shifts
in turn have prompted the wider digitalisation of transmission
and distribution grids, and of downstream or “behind-the-
meter” systems that incorporate electricity generation, storage
and demand.13 As power grids continue to evolve, numerous
examples have emerged of the digitalisation of key operating
nodes (such as control rooms and sub-stations) in order to
more effectively process and manage more complex flows of
information.14 Advanced digital technologies including artificial
intelligence and machine learning have been applied to improve
the accuracy of both generation and demand forecasting, and
to enable the aggregation of distributed energy resourcesii to
improve power system flexibility.15
Several technologies have supported the integration of
renewables by enabling greater flexibility in energy systems
or by promoting the linking of energy supply and demand
across electricity, thermal and transport applications. Among
the more mature or commercialised enabling technologies are
heat pumps, electric vehicles (EVs) and certain types of energy
storage, such as batteries. Other technologies that were still
emerging during 2020 but that may help to reach higher shares
of renewables in all sectors include renewable hydrogen, non-
lithium-ion batteries (such as flow batteries) and novel forms of
mechanical storage.
Power systems are
adapting to higher
shares of generation
capacity based on
power inverters, such as
wind and solar.
198
i This change is colloquially known as the “duck curve” effect: increased shares of solar electricity can result in a generation surplus in the day and a deficit in
the mornings and evenings when solar generation drops off. This can increase required generation ramp rates in the mornings and evenings and shorten peak
demand periods to less than four hours, which in turn create conditions well suited to use of batteries for peak capacity supply. See endnote 19 for this chapter.
ii Electricity market design extends beyond wholesale markets. For brevity, the GSR covers key high-level developments at the wholesale level only.
Share of total generation (%)
70
60
50
40
30
20
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Solar PV
Wind power
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INTEGRATION OF RENEWABLES
IN THE POWER SECTOR
In numerous countries, the power sector has transformed rapidly in
recent years, driven by the increased penetration of variable wind
and solar power.16 At least nine countries produced more than
20% of their electricity generation from VRE in 2020: Denmark,
Uruguay, Ireland, Germany, Greece, Spain, the United Kingdom,
Portugal and, for the first time, Australia.17 (p See Figure 52.)
Cost declines in wind, solar PV and battery technologies have
profoundly impacted the rate of deployment of renewables in
power systems. Solar PV and onshore wind have become the
cheapest sources of new generation for around two-thirds of the
world’s population.18 Battery storage has become the most cost-
effective new-build technology for “peaking” services in natural
gas-importing areas such as China, Europe, and Japan, and the
ability of batteries to provide peak capacity has been found to
improve as shares of solar electricity increase, due to a changei
in generation patterns.19
Declining costs have made renewables more accessible,
prompting numerous major multinationals to commit to achieving
100% renewable energy supply over the coming decade. Many
have been driving innovation in the procurement and application
of renewable energy.20 (p See Feature chapter.)
With the growth of VRE, the adaptation of power systems is
occurring on several fronts. Many interventions have focused on
maintaining or increasing system flexibility. As the grid evolves,
flexibility is essential to ensuring safe and economical service
delivery. Some of the key adaptations observed during 2020
involved:
competitive wholesale market design to reward or promote
flexibility and to allow for accurate pricing and remuneration of
capacity and ancillary services from VRE and energy storageii;
the wider integration of flexibility and ancillary services from
sources of supply and demand, and from inverter-based
energy resources;
advances in the forecasting of electricity generation and
demand, with the aid of advanced digital technologies; and
enhanced grid interconnections and grid management systems
to promote new linkages between VRE sources and demand
centres, and to optimise the use of existing infrastructure.
Note: Figure shows countries among the top 15 according to the best available data at the time of publication. Several smaller countries with low total
generation and/or high imports are excluded from this list.
Source: See endnote 17 for this chapter.
FIGURE 52 .
Share of Electricity Generation from Variable Renewable Energy, Top Countries, 2020
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i A “black start” is the process of restoring power in a power grid following a total or complete shutdown. Black starts have traditionally been supported by
hydropower or non-renewable generators.
RENEWABLES 2021 GLOBAL STATUS REPORT
COMPETITIVE WHOLESALE ELECTRICIT Y MARKET DESIGN
Many electricity markets source essential ancillary services –
such as operating reserves, voltage support and “black start”i
capabilities – from conventional generators based on fossil gas,
steam and hydro turbines. Market adaptations are required to
enable the procurement of these and other services from VRE
generators, energy storage systems and sources of flexible
demand.21 To this end, market rules were adapted in several
electricity markets during 2020 to allow for the participation of
ancillary services from distributed energy resources.
In the United States, the Federal Energy Regulatory Commission
instituted market reforms that allow behind-the-meter VRE
generators, EVs, batteries and flexible demand resources to
participate in wholesale electricity markets in an aggregated
manner.22 At the state level, the California Public Utilities
Commission set new interconnection policies for distributed
resources (including EVs) and behind-the-meter solar and
batteries, which may allow these resources to incorporate
flexibility into the grid.23 The UK system operator National Grid
implemented several mechanisms to procure grid support from
distributed energy resources, including communication and
control signals that will allow wind farms to provide voltage
and frequency response as well as generation reserves.24
INTEGRATION OF FLE XIBILIT Y AND ANCILL ARY SERVICES
FROM SOURCES OF SUPPLY AND DEMAND
In conventional power systems with low VRE shares, the ability
to balance generation and demand is obtained primarily from
flexible or “dispatchable” conventional generators that adjust
their output to follow demand.25 With rising VRE shares in some
power systems, the need for flexibility also has increased, with
hour-to-hour ramping requirements growing in numerous major
power systems including in China, the European Union (EU),
India and the United States.26
In some cases, the flexibility of conventional generators has
been enhanced in parallel with rising VRE shares. This has
helped reduce the curtailment of both VRE and conventional
generation, for example during periods of low demand and high
VRE production, when conventional generators are increasingly
required to ramp down production.27 In parallel, flexibility and
other ancillary services also have been recruited from VRE
generators themselves, which have been continuously adapted
to contribute essential reliability services to power grids, including
frequency control and regulation, inertial response, voltage
regulation, reactive power voltage support (also known as power
factor correction) and even black start capabilities.28 In Chile, for
example, the National Electricity Coordinator approved during
2020 the provision of ancillary services from a 141 MW solar PV
plant, including frequency management. During tests, the plant
was shown to provide better performance for load response than
equivalent gas-powered generators.29
A novel demonstration of ancillary service provision by VRE
generators occurred when the UK energy utility ScottishPower
used an offshore wind farm to restore part of the electricity grid
after an outage, demonstrating the world’s first “black start” using
VRE.30 The ability of solar and wind inverters to provide this type
of “grid-forming” service was the subject of US government-
funded research and development (R&D) by GE, which aims to
improve synchronisation between multiple grid-forming inverters
and to improve the stability of power systems with high shares of
variable renewables.31
Demand flexibility also is an important enabler of higher shares
of VRE, primarily through demand response initiatives that use
market signals – such as time-of-use pricing, incentive payments
and penalties – to influence the electricity use of consumers.32
In 2020, demand response technologies were supported by
enabling policies in countries such as Japan and the United
States, and in California demand response provided significant
system support during heat waves that put severe pressure
on the power system.33 Nonetheless, while demand response
capacity has grown in recent years, particularly in Australia, the
United States and some European countries, global growth rates
remain below those targeted by sustainable development plans
such as the United Nations Sustainable Development Strategy.34
Energy storage in the form of pumped hydropower has long
contributed to grid stability. More recently, however, other storage
technologies including batteries have been used to provide both
200
i Virtual power plants use digital technologies to co-ordinate and control energy demand, distributed generation and energy storage. See Glossary.
ii High-voltage direct current (HVDC) lines are used for high-efficiency, bulk transmission of power over large distances.
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grid flexibility and ancillary services.35 In some cases, batteries
have started to compete in capacity markets, for example in
the United Kingdom, where more than 100 megawatts (MW)
of utility-scale battery assets secured demand-side response
contracts in capacity auctions during 2020.36
Aggregators have extracted grid services from fleets of behind-
the-meter batteries, along with other distributed energy
resources, through the use of digital technologies that can
control fleets of assets providing flexibility services. By late
2020, the system operator National Grid, which operates in
both the United Kingdom and the United States, had enrolled
13 aggregators and 900 individual sites on a centralised demand
management system across the US states of Massachusetts,
New York and Rhode Island to provide more than 400 MW of
flexible load capacity.37 In the United Kingdom, the aggregation
platform developed by GridBeyond, a company specialising
in advanced demand response, enabled the participation of
both batteries and sources of flexible demand in auctions for
grid balancing services conducted by National Grid.38 In Japan,
Next Kraftwerke, a German operator of “virtual power plantsi”,
partnered with Toshiba to aggregate privately owned VRE and
energy storage resources to provide grid balancing services in
the control reserve market, which will allow participation of these
sources starting in April 2022.39
Fleets of EVs have been aggregated to provide grid balancing
services in the Netherlands, Norway, and Sweden, and
the provision of similar services is planned in Germany.40
(p See Electric Vehicles section in this chapter.)
ADVANCES IN FORECASTING OF GENERATION AND DEMAND
Digital technologies have begun facilitating more accurate
forecasting of both power system demand and VRE generation.
This has allowed system operators to better anticipate VRE
availability and to more cost-effectively balance generation and
demand in short-term energy market scheduling. This can in
turn reduce fuel costs, minimise curtailment of VRE and improve
system flexibility and reliability.41
With the growing number of grid-connected, distributed VRE
resources, generation forecasting has become increasingly
complex and specialised.42 Many grid operators have partnered
with forecasting companies to more accurately predict VRE
availability. For example, in Australia, the forecasting company
Solcast started a demonstration project in 2020 for the South
Australian grid, aimed at providing higher-resolution forecasts
updated with greater frequency than pre-existing alternatives,
that are designed specifically for the Australian energy market.43
Artificial intelligence has potential applications in increasing
complex generation forecasting, and in managing and
leveraging real-time supply and demand information produced
by decentralising power systems.44 In 2020, US federal funding
was announced for 10 research projects that will use artificial
intelligence and machine learning technologies to predict system
failures, schedule maintenance, address data quality issues and
combine disparate datasets, with the aim of improving both
forecasting and maintenance activities.45
Electricity demand fore casting has started to move away from
traditional worst-case methodologies to probabilistic studies
that involve intense computation processes.46 Advances in
computational power are allowing artificial intelligence and
machine learning systems to more rapidly analyse data from
energy users, bringing a bottom-up view to electricity demand
forecasting and enabling more precise balancing of demand with
available generation.47
ENHANCED GRID INTERCONNECTIONS AND
GRID MANAGEMENT SYSTEMS
Grid infrastructure can connect regions with strong wind and
solar resources to demand centres; aggregate VRE resources
over larger geographic areas to mitigate the effects of variability;
and link or expand electricity markets to increase market scope
and efficiency.48 Conversely, grid infrastructure constraints
have become a significant bottleneck for the integration of
VRE capacity.49 In the United States, 245 clean energy projects
at an advanced permitting stage were withdrawn between
2016 and 2020, due largely to limited transmission capacity.50
Large transmission projects also have faced regulatory and
developmental hurdles, notably in Australia, Germany and
the United States, due to public opposition, environmental
concerns, and the complexity of land-use agreements and
approval processes.51
Despite these barriers, numerous major transmission projects
were advanced in 2020, driven by demand for grid capacity
from VRE generators.52 (p See Figure 53.) In the United
States, around 225 kilometres of the planned 1,600 kilometre,
USD 2.6 billion Gateway West line was completed, which will
eventually connect wind farms in the state of Wyoming with
electricity markets in other western states, via Idaho.53 Other
major transmission projects, including long-range high-voltage
direct current (HVDCii) projects, were in planning across the
country.54 In India, seven new transmission projects were
approved, which will allow the grid interconnection of new
renewable energy parks in the country.55
South Africa’s public utility Eskom announced plans in
2020 to implement
an SAR 118 billion
(USD 8.4 billion)
transmission expansion
project to accommodate
new generation targets,
including 25 gigawatts
(GW) of wind and solar
by 2030.56
Digital technologies are
increasing the usable
capacity of existing
transmission infrastructure,
often a barrier to wider
VRE deployment.
201
Trans West Express
United States
1,174 km
Renewables interconnection
Status: Planning
Shetland HVDC Connection
United Kingdom
260 km
Renewable interconnection
Status: Planning
SuedLink Transmission Project
Germany
750 km
Wind and solar interconnection
Status: Planning
Changji-to-Guquan
Transmission Line
China
3,293 km
Wind and solar interconnection
and curtailment reduction
Status: Operational
La Niña–Piura Nueva
Ecuador and Peru
635 km
Hydropower interconnection
Status: Procurement
Juno Gromis
South Africa
282 km
Wind and solar interconnection
Status: Planning
Project EnergyConnect
Australia
900 km
Wind and solar interconnection
Status: Planning
Ajmer Phagi
India
134 km
Wind and solar interconnection
Status: Operational
Grain Belt Express
United States
1,260 km
Renewables interconnection
Status: Planning
RENEWABLES 2021 GLOBAL STATUS REPORT
Note: All projects are high-voltage direct current (HVDC).
Source: See endnote 52 for this chapter.
FIGURE 53.
Transmission Projects to Integrate Higher Shares of Renewables
Several cross-border transmission projects were under
construction or in planning during 2020. A new transmission
line being built between the United Kingdom and France was
one of several planned HVDC interconnections linking European
electricity markets, with the objective of improving overall system
flexibility and stability.57 In Australia, an HVDC connection was
proposed to connect solar generation in the country’s Northern
Territory with the city-state of Singapore.58
The digitalisation of power networks has helped to increase
the efficiency and usable capacity of existing infrastructure.
Digital technologies and methodologies – including power flow
controls, dynamic line ratings and topology optimisation – can
prioritise connections in the network that are below capacity in
real time, reducing the need for infrastructure upgrades.59 Several
companies were developing technologies in these areas during
2020, including a number of start-ups.60
Many grid operators have expanded the digitalisation of grid
control rooms, improved data management and communication
technologies, built more robust security and enabled remote
operations.61 These efforts were accelerated in 2020 as lockdown
measures related to COVID-19 forced many grid operations staff
to work remotely.62
Changes also occurred at the level of the sub-station, where
analogue communication and control systems were replaced
with integrated digital solutions that enhance system visibility,
operations and diagnostics; in India, for example, digital
automation systems were retrofitted at more than 100 sub-
stations over the past decade.63 Improved data management
capabilities at both the control room and sub-station levels
of these network nodes supports the creation of “digital
twins” – predictive grid simulations that promise to streamline
maintenance.64 Grid simulation systems, such as GE’s
Distribution Operations Training Simulator (DOTS), were used
to train grid operations personnel and to run scenario analyses
that cater to the growth of distributed energy resources.65
In some cases, digitalisation has prompted a shift of control
away from centralised control rooms at the transmission level
to smaller decentralised control points in the distribution
system. WePower, a blockchain-based renewable energy
financing and trading platform developed in Lithuania, was
piloted in several markets, giving electricity distributors a
more central role in the management of distributed energy
resources and enabling the localised trade of electricity.66
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i Biofuel oil is a fuel oil produced through the pyrolysis of biomass or municipal solid waste. Bio-LNG is a renewable alternative to natural gas that is produced
during the anaerobic digestion process of food or animal waste.
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ADVANCES IN THE INTEGRATION
OF RENEWABLES IN
TRANSPORT AND HEATING
In contrast to the power sector, shares of renewables in global
transport and heating systems remained low in 2020, accounting for
less than 4% of total final energy consumption in transport and less
than 11% in heating and cooling.67 (p See Global Overview chapter.)
Integrating renewables in both transport and heating systems
requires planning and adaptation to enable or increase the
blending or substitution of fossil energy with renewable alternatives
such as direct solar thermal or geothermal heat, biofuels, biogas
or renewable hydrogen. Alternatively, electrification of end-uses
within these sectors can enable consumption of variable or other
forms of renewable electricity. In many cases, these adaptations
require wide-ranging changes to the infrastructure and
technologies that both deliver and consume energy, such as the
adaptation of gas pipelines to accommodate renewable hydrogen,
the implementation of new safety standards, and the replacement
or conversion of heating systems and vehicles.68 Many of these
efforts faced cost barriers in 2020 as oil prices plummeted on the
back of reduced demand during COVID-19 lockdowns.69
Despite limited overall progress in transport, certain segments
saw notable pre-commercial and commercial activities that
supported the integration of renewables. Integration in road-
based transport was advanced mainly through the electrification
of vehicles (p see Electric Vehicles section in this chapter). By
contrast, efforts to use renewables in the aviation sector were
focused mostly on the use of advanced biofuels, as well as the
early-stage development of aircraft adapted to use renewable
hydrogen. In September 2020, the world’s largest aircraft
manufacturer, Airbus (France), announced three concept designs
for hydrogen aircraft, along with plans to bring the first emission-
free passenger aircraft to market by 2035.70 Smaller prototypes
for electric and fuel cell passenger aeroplanes were tested in
2020 in both Canada and the United States.71
A range of renewable fuel types were either available or under
development for shipping applications as of 2020. Of these,
biodiesel, biofuel oil and bio-liquefied natural gas (LNG)i were
commercially available.72 (p See Bioenergy section in Market
and Industry chapter.) Others such as biomass-to-liquid and
renewable hydrogen and ammonia remained pre-commercial.73
In 2020, hydrogen ships were under development in Europe and
Japan, while the world’s first electric container ship, the Yara
Birkeland, was launched in Norway.74
Efforts also were under way to integrate renewables into rail
transport, which is already widely electrified and can directly
access growing shares of VRE in a number of markets.
Countries such as India and Scotland advanced plans in 2020
to decarbonise rail transport through wider electrification of
diesel-based networks, and the parallel implementation of VRE
capacity.75 A train running on renewable hydrogen also was
piloted in the United Kingdom during the year.76
Heat pumps are a mature and widely deployed technology and
possess vast but largely untapped potential as an enabling
technology for the use of renewable energy in the heating and
cooling sectors. Along with other enabling technologies such
as EVs and energy storage, heat pumps can contribute
greatly to power system flexibility to support higher shares of
VRE. (p See Heat Pumps section in this chapter.)
The potential of heat pumps for integration of renewables was
illustrated by the Dutch transmission system operator Tennet
in early 2021, when it announced plans to use heat pumps with
intelligent controls to create up to 1 GW of flexible demand
while maximising the use of available wind and solar power.77
The UK government announced plans to aggressively scale up
the installation of heat pumps to decarbonise heating demand,
as part of the prime minister’s green industrial strategy.78
Geothermal heat, solar thermal heat and various forms of
bioenergy also were being used for heating and cooling. (p See
Bioenergy, Geothermal and Solar Thermal sections in Market
and Industry chapter.)
Electrification efforts faced
cost barriers in 2020 as
oil prices
plummeted
on the back of reduced
demand during COVID-19
lockdowns.
203
POWER
TRANSPORT THERMAL
Renewable
energy
Demand �exibility
and storage
Energy
storage
Energy
storage
Renewable
Hydrogen
RENEWABLES 2021 GLOBAL STATUS REPORT
ENABLING TECHNOLOGIES FOR
SYSTEMS INTEGRATION
Heat pumps, electric vehicles and energy storage are important
end-use technologies, supporting the integration of renewables
and contributing to greater flexibility in power systems.79
(p See Figure 54.) All of these technologies experienced
increased sales in 2020 despite the onset of the COVID-19
pandemic. While most of the technologies are well known,
their level of uptake remains low relative to their potential. For
example, heat pumps are widely present in new residential
buildings in several countries, yet they still represent less than
5% of the global market for heating appliances.80 EVs occupy
only a small share of the vehicle market despite surging
adoption in recent years. Meanwhile, the need for and interest
in energy storage has increased with rising integration of
VRE in power systems worldwide.
Source: See endnote 79 for this chapter.
FIGURE 54.
Coupling of the Power, Thermal and Transport Sectors
204
i In official statistics, heat pumps also can be recorded as “reversible air conditioners”, depending on the energy services they provide. Typically, if the appliance
supplies energy only for cooling, it is considered an “air conditioner”, despite the fact that it is reversible. This chapter endeavours to report official statistics for
heat pumps that are in use to provide energy for both heating and cooling.
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HEAT PUMPS
Heat pumps are commonly used to meet heating and cooling
needs for residential, commercial and industrial applications
– such as space heating and cooling, water heating, freezing
and refrigeration – within a wide range of temperatures.81 Heat
pumpsi typically are reversible units that can provide both heating
and cooling functions by drawing on one of three main energy
sources: the ground, ambient air and bodies of water.82 During
operation, these systems use an auxiliary source of energy (such
as electricity or fossil gas) to transfer ambient energy from a low-
temperature source to a higher-temperature sink in a refrigeration
cycle.83 Ambient heat sources include air, water, geothermal
heat and different types of waste heat (such as from industrial
processes and sewage treatment).84
Depending on the inherent efficiency of the heat pump itself,
its external operating conditions and the system design, heat
pumps that use varying ambient sources of energy differ in their
installation costs and overall efficiency.85 In general, heat pumps
are highly efficient heating and cooling devices.
The most efficient systems, operating under optimal conditions,
can deliver three to five units of thermal energy (either heating
or cooling) for every one unit of external energy consumed.86
The difference between the energy delivered and the energy
consumed is considered the renewable portion of the heat
pump output, regardless of the external energy source.87 When
the auxiliary energy used to drive the heat pump is renewable,
so is 100% of the output of the heat pump.88
Electric heat pumps are among the most cost-effective solutions
for decarbonising thermal energy, notably in buildings, and can
be used in various environments, even in colder climates.89 When
used with appropriate control measures and thermal storage
(e.g., thermal mass, hot water tanks, chilled water), they also can
increase power system flexibility by using (surplus) solar and
wind power, and coupling electricity generation with heating
and cooling devices that have flexible demand characteristics.
Adding large-scale heat pumps to district heating systems
can increase flexibility through their inherent thermal storage
capabilities.90
When the energy used
to drive a heat pump is
renewable, so is
100% of
its output.
205
i Many of these units are used only for cooling, while heating demand is met via district heat or other sources.
ii Refers to residential and commercial units that are used for both heating and cooling. This number also includes ductless split units that are used for cooling only.
RENEWABLES 2021 GLOBAL STATUS REPORT
HEAT PUMP MARKETS
Although heat pump technology is widely used in the residential and
commercial sectors, limited availability of data related to this market
remains a barrier to full assessment of global heat pump uptake.
Globally, air-source heat pumps accounted for the highest sales
volumes of all heat pump technologies in recent years, followed by
ground-source heat pumps.91 Although heat pumps are the most
common heating technology in new buildings in several countries,
they met only 5% of global building heating demand in 2019.92
In the Asia-Pacific region, despite subsidies in Japan and
northern China favouring heat pump adoption, uptake has
slowed due to a decline in Chinese infrastructure investment
and because natural gas boilers are favoured under China’s coal
phase-out plan (as a less-expensive alternative to coal boilers
in residential heating).93 Additionally, because China does not
classify heat pumps as a renewable technology at the national
level, the devices cannot benefit from the clean heating subsidy
offered in the country’s north.94 Even so, more than 117 millioni
heat pumps were sold nationwide in 2020, virtually all (99%)
of which were air-to-air heat pumps, with the rest being air-to-
water devices.95
In Japan, air-source heat pumps dominated heat pump sales in
2020, although the total number sold fell 0.7% from the previous
year (to 10.7 million in 2020, down from 10.8 million in 2019).96
This drop was due to lower demand in the commercial sector
(down 14.3%) and only minor growth in the residential sector
(up 0.6%).97 Japan also is a significant market for heat pumps
for water heating, sales of which increased 30% since 2015 to
more than 500,000 water heaters sold in 2020.98
The capability of heat pumps to provide both heating and
cooling is a key factor behind their increased adoption in
North America.99 The US heat pump market continued to grow,
with 3.4 million units sold in 2020, up nearly 10% from 2019.100
The majority of demand comes from new buildings and the
replacement of oil and propane furnaces.101 In Canada, more
than 530,000 air-source heat pumpsii were sold in 2020, up 6%
from 2019, thanks to an increase in residential installations (up
13%) that counterbalanced a decline in the commercial sector
(down 21%).102
In Europe, despite facing shortages in the supply chain due to
the COVID-19 crisis, 1.6 million heat pumps were installed in
2020, up 5% from the previous year.103 France (394,000 units
sold), Italy (233,000) and Germany (140,000) were the regional
leaders, totalling 48% of all sales.104 Spain, Sweden, Finland,
Norway, Denmark, Poland and the Netherlands rounded out
the top 10 countries.105
Germany experienced a 40% increase in heat pump installations,
for a cumulative total of more than 1 million units by year’s end,
entering the top three in Europe for the first time.106 Uptake in
the country was boosted by an aggressive new subsidy scheme
that aims to accelerate heat pump deployment (subsidising
35% of the cost in new construction and renovations and up to
45% if the heat pump replaces an oil-fuelled boiler).107 Similar
support schemes exist in France – where the level of subsidy
depends on household income – as well as in Italy.108 The United
Kingdom has proposed a target of 600,000 annual heat pump
installations by 2028.109
In industrial processes, the growing application of heat pumps for
temperatures below 100 degrees Celsius (°C) has demonstrated
the reliability and efficiency of waste heat recovery for industrial
processes, directly combining cooling and heating demands.110
However, despite the technology’s availability and potential,
heat pumps are still not widespread in the sector, even for new
installed capacity where fossil fuel heating equipment remains
the standard.111 This is due, among others, to a lack of knowledge
and awareness on the part of end-users and to a capital cost
that remains high.112
Heat pump uptake slowed
in Asia-Pacific in 2020, while
the market rose
10% in the US, 6% in
Canada, and 5% in Europe.
206
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HEAT PUMP INDUSTRY
The heat pump industry in 2020 was characterised by several
trends, including company acquisitions, new solutions integrating
heat pumps with other energy devices, and the development of
components adapted to refrigerants with low global warming
potentials, and those for ground-source heat pumps.
Several acquisitions of companies occurred throughout the
year. NIBE (Sweden) completed six acquisitions, including of:
water heater manufacturer TIKI Group (Serbia), the heat pump
manufacturer Waterkotte GmbH (Germany), a 50% share in
the Üntes group of companies (Turkey), a 51% share in Nathan
Holding B.V. (Netherlands), a 60% share in VEÅ AB (Sweden)
and an 87.5% share in the element company Termotech s.r.l.
(Italy).113 In addition, Legal & General Capital (UK) acquired
a 36% stake in the ground-source heat pump firm Kensa
(UK), with the aim of establishing a portfolio of companies
decarbonising heat and transport.114 Bosch Thermotechnology
(Germany) acquired a controlling share in Electra Industries
(Israel), a manufacturer of heat pumps based in Haifa.115 After
installing heat pumps in its own stores, the retailer IKEA
(Sweden) decided to commercialise residential heat pumps in
Switzerland as part of its “clean energy offer”.116
Both start-ups and well-established companies have begun
offering or exploring energy solutions that integrate heat
pumps with renewable or storage technologies. In 2020, the
US Department of Energy explored existing European heat
pump modular solutions that, by reducing the complexity of
installation, could offer an effective solution to mass renovation
of existing buildings in the United States and elsewhere.117
LG Electronics (Republic of Korea) launched a hybrid system
in early 2021 combining a heat pump, a solar PV system and
battery storage to provide residential and small commercial
buildings with heat and electricity.118 The system also includes
an energy management system, controlled by a software
application, to maximise self-consumption.119
Factory Zero (Netherlands), Nilan (Denmark) and Drexel und Weiss
(Germany) have proposed integrating a heat pump, hot water tank,
ventilation system, solar PV system and monitoring equipment in a
single “box”.120 Such integrated systems, designed for use in nearly
zero-energy buildings, have the potential to unlock the US retrofit
market and to help the EU optimise the heating and cooling energy
consumption of buildings through mass renovation.121
The heat pump market continues to be dominated by vapour
compression technologies; however, opportunities exist for
innovation to address overall efficiency of the system, operation
in cold climates and digitalisation to improve integration with
electricity grids.122 Innovation in Europe was driven in part by the
EU’s “F-gas” regulation, which gradually phases out the sale and
manufacture of fluorinated gases – substances used mainly as
refrigerants in air conditioning and other refrigeration systems
with a high global warming potential – and encourages their
replacement by alternatives with low global warming potential.123
Heat pump manufacturers have focused on developing solutions
to replace the refrigerants necessary for the exchange of heat
within heat pump systems with HFO (hydrofluoro-olefin) and
hydrocarbon refrigerants as well as carbon dioxide and ammonia
– all of which have lower global warming potential.124 Adapted
components, such as compressors and heat exchangers, have
been developed to accommodate the new refrigerants.125
Several notable ground-source heat pump pilot projects were
approved, implemented or researched in 2020. The US state
of Massachusetts approved two pilots for neighbourhood-
wide deployment of the ground-source heat pump innovation
concept GeoMicroDistrict, which uses the existing natural
gas infrastructure to transfer thermal energy between a
shared district water loop and a building’s heating and cooling
distribution systems.126 In the United Kingdom, a housing
provider started installing a demonstration project in 300
homes to show how ground-source heat pumps with digitalised
heating controls can reduce heating costs for residents and
help balance the electricity grid.127 A study in Mongolia, where
temperatures can drop to minus 40°C, revealed that ground-
source heat pumps were the most cost-effective and low-carbon
solutions for heating.128 Meanwhile, the US ground-source heat
pump company Dandelion Energy raised USD 30 million to
scale up its technology and develop its product further.129
For processes requiring temperatures above 100°C, current
research, development and demonstration is focusing on the
100-200°C range.130 The low priority of industrial heat pumps in
the EU research programme Horizon 2020 limited the number of
European projects.131 However, some national projects focusing
on the 100-200°C range exist in Scandinavia and the Netherlands
and have shown that heat pumps can achieve significant energy
savings and emission reductions.132
In recent years, innovation in digital technologies to integrate
heat pumps and electric grids has begun allowing them to benefit
from operational cost reductions using demand-side flexibility
as well as enabling new business models.133
207
i Electric vehicles include any transport vehicles that use electric drive and can take an electric charge from an external source, or from hydrogen in the case of
fuel cell EVs. See Glossary.
ii Fuel cell electric vehicles represent a small share of the total EV market, accounting for less than 0.5% of total sales in 2020.
iii Including EU Member States and members of the European Free Trade Association (Iceland, Liechtenstein, Norway and Switzerland).
Sales, million units
Sales in million units 2020 share of global sales
0
0
0.5
1.0
1.5
2.0
2.5
3.0
0.5
1.0
1.5
2.0
2.5
3.0
20162015 2017 2018 2020
20162015 2017 2018 2020
XXXXXXXX
XXXXXXXXXX
XXXXXXXXX
XXXXXXXXX
XXXXXXXXX
XXXXXX
38.9%38.9%
13.2%13.2%
9.9%9.9%
6.2%6.2%
5.9%5.9%
20.5%20.5%
5.4%5.4%
Rest of World
Rest of Europe
United Kingdom
France
United States
Germany
China
5.4 %5.4 % Rest of World
20.5 %20.5 %
United Kingdom5.9 %5.9 %
France6.2 %6.2 %
United States9.9 %9.9 %
Germany13.2 %13.2 %
Rest of Europe
38.9 %38.9 % China
RENEWABLES 2021 GLOBAL STATUS REPORT
ELECTRIC VEHICLES
Electric vehiclesi are an important end-use for renewable energy,
as they allow the displacement of fossil fuels in key transport
modes, mainly in road and rail transport. On the demand side, EVs
achieve a double benefit: not only are they more energy efficient
than vehicles with internal combustion engines, but the required
electricity can be supplied more readily from a wide variety of
renewables. Allowing and interrupting the battery charging to
coincide with renewable power generation could help integrate
larger shares of VRE.134 On the supply side, technology such as
vehicle-to-grid can turn EVs into energy storage devices, allowing
batteries to store energy from the electricity grid during off-peak
periods and then to discharge it back to the network when it is
most needed, increasing the overall flexibility of the grid.135
In 2020, key developments continued to focus on electric cars
(passenger EVs), whereas electrification efforts for marine
vehicles and aviation remained limited.136 The rise in the number
of EVs can be explained by the favourable support policy context
(e.g., fiscal incentives, tightening of emission standards, support
for charging infrastructure) and by the benefits such vehicles
offer.137 Consumers in Europe and the United States remained
attracted, by order of importance, to the environmental benefit,
the economic savings, the ease of driving and the novelty value
of owning new technology.138
ELECTRIC VEHICLE MARKETS
While global car sales decreased in 2020 – falling 14% from the
previous year, according to preliminary market data – global
sales of electric cars (including both battery electric vehicles and
plug-in hybridsii) resisted the COVID-19-induced downturn with
2.9 million units sold, up 41% from 2019.139 Among other factors, this
is attributed to favourable existing policies, lower battery costs and
the fact that EV buyers are mainly from high-income households,
which tended to be less affected by the crisis.140 As a result, the
market share of electric cars in new car sales reached 4.6% in
2020, surpassing the 2019 record of 2.7%, and the global stock of
electric cars grew to exceed 10 million units.141 (p See Figure 55.)
Europeiii was the only market that did not experience lower
electric car sales during the first half of 2020 – showing a 55%
increase – whereas global EV sales were on average 15% lower
due to lockdown measures that affected both the supply and
demand.142 For the full year, electric car sales in Europe were
up 142% compared to 2019 (reaching almost 1.4 million units),
surpassing China for the first time since 2015 (with 1.16 million
units sold, only a 9% increase).143 The United States occupied the
third position with 296,000 units sold despite a 10% decrease
compared to 2019.144 Japan and Australia were the only major
markets where the EV market declined more than overall car
sales in 2020.145 Norway remained the leading country in EV
market share (75% in 2020), followed by Iceland (52%) and
Sweden (32%).146
Note: Includes battery electric passenger vehicles and plug-in hybrid passenger electric vehicles.
Source: IEA. See endnote 141 for this chapter.
FIGURE 55.
Electric Car Global Sales, Top Countries and Rest of World, 2015-2020
208
i Instead of using an onboard battery, trolley buses draw power from overhead wires.
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As of the end of 2020,
around 290 million
electric two- and three-
wheelers were on the
road globally.147 Around
one-third of all units sold
during the year were
electric, and 99% of new
registrations were in
China, with most of the
rest also in Asia.148 The
Indian market fell 5.5%
in 2020, with more than 25,000 electric two-wheelers sold.149
While still being a minor market, the European market grew
rapidly (up 30%).150 Electric micro-mobility (particularly e-bikes)
increased greatly in the second half of 2020, benefiting from the
implementation of new bike lanes and other mobility measures; in
the United States, e-bike sales more than doubled for the year.151
China remained the main electric bus market in 2020 (up 9% in
2020) and accounted for 99% of global sales from 2016 to 2020;
however, adoption of the buses increased worldwide, especially
in Europe (up 7%).152 Electric buses were the second largest
category of EV spending (based on preliminary sales data and
estimated vehicle prices) after private vehicles.153 Still, annual
spending in this sector continued its downward trend, totalling
USD 11 billion in 2020 (down 48% since 2016).154 This was due
mainly to changing market dynamics in China, specifically
a reduction in e-bus prices, combined with a decrease in
purchase subsidies and market saturation in large cities, which
slowed annual sales.155
Around 4,000 electric buses (including battery electric, plug-in
hybrid, trolley busesi and fuel cell buses) were circulating in
Europe, representing 1% of the total fleet.156 Around 2,100 new
electric buses were registered in 2020, up 22% from 2019.157
Denmark led in the market share of new e-buses (78%), followed
by Luxembourg (67%) and the Netherlands (65%).158 In Latin
America, 2,000 buses – less than 1% of the region’s fleet – were
electric in 2020, despite steady interest and the fact that Santiago,
Chile has the largest number of electric buses of any city outside
of China (400 added in 2020 for a total stock of more than 800).159
Bogotá (Colombia) added 470 electric buses in 2020 and placed
an order for 596 more.160
In North America, only 580 new electric buses were registered
in 2020, down nearly 15% from 2019.161 California leads in US
deployment due to the state’s commitment to buy only electric
buses (battery electric or fuel cell) from 2019 onwards.162 India
increased electric bus registrations 34% to 600 in 2020.163
Alongside the increased adoption of EVs, charging
infrastructure is expanding as well. Investment in EV charging
infrastructure has surged since 2016 and constituted a small
portion of the spending on new cars in 2020 (USD 4.1 billion in
public charging and USD 2.1 billion in home charging).164 The
number of public charging stations installed globally totalled
1.3 million in 2020, up 45% from the previous year, with most of
the infrastructure built in China and Europe.165
In China, an estimated 10,000 new public and private charging
stations were installed monthly in 2020, due mainly to the
government response to the COVID-19 crisis, which included
high investments in charger installation to stimulate the
economy.166 China had a total of around 810,000 chargers as of
2020, followed by Europe with 288,000 chargers.167 The United
States had only around 100,000 total charging stations due to
a lack of public support and incentives.168 Canada allocated
funds in its COVID-19 recovery plan towards deploying charging
stations to accelerate EV use.169
Globally, all urban and high-speed rail networks are electric, and
in 2019 around 75% of conventional (not high-speed) passenger
rail activity used electricity.170 The electrification of conventional
rail continued in 2020: India announced its commitment to a
100% electrified railway network by 2023, and Russian Railways
announced new electrification of freight routes in the country,
despite the fact that 86% of cargo volumes in the Russian
Federation are already served by electric trains.171 The United
Kingdom also continued the electrification of its railways, with
251 kilometres electrified between 2019 and 2020.172
ELECTRIC VEHICLE INDUSTRY
In 2020, the leading manufacturers of passenger EVs globally
were (by number of units produced) Tesla (US), Volkswagen
(Germany), General Motors (US), R-N-M Alliance (France/Japan),
Hyundai (Republic of Korea), BYD (China), BMW (Germany),
Daimler AG (Germany), PSA (France) and Volvo (Sweden).173
Tesla became the first automaker globally to produce 1 million
electric cars, and its Model 3 became the all-time best selling EV,
replacing the Nissan LEAF.174
In the European market, Renault (France) has a significant presence,
with its Zoe model replacing Tesla’s Model 3 as the best-selling
battery electric car in Europe in 2020.175 In China, three start-ups
experienced a surge in sales in 2020: Nio (one of the best-performing
US-listed Chinese companies in 2020) and Xpeng doubled their
sales compared to 2019, while LiAuto saw a 150% increase.176
In 2020, traditional automakers continued announcing plans to
shift production to EVs. Volvo started manufacturing its first fully
electric car late in the year and said that half of the company’s
global sales would be fully electric by 2025.177 General Motors
announced plans for 40% of its models to be electric by 2025
and for all of its new light-duty vehicles to be zero-emission by
2035, while Jaguar (UK) committed to being a fully electric car
manufacturer by 2025.178
The number of public
charging stations totalled
1.3 million
in 2020, with most of
the infrastructure built in
China and Europe.
209
i Pop-up pavement chargers are on-street devices that retract into the ground when not in use. EV owners can charge their cars using a standard cable and a
mobile app to locate chargers around the city. See Urban Electric, https://www.urbanelectric.london.
RENEWABLES 2021 GLOBAL STATUS REPORT
Both GM and Jaguar plan to include sport-utility vehicle (SUV)
models in their electric transition (with the Hummer and Jaguar,
respectively). Overall, nearly all major auto manufacturers –
including Audi, Ford, Honda, Hyundai and Volkswagen – already
have (or have announced) new electric SUVs in the coming
years.179 By 2020, 44% of EV models available worldwide were
SUVs.180 The increased offering of electric SUVs (100 models
globally in 2019) compared to fossil-fuelled SUVs (180 models in
2019) is not yet reflected in sales, as the vast majority of SUVs
sold (97%) are still fossil-fuelled.181
In total, 160 new EV models (battery electric and plug-in hybrid)
were launched in 2020, mainly in China (77 models, 61 of them
fully electric) and Europe (65 models, 30 of them fully electric).182
Manufacturers in North America came in a distant third, launching
only 15 new models.183
In 2020, seven truck manufacturers, including Daimler (Germany),
Ford (US), Scania and Volvo (both Sweden), signed a pledge to
stop selling diesel-fuelled trucks by 2040, a decade earlier than
previously planned – focusing instead on the development of
hydrogen battery and clean fuel technologies.184 Meanwhile,
Daimler’s Mercedes-Benz abandoned its hydrogen car
programme due to high costs and a lack of market interest.185
Several joint ventures were established in 2020, including
Marathon Motor Engineering, a company created between
Hyundai and Olympic champion Haile Gebrselassie, which began
assembling the all-electric Hyundai Ioniq in Ethiopia.186 Other
joint ventures focused on the production of specific equipment
for EVs. They included, among others: LG Electronics’ association
with the supplier Magna International to manufacture e-motors,
inverters and onboard chargers; the launch of Automotive Cells
Company, a battery manufacture created by Total and PSA (both
France); and Volkswagen’s acquisition of a more than 25% stake
in Guoxuan High-tech Co Ltd, a Chinese battery manufacturer,
in order to boost the German automaker’s market penetration
in China.187 In Japan, seven companies established the e5
Consortium, aiming to develop zero-emission electric ships.188
Innovation in the EV battery industry, and in particular in lithium-
ion batteries, was the main driver of technological progress in
the electricity storage area.189 Significant cost reductions were
achieved due to an increase in manufacturing production, growth
in battery EV sales and the introduction of new pack designs.190
(p See Energy Storage Industry section in this chapter.) With the
sharp drop in battery costs (down 89% between 2010 and 2020)
and depending on the automaker and location, EVs are nearing
the cost (with the same margin for automakers) of comparable
petrol-powered vehicles (cost parity is projected to occur by
2023).191 Tesla announced its ambition to produce EV batteries
using cobalt-free cathodes, since reducing the use of this costly
material would make EVs more affordable.192
New charging technologies, crucial for mass adoption of EVs,
also experienced significant developments. Wireless charging
has been piloted in various cities – including in UK cities to
charge taxis and in US cities to charge electric buses – and
China announced a national standard for the technology.193
Other charging innovations include pop-up pavement chargersi
(an innovation of the start-up Urban Electric Networks, which
concluded a successful trial period in 2020 and planned to start
commercial production in 2021); electrified roads (transmitting
energy directly to EVs); and lamp-post charging (such as
London’s “electric avenue”, where 24 lamp-posts were converted
by Siemens of Germany into charging units).194
In the United States, more than 35 utility-run managed charging
demonstration projects were developed in 2019, in order to
balance grid loads by changing customer behaviour or controlling
charging time, scale and location.195 Innovation also occurred
in battery charging speeds, helping to reduce a key barrier for
EV adoption; StoreDot (Israel) developed EV batteries that can
be fully charged in just five minutes, using organic compounds
combined with nano-materials.196
In 2020, around 80 vehicle-to-grid projects (mostly pilots) were in
place mainly in Europe (51) and the United States (20), involving
more than 6,700 EV chargers.197 Only six projects were initiated
during the year, involving 195 chargers, down from 9 projects
started in 2019.198
Pilot projects for hydrogen-fuelled trains are under way in the United
Kingdom and Scotland as a means to decarbonise the regional
railway network.199 Using hydrogen could be a less expensive
option than electrifying the UK’s rail system because existing
diesel trains can be retrofitted to be hydrogen powered.200 For
shipping, Japan created an academic and corporate consortium to
research integrating renewable hydrogen production systems in
cargo ships to power them during low-wind periods.201
Electric aviation remains pre-commercial, with Rolls-Royce (UK)
developing the fastest all-electric aircraft and Airbus (France)
developing electric and hybrid-electric propulsion for commercial
aircraft and partnering with Air Race E, the world’s first all-
electric aeroplane race.202 Start-up Wisk continued to progress
towards passenger trials of its autonomous air taxi service in
New Zealand.203
210
https://www.urbanelectric.london
i The terminology used to categorise energy storage by duration or discharge period varies widely in academia, industry and the media. The GSR considers
“short-duration” storage to be energy storage for less than around 10 hours, and “long-duration” refers to periods of around 10 to 100 hours. “Long-term”
or “seasonal” storage describes energy storage for periods in excess of 100 hours, typically for weeks, months and years. Pumped storage is a mature and
widely commercialised form of long-term storage.
ii Due to data limitations, Europe’s storage capacity is reported in GWh.
20202019
Lithium-ion storage
90.3%
Pumped storage92.6%
Pumped storage
Other electrochemical storage
Other energy storage
4.6 %
Molten salt
storage
0.6% 0.6%
0.4 % 0.4 %
1.8 % 1.8 %
6.9 %
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ENERGY STORAGE
Energy storage has been in use for decades. Batteries were
invented in the 1800s, and the first pumped storage projects were
implemented in the early 1900s.204 More recently, storage has been
increasing alongside the use of portable electronics, electrification
of the transport sector and the growth of VRE (mainly wind and
solar power), among others. The recent increase in VRE production
requires more flexibility in the power grid, which can be supplied
by energy storage by balancing demand and production.205 By
reducing curtailment and improving flexibility, storage technologies
have the potential to increase the share of VRE in power systems.
In buildings and industry, thermal energy facilitates temporal
shifts in renewable electricity or thermal energy supply to meet
heating and cooling demands, and can allow (surplus) renewable
electricity to serve thermal loads.206
Forms of energy storage (and key technologies) include
mechanical (pumped storage, flywheels), electrochemical
(batteries, including lithium-ion and lead-acid), chemical
(hydrogen) and thermal energy storage (molten salt storage and
hot water tanks). Depending on the type of technology, storage
duration can greatly vary: from less than 10 hours (e.g., some
batteries) to seasonal storage (e.g., pumped storage)i. Battery
energy storage systems were among the technologies with the
most activity in 2020, as they are easy to deploy and benefit from
cost reduction trends. Renewable hydrogen also experienced
lower costs and a more favourable policy context.
ENERGY STORAGE MARKETS
The COVID-19 crisis delayed the implementation of energy
storage projects in 2020, as supply chains were disrupted and
travel restrictions limited the ability to visit sites.207 However,
new electrochemical energy storage projects put into operation
reached 4.73 GW in 2020, up 62% compared to 2019, when only
2.9 GW of capacity was added to electricity systems worldwide
(nearly 30% less than in 2018).208 The energy storage market
also benefited from new opportunities in COVID stimulus
packages that aim for a sustainable recovery and carbon-
neutrality goals.209
Overall, the global operational energy storage capacity
reached 191.1 GW in 2020, reflecting 3.4% growth year-on-
year.210 (p See Figure 56.) The largest market was China (18.6%
of the global total), which reached 35.6 GW by year’s end, up
4.9% from 2019.211 The United States added 1.5 GW due to a
record fourth quarter in the deployment of front-of-the-meter
storage, to reach an estimated 23.2 GW by year’s end.212 The
European market grew 54%, adding 1.7 gigawatt-hoursii (GWh)
of storage capacity for a cumulative capacity 5.4 GWh.213 In
addition, 4 GW was either announced or under construction
across the region.214
Source: See endnote 210 for this chapter.
FIGURE 56.
Share of Global Energy Storage Installed Capacity, by Technology, 2019 and 2020
211
i In pit storages, water is stored in a pit with an insulated cover on top. See State of Green, “Large-scale thermal storage pit”, https://stateofgreen.com/en/part-
ners/ramboll/solutions/large-scale-thermal-pit-storage.
RENEWABLES 2021 GLOBAL STATUS REPORT
Pumped storage continued to represent the majority of the
installed capacity, with 90.3%, up 0.9% from 2019.215 In China,
pumped hydro capacity increased 4.9% for a total of 31.8 GW.216
(p See Hydropower section in Market and Industry chapter.)
Batteries continued their upward trend and constituted the
second largest energy storage technology by capacity. In 2020,
global battery storage capacity increased 1.7% to 14.2 GW (or
7.5% of total operating storage capacity).217 Most of this battery
capacity (92%) was lithium-ion batteries, with the rest being
mainly sodium-sulphur (NAS) batteries (3.6%) and lead-acid
batteries (3.4%).218
China surpassed 3 GW of battery capacity in 2020, up 91.2%
from 2019, thanks notably to the addition of 1,083 MW of
newly operational electrochemical storage, including the
200 MW / 200 MWh SPIC Huanghe New Energy Base project
in Qinghai province. 219 The United States also experienced
additions of large-scale batteries, surpassing the 1 GW
mark in 2020 to reach 1.76 GW of overall capacity, up 72%
from the previous year. 220 New installations totalled 734 MW
and were located mainly in California, including the world’s
biggest batteries at the time of publication: Vistra Moss
Landing (300 MW / 1,200 MWh) and the Getaway project
(250 MW / 250 MWh). 221 Mega-battery projects also were
added in nine other US states, mainly in Massachusetts
and Texas. 222
The residential behind-the meter battery sector grew strongly
in the United States, with 90.1 MW deployed just in the
fourth quarter of 2020, due mainly to rising interest among
homeowners in California.223 Germany also experienced a high
increase in residential energy storage – from 185,000 installed
units in 2019 to 285,000 in 2020 – for a combined 1.21 MW
of capacity by year’s end.224 This was driven by the growing
number of homeowners purchasing solar PV systems (which
doubled compared to 2019), combined with the fact that half
of them also invested in batteries.225 In Australia, small-scale
battery storage increased from around 1,500 units in 2016 to
more than 9,000 in 2020.226
Thanks to a decline in battery prices and an increase in wind
and solar generation, interest in renewables-plus-storage
projects – which combine wind and/or solar power capacity
with on-site batteries, creating a hybrid power plant – grew in
recent years to become a significant driver of battery storage
implementation.227 In the United States, the number of hybrid
sites doubled between 2016 and 2019, with solar PV-plus-
storage more common than wind-plus-storage.228 In 2020,
China announced several hybrid projects of more than 1 GW
of capacity, many of which opted for wind energy as the
basis of generation, combined with solar or thermal energy.229
In Japan, a 6 MW utility-scale solar-plus-storage project
became commercially operational at year’s end.230
Thermal energy storage (TES), mainly in the form of molten
salts, represented 1.5% of the global operational energy storage
capacity in 2020 (around 2.9 GW).231 Due to its advanced
technological readiness, molten salt storage is commonly
deployed in concentrating solar thermal power (CSP) plants.232
As of the end of 2020, the top five countries in installed molten
salt storage capacity in CSP plants were Spain, the United
States, South Africa, China and Morocco.233
Thermal energy also is commonly stored as water in tanks, large
pits, boreholes, underground, or in a phase change material,
which can be frozen and melted, thus storing and releasing
heat.234 The largest application of TES is in district heating and
cooling networks, including those that generate heat from solar
energy.235 In these systems, TES can decouple the demand for
district heating and cooling with available electricity generation,
enabling seasonal storage of variable renewable energy
sources.236 In early 2021, five large-scale thermal storage pitsi
were in operation in Denmark connected to the local district
212
https://stateofgreen.com/en/partners/ramboll/solutions/large-scale-thermal-pit-storage
https://stateofgreen.com/en/partners/ramboll/solutions/large-scale-thermal-pit-storage
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heating network.237 District energy systems with thermal energy
storage are present in Denmark, France, Germany, and Sweden,
countries that make up more than 60% of total thermal storage
capacity for district heating.238 Use of TES in district heating also
is rising in China, supported by the country’s 13th Renewable
Energy Development Five-Year Plan.239
Renewable hydrogen is an energy storage solution that can be
produced by using renewable electricity to power an electrolyser
that splits the hydrogen from water molecules.240 Hydrogen also
is produced directly from fossil fuels by using steam methane
reforming or coal gasification.241 More than 99% of global
hydrogen production is currently based on fossil fuels (mainly
natural gas).242
Interest in renewable hydrogen gained momentum in 2020, due
in part to low electricity prices for VRE and to reductions in the
cost of electrolysis equipment (leading to declines in production
costs); in addition, several countries announced national
hydrogen strategies and hydrogen energy frameworks (including
Chile, Norway, the Russian Federation and some European
countries).243 At the time of publication, 8 countries and the EU
had national strategies in place to support renewable hydrogen
development, and several had hydrogen roadmaps or draft
renewable hydrogen strategies in the pipeline.244 China and India
also have shown interest in ramping up their renewable hydrogen
economies.245 (p See Table 5 in Policy Landscape chapter.)
By the end of 2020, the global operating capacity for hydrogen
electrolysers was an estimated 82 MW (including all types of
hydrogen) – or less than 0.05% of the global energy storage
capacity.246 The largest renewable hydrogen production site as
of April 2021 was located in Quebec, Canada, offering 20 MW
capacity of hydrogen produced with hydropower, doubling within
a year the previous record set by Japan’s 10 MW solar-powered
hydrogen production facility.247 As of the end 2020, additional
renewable hydrogen projects of more than 130 GW were either
announced, planned or under construction (most of them
gigawatt-sized projects).248
Europe and Australia dominate the renewable hydrogen pipeline,
with 11 proposed projects of 1 GW electrolyser capacity or more.249
The largest is being developed by a consortium of European
companies that plans to use 95 GW of solar capacity to power
67 GW of electrolysers across multiple locations in Europe by
2030.250 The next largest project is the Asian Renewable Energy
Hub in Pilbara, Australia, where 16 GW of onshore wind and 10 GW
of solar capacity will be used to supply 14 GW of electrolyser
capacity.251 These are followed by projects in the Netherlands and
Germany (10 GW capacity, combined with offshore wind power
capacity), China (5 GW), Saudi Arabia (4 GW), Chile (1.6 GW),
Denmark (1.3 GW) and Portugal (1 GW).252 At a smaller scale,
the European Marine Energy Centre announced in 2020 its
plan to combine tidal power and battery technology to generate
renewable hydrogen at a pilot project in Scotland.253
Other developments related to energy storage markets included
the release in California of the first major procurement targeting
long-duration storage projects (more than eight hours storage).254
Companies answering this tender covered a range of technologies,
including pumped storage, gravity-based, compressed air, and
flow batteries, as well as the current market leader lithium-ion
batteries.255
A total of 130 GW of
renewable
hydrogen
projects were either
announced, planned
or under construction
in 2020.
213
i Each international patent family (IPF) represents “a unique invention and includes patent applications filed and published in at least two countries. IPFs are
a reliable and neutral proxy for inventive activity because they provide a degree of control for patent quality and value by only representing inventions
deemed important enough by the inventor to seek protection internationally”. See International Energy Agency, Innovation in Batteries and Electricity Storage
(Paris: 2020), https://www.iea.org/reports/innovation-in-batteries-and-electricity-storage.
RENEWABLES 2021 GLOBAL STATUS REPORT
ENERGY STORAGE INDUSTRY
During 2020, the energy storage industry saw significant cost
reductions and innovation in battery technologies, and an increased
number of collaborations to produce renewable hydrogen.
Innovation has been particularly dynamic in the electricity
storage sector, where inventions (estimated based on the
number of international patent familiesi) increased 14% annually
on average between 2005 and 2018, four times faster than
for all technology fields.256 This was driven mainly by battery
innovation, particularly lithium-ion batteries used in consumer
electronic devices and EVs.257 (p See Electric Vehicles section in
this chapter.) Lithium-ion battery costs have fallen sharply, with
prices dipping below USD 100 per kWh for the first time in 2020,
and a market average of USD 137 per kWh.258
Battery R&D during the year included research on a long-duration
solar flow battery that would benefit from a 20% efficiency record,
and solid-state batteries that could be safer and contain more
energy than traditional lithium-ion batteries (for example the
lithium-metal battery of the start-up QuantumScap).259 A power
plant in the US state of Minnesota announced a pilot deployment
of the “aqueous air” battery system, developed by the long-
duration battery start-up Form Energy, which can discharge
power capacity for up to 150 hours.260 Among other investments,
the state of California allocated USD 16.8 million for energy
storage technologies beyond lithium-ion (employing mainly
zinc), and Form Energy raised USD 70 million prior to its first
commercial deployments.261 Eos, the developer of an aqueous
zinc battery, entered the stock exchange market in 2020.262
Environmental and social concerns related to the increased mining
of lithium for battery production prompted development in new
extraction technologies from geothermal waters, with the aim of
producing “green lithium” with a reduced environmental footprint.263
Because battery technologies are driven mainly by the EV
industry, most cannot provide the type of long-duration storage
suitable to countries that have harsh climatic conditions and low
capacity for operation and maintenance.264 Moreover, the high
cost of battery technology has prohibited batteries from being
widely deployed in large-scale projects in developing countries,
even though these areas may have the greatest deployment
potential.265 To remedy this, the World Bank convened a global
partnership in 2019 fostering R&D, policies, and regulations,
and in 2020 the Bank highlighted the importance of warranties
for battery storage systems to mitigate the technical and
operational risks of projects for buyers and investors.266
In the area of renewables-plus-storage, two collaborations
emerged in the United Kingdom. The first is a joint venture
between Macquarie’s Green Investment Group and renewable
energy developer Enso Energy to develop 1 GW of unsubsidised
solar-plus-storage capacity.267 In addition, the French electricity
provider EDF partnered with the UK renewable energy
developer Octo Energy to build 200 MW of solar-plus-storage
capacity in England and Wales.268
214
https://www.iea.org/reports/innovation-in-batteries-and-electricity-storage
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Thermal energy storage technologies outside of molten salt
storage include the commercially viable thermal tanks (using
water) and solid-state (using rocks, concrete and ceramic bricks)
and liquid air variants – which made significant strides towards
commercial viability in the near term.269 A UK-based company
started developing large-scale plants whose mechanism stores
energy by supercooling air in pressurised above-ground tanks.270
Solid-state thermal storage using concrete is being developed in
China as part of a deployment of CSP demonstration projects,
and a US research programme progressed in 2020 with the
design of a pilot-scale facility, with testing expected in late 2021.271
Malta Inc. (US), a company developing pumped heat energy
storage – a long-duration energy storage technology converting
electricity to be stored as thermal energy – raised USD 50 million
in funding in 2020.272
Renewable hydrogen was a key focus of international
collaboration in 2020, with some of the world’s largest energy
companies including Enel (Italy), ENGIE (France), Equinor
(Norway), Ørsted (Denmark), Shell (Netherlands), BP (UK)
and Siemens (Germany) proposing projects, investments and
partnerships in low-carbon hydrogen.273 The United Nations’
Green Hydrogen Catapult aims to scale up hydrogen production
by 2026 and was initiated by, among others, IPP ACWA Power
(Saudi Arabia), wind turbine manufacturer OEM Envision (China),
offshore wind developer Ørsted (Denmark) and gas grid firm
Snam (Italy).274
Several countries agreed to join efforts on hydrogen development,
such as the United States and the Netherlands, which are
collaborating on collecting, analysing and sharing information on
hydrogen production and infrastructure technologies; Germany
and Niger, which established a hydrogen exploration partnership
that will expand to West Africa; and the Netherlands and
Portugal, which signed an agreement to facilitate the transport of
renewable hydrogen between the two countries.275 Additionally,
the 21 countries participating in the Clean Energy Ministerial
Hydrogen Initiative (CEM H2I) will collaborate on policies,
programmes and projects across all sectors of the economy to
accelerate the commercial implementation of hydrogen and fuel
cell technologies.276
With this rising interest, the cost of producing hydrogen from
electricity has declined, falling 40% on average between 2015
and 2020.277 However, the cost of producing renewable hydrogen
in 2020 remained around twice as expensive as producing
hydrogen using carbon capture.278
Boosted by cost declines and by national plans promoting
investment in hydrogen production (as in France, Germany and
Portugal), Europe has been centre stage for numerous new
consortia.279 In Portugal, the electric utility EDP, grid manager
REN, and industrial group Martifer, together with Danish wind
turbine manufacturer Vestas and other European partners,
announced their intention to evaluate the viability of the H2Sines
renewable hydrogen project.280 In the Netherlands, NortH2, a
consortium comprising Shell, the gas grid operator Gasunie
and the Port of Groningen, planned to develop a “Hydrogen
Valley” linking offshore wind generation to renewable hydrogen
production.281
Major electricity groups – including EDP, Enel, Iberdrola (Spain)
and Ørsted – also created the joint initiative Choose Renewable
Hydrogen to highlight hydrogen’s role and to ensure its integration
into EU COVID-19 recovery plans.282 In early 2021, Sinopec, the
Chinese oil giant and the world’s largest producer of hydrogen,
announced plans to move away from fossil-based hydrogen
production and towards renewable hydrogen; it also entered a
partnership with the world’s largest solar PV manufacturer, Longi
Green Energy Technology.283
In the United States, the hydrogen-specialised company Plug
Power raised USD 1 billion to build a gigafactory that would
produce both fuel cells and electrolysers.284 Additionally, major
energy player Xcel Energy targeted wind and solar investment in
the state of Minnesota to plan a renewable hydrogen production
pilot as well as energy storage and EV charging.285
The cost of producing
renewable hydrogen in
2020 remained around
twice as
expensive
as producing hydrogen
using carbon capture.
215
07
In 2020, United Airlines pledged to reduce its greenhouse gas emissions by 100% by 2050,
including the usage of sustainable aviation fuel.
07
enewable energy and energy efficiency have long
been known to provide multiple benefits to society,
such as lowering energy costs, improving air quality
and public health, and boosting jobs and economic growth.
Increasingly, renewables and efficiency are viewed as crucial for
reducing carbon emissions. Energy production and use account
for more than two-thirds of global greenhouse gas emissions,
and together renewables and energy efficiency have made
significant contributions to limiting the rise in carbon dioxide
(CO2) emissions.1
This is reflected by the growing number of countries pledging
to achieve net zero emissions and making emission reduction
commitments in their Nationally Determined Contributions
(NDCs) under the Paris Agreement – providing a key driver for
greater implementation of both renewables and efficiency. As of
the end of 2020, 190 parties to the Paris Agreement mentioned
renewable energy in their NDCs, while 144 parties mentioned
energy efficiency, and 142 mentioned both.2
Previous editions of the Renewables Global Status Report
have tracked the combined benefit of renewables and energy
efficiency through trends in the share of renewable energy and
in energy intensity. Energy intensity can be assessed both as
primary energy supply per unit of gross domestic product (GDP),
and as final energy consumption in an end-use sector relative
to a sector-specific metric (for example, energy use per square
metre in buildings).3 Between 2015 and 2019, the annual rate of
improvements in energy intensity slowed.4
ENERGY EFFICIENCY,
RENEWABLES AND
DECARBONISATION
Global carbon intensity has improved
due in part to an increase in renewable
electricity production, but even more so
due to greater energy efficiency, despite a
recent decline in efficiency improvements.
Increased penetration of renewables,
along with rising electrification of key
end-uses such as household appliances
and industrial processes, have contributed
greatly to improving the carbon intensity
of end-use sectors such as buildings,
industry and transport.
Despite improvements in energy intensity,
total emissions have increased, driven
by rising energy demand (particularly
electricity demand in buildings) in
developing economies and by a growing
trend towards energy-intensive transport.
K E Y FA C T S
07
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RENEWABLE ENERGY AND
CARBON INTENSIT Y
217
i A “complete” accounting of the carbon intensity of GDP includes all greenhouse gas emissions from both energy and non-energy uses. However, considering
that CO2 is the main greenhouse gas emitted by the energy sector, this chapter focuses on the carbon intensity of GDP due to CO2 emissions from energy use
and refers to this concept as “carbon intensity of GDP”.
RENEWABLES 2021 GLOBAL STATUS REPORT
However, energy intensity is an imperfect indicator for
measuring the transition to more efficient and cleaner energy
production and use. Trends in carbon intensityi – measured
here as energy-based CO2 emissions per unit of GDP – help
to better understand the full impact of both energy efficiency
and renewables. Unlike overall emissions, which until 2015
increased in parallel with GDP growth, carbon intensity of GDP
reflects the technical or structural improvements that occur in
various sectors.5 As with changes in energy intensity, changes
in carbon intensity result from a combination of factors beyond
energy efficiency measures and the deployment of renewables
alone, such as increased production from non-renewable energy
sources and the growth of more carbon-intensive industries.6
Carbon intensity of GDP can be expressed as the product of
the energy intensity of GDP and the carbon intensity of energy
(that is, the CO2 emissions associated with energy production
and use).7 Energy efficiency measures and the deployment of
renewables can bring about improvements in both of these
variables.
Renewable energy can improve the energy intensity of GDP by
reducing the losses that occur in energy transformation and thus
decreasing the amount of primary energy input that is needed
to meet existing demand. Energy efficiency, in turn, can lower
both the overall primary energy supply needed as well as the
capacity and cost of the low-carbon energy systems needed to
meet demand, thereby growing the share of renewables in the
energy mix.8
Carbon intensity can be analysed both from the perspective of
the energy sector as a whole, and with respect to the carbon
intensity of specific end-use sectors, namely buildings, industry
and transport. Some measures in these sectors – such as energy
codes for buildings or the deployment of distributed renewables,
heat pumps and other technologies for electrification – impact
carbon intensity as they can have both an energy efficiency
and a renewable energy component. Other energy efficiency
measures can play a role in each sector, including digitalisation
in the buildings and industry sectors, and fuels and vehicle
emission standards in the transport sector. In 2020, the COVID-
19 pandemic impacted the energy efficiency of all three end-use
sectors.9 (p See Sidebar 7.)
Energy production is associated with various sources of CO2
emissions. These include, among others, oil and gas extraction
and refining, fugitive emissions from mining and biofuels
production, and the combustion of fossil fuels both for electricity
production and for direct use in end-use sectors.10
Between 2013 and 2018, global energy-related CO2 emissions
grew 1.9% (0.4% per year on average), to nearly 38 gigatonnes
(Gt).11 The increase took place during a period of economic
growth – global GDP grew 23% during the five-year period – but
was slowed by improvements in the overall carbon intensity of
GDP.12 In other words, there was an overall decoupling of global
economic growth and CO2 emissions.13 These improvements
in carbon intensity were due in part to increased renewable
electricity production and, to a greater extent, to improved
energy efficiency.14 (p See Figure 57.) This was despite a decline
in energy efficiency improvements that began in 2015 and has
been reinforced by the COVID-19 crisis and low energy prices.15
218
Carbon intensity (tonnes of CO2 / million USD)
350
330
310
290
20182016201520142013 2017
-15.1%
Global carbon intensity
reduction
-2.5%
from production
of zero-emission
renewable
electricity
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Reductions in
carbon intensity:
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Note: This figure estimates the additional primary energy input that would have been required in the absence of renewable electricity uptake since 2013, all
else being equal. The estimation accounts for the difference in transformation losses between conventional and renewable electricity generation. However,
it does not account for potential feedback loops on the energy demand itself due to energy prices, structural changes in economic activity or similar effects.
The figure is not intended to provide results of a comprehensive energy model. Sources of renewable energy in this figure include those that emit no CO2 in
production of electricity. Dollars are at constant purchasing power parities.
Source: See endnote 14 for this chapter.
FIGURE 57.
Estimated Impact of Renewables and Energy Efficiency on Global Carbon Intensity, 2013-2018
Renewable energy
and energy efficiency
together help
lower carbon
emissions
per unit of GDP.
219
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 7. COVID-19 and Energy Demand in Buildings, Industry and Transport
Throughout 2020, the COVID-19 pandemic affected most aspects
of daily life across the globe, forcing individuals and communities
to pivot quickly to new routines to prevent the spread of infection.
Changes in energy use accompanied this major shift in societal
behaviours.
Full lockdown measures reduced electricity demand 20% on
average, depending on the country, with smaller effects for partial
lockdowns. As a result, renewables claimed a greater share of
global electricity generation (around 29% in 2020, up from
27% the previous year); this was in part because the output of
renewables is often less directly influenced by electricity demand.
(p See Global Overview chapter.)
In buildings, remote working caused a shift in energy
demand from commercial to residential buildings. In the first
half of 2020, electricity use in residential buildings in some
countries grew 20-30%, while it fell around 10% in commercial
buildings. Depending on home size, heating or cooling
needs, and the efficiency of computers and other information
technology equipment and appliances used at home, a single
day of teleworking can increase daily household energy
consumption 7-23%, compared with a day working at the office.
In some countries, consumers bought additional appliances
(entertainment devices, teleworking equipment, etc.), which,
coupled with the fact that people were spending more time
at home, increased total appliance energy use. However,
purchases of new, efficient appliances and replacement of old,
inefficient models improve the energy intensity of the global
appliances stock.
Most commercial buildings, even when offices remain
unoccupied, continue to consume energy to maintain
heating, ventilation and air conditioning systems and to
power computing servers. The energy intensity of commercial
buildings reportedly increased as the share of energy use from
more energy-intensive essential sub-sectors grew. For example,
food sales outlets, which largely continued to operate during
the pandemic, were more than twice as energy intensive as
the average office. Additionally, pre-COVID, around 30% of a
building’s energy was dissipated in ventilation and exfiltration
of air; as more people returned to workplaces later in 2020,
demands for higher ventilation rates (for health reasons)
increased the energy intensity of commercial buildings.
Restrictions on the ability of professional contractors to access
residential properties delayed efficiency upgrades. At the start
of the COVID crisis, global construction activity slowed an
estimated 24%, along with a 12% decrease in on-site work at
buildings, but as the sector rebounded the overall slowdown
in construction activity fell to 10% by the end of 2020. In some
markets, increased rates of do-it-yourself renovations may
have led to improved technical efficiency. For example, sales of
insulation in Australia were 20% to 40% higher in the first half
of 2020 than a year earlier, and sales at US home improvement
chains increased compared to 2019.
In industry, reduced production and consumer demand
lowered energy demand across all manufacturing sectors.
Energy-intensive sub-sectors (such as iron and steel, and
cement) saw a lower decline in their activity than less
energy-intensive industrial sub-sectors (such as textiles,
machinery and equipment). For example, the share of
automotive manufacturing in the industry sector decreased
30% in the first half of 2020 relative to the previous year,
whereas basic metals manufacturing fell only 15%. As a
result, upstream energy-intensive industries made up a
larger share of industry activity, thus increasing energy and
carbon intensity.
In transport, the major trends emerging from the crisis in
2020 were related to the impact of travel restrictions and
remote working measures on both urban transport and the
aviation sector. Long-distance passenger load factorsi in
aviation fell dramatically, with the demand for commercial
air travel dropping around 60% and rail demand declining
30%. This led to increased energy use per passenger and
per kilometre travelled, despite the decline in overall energy
use. A shift from aviation to rail can reduce energy intensity,
whereas a shift from rail to road vehicles can increase it.
For those commuting by car, teleworking is estimated
to reduce total energy consumption and emissions.
However, for commuters who normally make only short
trips by car (under 6 kilometres in the United States and
under 3 kilometres in the European Union (EU), as well as
commuters who mainly take public transport, teleworking is
estimated to produce a small net increase in total energy
demand and emissions. This is even before accounting for
the fact that smaller numbers of bus and train passengers
during 2020 increased the energy and carbon intensity of
these modes of transport, per passenger-kilometre travelled.
Due to social distancing efforts, people turned instead to
private vehicles and active modes of transport, such as
walking and cycling. Temporary bike lanes were installed
in Paris (France) and Toronto (Canada), among many other
cities, and some of these lanes have been converted into
permanent infrastructure. Consequently, energy efficiency
(per passenger-kilometre) of buses and trains decreased in
tandem with lower passenger volumes.
Globally, as sales of new cars declined in 2020, the vehicle
stock became relatively older and less efficient. However,
this was partially offset by the fact that the relative share of
electric vehicles (EVs) in new car sales rose, impacting the
average efficiency of new road vehicles.
i Passenger load factors measure the capacity utilisation of an aircraft
(i.e., how many of its seats are filled).
Source: See endnote 9 for this chapter.
220
Change in carbon
intensity of
final energy
Change in share of
modern renewables
in TFEC
0
40
20
-20
60
100
80
120
Asia
excluding
China
and India
United
States
EU-28 China India World
Change (in %)
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DECARBONISATION OF
END-USE SECTORS
Total final energy consumption (TFEC) – the energy remaining
after losses during transformation, energy sector own-use,
transmission and distribution – amounted to 378 exajoules in
2018, up 2% from the previous year.16 This energy is consumed
primarily in the three end-use sectors: buildings (residential and
commercial), industry and transport.17
CO2 emissions from final energy use reached 24 Gt in 2018.18
Around 63% of this total was direct emissions, or emissions
from sources that are directly controlled by a sector or entity
(for example, emissions from combusting fossil gas in a boiler).
The remainder was indirect emissions: these are released as
a consequence of activities within a sector or entity (such as
buildings), but they occur at sources owned or controlled by
another sector (for example, emissions from producing the
electricity that is later consumed in a building). Most indirect
emissions come from electricity production.19
Reducing indirect emissions, as well as addressing direct
emissions by improving the carbon intensity of final energy use,
are key ways to decarbonise the entire energy sector. Between
2008 and 2018, the global carbon intensity of final energy
decreased 2%.20 At the same time, the global share of modern
renewables in TFEC grew 38%.21 (p See Figure 58.)
Parts of the developed world showed a similar trend over the
decade: that is, improvements in the carbon intensity of energy
were accompanied by an increase in the share of renewables.
The United States and the EU-28 (two of the top-five emitting
regions) experienced total decreases in their carbon intensities
of 14% and 12%, respectively, during 2008-2018, together with
respective increases in the share of modern renewables in TFEC
of 56% and 80%.22
However, in certain developing and emerging countries, the rising
share of renewables in TFEC did not necessarily coincide with
an improvement in the carbon intensity of final energy. Despite
a 109% increase in renewable energy uptake during 2008-2018
(4.4% annually), China’s carbon intensity of final energy stayed
relatively constant, for a total increase of 1% (0.05% annually).23
In all Asian countries excluding China, the smaller increase in
renewables – 29% over the decade – was not enough to halt the
rise in carbon intensity, which grew 14%.24
Although the impact of increased renewable energy penetration
varies depending on local circumstances, the rising share of
renewables, together with increased electrification of key end-
uses, has contributed greatly to improving the carbon intensity
of end-use sectors.25 (p See Sidebar 8.) This highlights the
importance of other decisions (for example, phasing out coal)
that influence the energy mix, in addition to renewable energy
uptake.
Additional decarbonisation can be achieved through a
combination of direct deployment of renewables and energy
efficiency measures in the end-use sectors. By reducing overall
energy demand, or limiting its growth, energy efficiency in end-
use sectors impacts both direct and indirect CO2 emissions.
Source: Based on IEA data. See endnote 21 for this chapter.
FIGURE 58.
Change in Carbon Intensity of Final Energy Consumption and Share of Modern Renewables,
Selected Countries, 2008-2018
221
RENEWABLES 2021 GLOBAL STATUS REPORT
SIDEBAR 8. Decarbonisation Through Monitoring, Reporting and Verification Systems
Accurate data and regular monitoring are key in tracking progress
towards meeting the objectives of Sustainable Development
Goal 7 (SDG 7), which calls for “affordable, reliable, sustainable
and modern energy for all” by 2030. One such monitoring tool
is RISEi (Regulatory Indicators for Sustainable Energy), a set of
indicators used to compare countries’ policies and regulatory
frameworks towards achieving SDG 7. In particular, RISE can
help indicate the readiness of policy makers to track the carbon
intensity of end-use sectors such as power, buildings, industry
and transport.
The RISE Carbon Pricing and Monitoring indicator measures two
important aspects of regulating carbon emissions: 1) monitoring,
reporting and verification (MRV) of emissions and 2) assigning
an appropriate price to emissions. Carbon pricing is seen as an
efficient way to account for the external costs associated with
energy-related CO2 emissions. Whether or not it is economically
or politically feasible for a country to price carbon emissions, an
MRV system can be a first step towards adopting low-carbon
policies. Implementing an MRV system for emissions can help
standardise data and support decision making on policies
or investments related to carbon intensity.
Policy makers can implement an MRV system to monitor carbon
emissions on a regular basis, particularly for the most energy-
intensive sectors of the economy. A monitoring system not only
provides key data to better inform policy decision making, but
also builds institutional capacity and knowledge for regulators
to oversee economic activity transparently and effectively. In
complex economies with diverse economic sectors, an effective
approach to reporting carbon emissions is a bottom-up system
whereby individual entities report their own emissions in order
to comply with an enforced mandate, which is then verified by a
regulatory agency.
In January 2021, the Republic of Korea entered the third phase
of a bottom-up monitoring programme for its emission trading
scheme. This phase involves monitoring emissions from heat
and electricity generation, industry, buildings, transport, water
and public buildings. The programme requires an independent
third-party verifier (selected by the government) to approve the
emission reports submitted by each entity. Based on the approved
data, the Korean Greenhouse Gas Inventory and Research Center
regularly releases evaluation reports that include key emission
statistics, market performance indicators and survey results from
these entities. The information verified by regulators can provide
a foundation to monitor and quantify the mitigation impact
of investment in renewable energy technologies and energy
efficiency measures. This, in turn, can help attract international
private or public finance targeting the deployment of renewable
energy technologies.
Another bottom-up example is the Emissions Trading Scheme
(ETS) used by the European Union (along with Iceland,
Liechtenstein and Norway) since 2005, which sets a limit (or cap)
on the total amount of certain greenhouse gases that can be
emitted by covered sectors. Within the cap, companies receive
or buy emission allowances, which they can trade with one
another as needed. This regional cap-and-trade system limits
emissions from more than 10,000 heavy energy users within
Europe, including power stations, industrial plants, and airlines,
covering nearly half of the EU’s greenhouse gas emissions. As the
MRV system improved following the EU ETS’ launch trial period
(2005–2007), policy makers have used historic data to reform
the programme by adjusting the limits on the total number of
allowances via phased reforms over the past decade. This helped
the programme overcome market failures due to volatility in the
market price for allowances.
Top-down approaches, in contrast, require monitoring and
verification of an entity’s emissions by public regulators or
approved third parties. Because this kind of system has much
higher public sector staffing costs, it may be more appropriate
for use in economic sectors that have a homogenous group of
emitters, such as specialized industrial sectors. For example,
China launched the first phase of its national emission trading
scheme in January 2021ii through a federal pilot to monitor only
coal- and gas-fired power plants. Assigning federal regulators
to each power plant will help determine appropriate emission
baselines to inform not only the scheme’s design, but also energy
conservation standards for other sectors, long-term plans for
capacity retirements and China’s contributions for reducing
emissions under the Paris Agreement. However, it may not be
feasible to assign this same level of oversight to entities in all
economic sectors, especially in developing countries that have
more limited public resources.
222
Middle East
Africa
Asia and the Pacific
Americas
Europe
Number of Countries
70
60
50
40
30
20
0
10
20192010 2011 2012 2013 2014 2015 2016 2017 2018
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By the beginning of 2020, only 60 out of the 138 countries
covered by RISE had established a mandated system for
emissions MRV from different end-use sectors. However,
uptake of MRV has nearly doubled since 2010, when only 27
countries had such regulations. Of the 60 countries with MRV
regulations in early 2020, 44 countries also had in place a
carbon pricing scheme (carbon tax and/or emissions trading),
and more than a third of these countries were in Europe (with
only four countries located in Africa). However, Africa has
experienced the largest increase in uptake of MRV regulations
(eight additional countries since 2010) followed by the Middle
East (seven additional countries). In 2019, Europe had the
largest share of countries with MRV policies for emissions
in place (27%), followed by the Middle East (15%) and Africa
(14%). (p See Figure 59.)
Within Africa, Malawi and South Africa are the only
countries implementing both types of regulations (emissions
MRV and carbon pricing). Malawi implemented its MRV
programme in 2019 targeting emissions from oil and diesel
generators and the transport sector, and the resulting tax
revenues collected exceeded the country’s expectations.
In India, although there is no explicit carbon tax in place,
the MRV system implemented for the coal industry in 2010
has informed the efficient fuel-switching programme for
electricity generators, as policy makers have been able to
set appropriate benchmarks for emission limits based on
the verified emission data. Subsequently, between 2010 and
2015, the Indian government introduced coal emission limits
and corresponding excise duty penalties in a transparent
step-phase approach. The limits and penalties are adjusted
yearly based on historic data from the MRV system, giving
emitters the ability to plan operations accordingly.
i The 2020 edition of RISE includes 31 indicators distributed among
four pillars (access to electricity, access to clean cooking, renewable
energy and energy efficiency), measured across 138 countries globally
and covering more than 95% of the world’s population. By providing
empirical evidence of the support provided by policy frameworks, the
RISE database helps countries attract investments in their sustainable
energy sectors. Private investors and developers also use RISE to carry
out due diligence related to new projects, products and services. RISE
indicators can help policy makers benchmark their own national energy
framework against those of regional and global peers. See https://rise.
esmap.org.
ii China’s Emission Trading Scheme was designed by the National
Development and Reform Commission beginning in 2018 but was not
officially implemented until the first phase began in January 2021.
Source: See endnote 25 for this chapter.
Source: World Bank Group. See endnote 25 for this chapter.
FIGURE 59.
Number of Countries with Carbon Emission Monitoring, Reporting and Verification Policies, by Region, 2010-2019
223
https://rise.esmap.org
https://rise.esmap.org
i For example, opting for larger homes or increasing the building floor area and appliance ownership per household, although these trends are not exclusive to
developing countries.
ii In buildings, this refers to the data collection, representation, observation and control of physical systems by digital means, often called digital or ”smart” tech-
nologies/solutions.
RENEWABLES 2021 GLOBAL STATUS REPORT
BUILDINGS
The buildings sector
accounted for around
33% of TFEC in 2018, a
share that has risen about
1% annually since 2008.26
Residential buildings
consumed nearly three-
quarters of this energy,
while the remainder was
used in commercial and
public buildings.27 Total energy-related CO2 emissions from
buildings increased to a record 10 Gt in 2019, only 3.1 Gt of
which were direct emissions.28 Indirect emissions thus are highly
relevant within the buildings sector, due notably to its dominant
share of global electricity consumption (around 55% in 2019).29
Between 2013 and 2016, carbon intensity improvements in the
power sector were sufficient to cause CO2 emissions to level
off in buildings, illustrating the general effectiveness of rising
electrification in buildings, combined with the decarbonisation
of electricity generation itself.30 Electricity can power various
services efficiently in buildings through the use of appliances and
equipment (some of which are typically fossil fuel-powered) that
are already widespread, such as fans, refrigerators, water boilers,
cook stoves and heat pumps.31 Additionally, electric appliances
tend to be more efficient than the equipment they replace.32 On
a final energy basis, heat pumps can be three to five times more
energy efficient than their natural gas counterparts.33
However, between 2000 and 2019, electricity use in buildings
grew five times faster than improvements in the carbon intensity
of electricity generation.34 This is due in part to changes in
rapidly developing countries (where electricity remains carbon
intensive) – including rising electricity demand for space cooling
and appliances, increased access to modern energy services,
and changing consumer behaviouri, such as purchases of less-
expensive but inefficient air conditioners.35
In developed countries, however, energy efficiency improvements
largely offset increased electricity demand from increasing
digitalisationii and electrification.36 Between 2008 and 2018, the
carbon intensity of buildings in member countries of the Organisation
for Economic Co-operation and Development (OECD) improved
2.7% annually in the residential sector (from an average of 4.6 tonnes
of CO2 per dwelling in 2008 to 3.5 tonnes in 2018), and it improved
3.6% annually in the commercial sector (from 3.8 tonnes of CO2
per employee to 2.6 tonnes over the decade).37
In parallel, efforts in energy efficiency have progressed due to
increasing digitalisation in building operations.38 Digital solutions
for building operations serve three essential functions: monitoring
energy consumption (for example, via “smart meters”); identifying
potential energy savings; and reducing energy consumption
through intelligent controls.39 Smart technologies range from
applications that measure and optimise the use of energy or guide
users’ behaviour, to software for professional facility management.40
Digital technologies can reduce building energy use nearly 20% in
several types of commercial buildings, including offices, retail, hotels
and hospitals.41 Digital energy management devices are increasingly
prevalent as well. Smart thermostats are the second most common
smart home device (following audio speakers) in UK households,
with 6% penetration, followed by smart lighting (5%).42
In addition to the energy savings realised by electrification
measures and digital technologies, improved building
performance – that is, energy usage per square metre – is critical.
Improving energy performance is generally simpler in new
buildings than in existing buildings, as efficiency improvements
can be integrated into the design stage.
The EU’s Energy Performance of Buildings Directive requires
all new buildings from 2021 onward to be nearly zero-energy
buildings (NZEBs).43 However, since the directive does not provide
a specific accounting method, tracking the market penetration of
NZEBs can be challenging.44 For example, the uptake of NZEBs in
France appeared rapid because the country’s NZEB accounting
method matches the current thermal regulation (hence all new
buildings are considered NZEBs), whereas in Italy the uptake
seemed slower as the national accounting method is stricter
compared to the building code requirements.45
In the United States and Canada, the number of zero-energy projects
has increased steadily, reaching 27,965 in 2019, although the yearly
rate of increase has declined from previous years (falling from 59% in
2018 to 26% in 2019).46 Meanwhile, such standards often are lacking
in developing countries that have rapidly growing urban populations
(especially in Asia and Africa); in many of these countries, building
codes either do not exist or do not apply to all building energy use.47
Carbon
intensity
in buildings is driven by
indirect emissions (around
70%), notably by electricity
generation.
224
i Data for indirect emissions were not available for the industry sector, and direct emissions data were provided only up to 2018.
ii Due to data availability, the analysis includes the following countries: Australia, Austria, Belgium, Canada, the Czech Republic, Denmark, Finland, France,
Germany, Greece, Ireland, Italy, Japan, the Netherlands, New Zealand, Portugal, the Republic of Korea, the Slovak Republic, Spain, Switzerland, the United
Kingdom and the United States.
Carbon intensity per value added
(kgCO2/USD PPP 2015)
Share (in %)
Average
carbon intensity
in industry
Share of electricity
in industry final
energy consumption
Global share
of renewable
energy
in industry
0.90
0.75
0.60
0.45
0.30
0
60
50
40
30
20
100.15
20182008 2009 2010 2011 2012 2013 2014 2015 2016 2017
0
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In developed countries, lower rates of new construction mean that
decarbonising the existing building stock – a much greater challenge
– is more critical to decarbonising the sector as a whole.48 In the
EU, however, only around 1% of existing buildings are renovated for
energy efficiency improvements annually, compared to a required
3% in order to meet the region’s 2030 emissions target.49 In some
OECD countries, energy-efficient renovations, including improving
building insulation and installing more efficient heating systems,
contributed to carbon intensity improvements for space heating.50
In Finland, France and New Zealand, the carbon intensity of space
heating was reduced more than 30% between 2008 and 2018.51
Integrating renewable energy solutions in buildings – such as solar
water heaters, heat pumps and renewables-based district heating
and cooling – can help reduce carbon emissions and is more
effective in terms of implementation when planned in conjunction
with building renovations or design.52 The Energiesprong
renovation programme, which began in the Netherlands and
now operates in France, Germany, Italy, the United Kingdom and
the US state of New York, can provide a framework to increase
the uptake of NZEBs through a combination of standardisation,
prefabricated building components and third-party finance.53
Some buildings financed by Energiesprong have produced more
energy than they consumed by combining energy efficiency
technologies with renewables, using insulated rooftops with solar
panels, and installing ventilation and cooling systems.54
INDUSTRY
The industrial sector accounted for 34% of TFEC in 2018, and
its direct emissions totalled 7.9 Gt of CO2i – representing 33% of
direct greenhouse gas emissions from final energy use.55 Global
industrial direct CO2 emissions due to energy consumption
increased 13% between 2008 and 2018.56
A combination of factors influences changes in carbon intensity
in the industrial sector – including the fuel mix of electricity
generation, technological improvements and structural changes
in the share of carbon-intensive industries in the economy.
Nonetheless, it is noteworthy that, in a selection of OECD
countriesii, carbon intensity in industry improved 25% between
2008 and 2018, as the share of electrification increased to 13%.57
(p See Figure 60.)
As with electric appliances in the buildings sector, electrically driven
technologies in the industry sector are, in general, more energy
efficient than conventional ones.58 From a technical point of view,
all energy required to generate heat for industrial processes up to
around 1,000 degrees Celsius could be replaced by electricity.59
However, the technologies involved can be more expensive than the
conventional options, and policy support is needed to promote their
uptake in industrial processes.60 (p See Policy Landscape chapter.)
Another effective strategy for achieving significant carbon intensity
improvements is to implement heat recovery technologies.
Note: The countries included are Australia, Austria, Belgium, Canada, the Czech Republic, Denmark, Finland, France, Germany, Greece, Ireland, Italy, Japan,
the Netherlands, New Zealand, Portugal, the Republic of Korea, the Slovak Republic, Spain, Switzerland, the United Kingdom and the United States.
Source: See endnote 57 for this chapter.
FIGURE 60.
Carbon Intensity and Share of Electricity in Industry, Selected Countries, 2008-2018
225
i Contrary to passive heat recovery, active heat-recovery equipment requires an external energy source to operate.
ii Data for indirect emissions were not available for the transport sector, and direct emissions data were provided only up to 2018.
RENEWABLES 2021 GLOBAL STATUS REPORT
These tap into waste energy streams and reuse them for various
purposes within a facility (e.g., space heating or cooling) or within
the process itself (e.g., pre-heating air and boiler make-up water).
Activei heat recovery equipment, such as heat pumps, make it
possible to increase the temperature of a waste heat stream to a
higher, more-useful temperature.61 Consequently, heat pumps can
facilitate energy savings beyond those achieved by conventional
passive heat recovery.62 (p See Systems Integration chapter.)
Industry-wide, low-temperature waste heat streams have
the greatest potential to use waste heat recovery. However,
barriers – such as the variability in temperature, availability and
contaminating content of low-grade heat sources – continue to
impede significant uptake.63 While the deployment of heat pumps
in industry is still low, a number of applications do exist, mainly in
heating and drying applications.64
In recent years, the uptake of renewables in industrial processes
(mainly bioenergy, as well as geothermal and solar heat) has
helped improve industrial carbon intensity.65 Although solar
thermal has not yet been widely adopted in the sector, some
479 gigawatts-thermal of capacity was in operation in industrial
processes at the end of 2020.66 (p See Market and Industry
chapter.)
Finally, digitalisation has allowed industrial sites to more
comprehensively analyse energy use and to continuously
improve energy performance.67 Modern digitally driven energy
management systems, as well as standards such as ISO 50001,
help industries identify opportunities to adopt and improve cost-
saving technologies, including those that do not necessarily
require high capital investment (whether energy efficiency
technologies, renewables or both).68 Additionally, by collecting
data and simplifying monitoring, energy management systems
ensure better performance, thereby improving the bankability
of company projects and encouraging investments to improve
carbon emissions.69
TRANSPORT
The transport sector accounted for 33% of TFEC in 2018.70 Road
transport represented the bulk of the transport sector’s energy
demand (75%), followed by aviation (12%), marine transport
(10%) and rail (2%).71 (p See Global Overview chapter.)
Direct CO2 emissions from transport totalled 8.1 Gt in 2018,
which represented 34% of directii greenhouse gas emissions
from final energy use.72 Emissions from transport grew 19%
between 2008 and 2018, at an average annual rate of 1.8%.73
This upward trend reflects the increase in the size and number
of, as well as distances travelled by, road vehicles and to a lesser
extent aviation.74 It also underlines the increasing prevalence
of sport utility vehicles (SUVs), which are larger and less fuel
efficient than other passenger cars.75 Total emissions from road
transport in SUVs tripled globally between 2010 and 2020.76
In OECD countries, even as the demand for transport increased
between 2008 and 2017 – with vehicle-kilometres travelled
rising 0.73% annually during this period – the carbon intensity
of transport (i.e., the CO2 emitted per vehicle-kilometre for
cars and light trucks) improved at an annual rate of 0.64%.77
(p See Figure 61.) In general, this carbon intensity improvement
was due partly to the implementation of fuel economy and
greenhouse gas emission standards for light-duty vehicles.
As of 2017, 10 out of the top 15 vehicle markets worldwide
(including China, the EU, India and the United States) had
established fuel economy and/or emission standards for light-
duty vehicles.78 This is significant considering that at the end of
2007, only four governments had mandatory standards of either
kind.79 In total, as of 2017, nearly 80% of new light-duty vehicles
sold globally were subject to some kind of fuel economy or
emission standards.80 (p See Policy Landscape chapter.)
However, challenges remain to determine the full impact of such
regulations on global transport carbon intensity, as regulations
in some countries became stricter (for example, in Japan and the
Republic of Korea), while others were less binding (for example,
in India).81
In developing countries, the carbon intensity of road transport
is determined largely by the used vehicle market: 70% of the
world’s used exported light-duty vehicles are shipped to Africa
(the largest importer at 40%), Eastern Europe (24%), Asia-Pacific
(15%), the Middle East (12%) and Latin America (9%).82 While
import and export regulations tend to lower carbon emissions,
such measures often are lacking in importing countries.83 For
example, Kenya imposes an age limit for imported cars of
8 years, whereas neighbouring Uganda has a limit of 15 years,
and Rwanda has no age limit for imports.84 All three of these
countries import used vehicles from Japan, but because Kenya
has a stricter import policy, the average fuel consumption and
CO2 emissions of its fleet are around 25% lower than those of
its neighbours.85
The energy efficiency (kilometres travelled per unit of energy)
of electric vehicles is higher than that of internal combustion
226
Annual growth rate in %
0.10
0.08
0.06
0.04
0.02
0
-0.02
-0.04
-0.06
-0.08
-0.10
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Cars and light trucks
20182016201520142013201220112008 2009 2010 2017
+0.73%
Vehicle
kilometres
travelled
-0.78%
Carbon intensity
per kilometre
travelled
Compound average annual
change, 2008-2018
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engine vehicles, and EVs produce zero direct CO2 emissions.86
EVs also can have a positive impact on the carbon efficiency of
the global vehicle fleet, particularly when the share of renewable
energy in the electricity mix is high.87 While the CO2 emissions
benefit of EVs is somewhat less significant when considering
indirect emissions during production and disposal of the
vehicle and battery system, as well as the electricity generation
necessary, the life-cycle emissions of EVs are typically much
lower than those of internal combustion engine vehicles.88
Boosted by national and local government decisions to phase
out petrol and diesel vehicles, sales of electric cars topped
3.2 million globally in 2020, surpassing the record year of 2019.89
(p See Systems Integration
chapter.) However, the
current overall impact
of EVs on the carbon
efficiency of the transport
sector is minimal, as
the share of electricity
in TFEC of transport
remains low, around 1.1%,
of which less than 30%
is from renewables.90
Furthermore, few countries
explicitly link EV targets with renewable electricity targets.
(p See Policy Landscape chapter.)
Mobility systems focusing on shared transport, or mobility
as a service, also improve energy and carbon efficiency per
passenger.91 While mobility innovations such as e-scooters
have increased greatly in recent years and may have the
potential to replace personal car use, their impact on improving
energy intensity and carbon intensity remains anecdotal and is
undetermined globally.92
During 2020, the COVID-19 crisis impacted existing mobility
trends, with a growing tendency towards individual transport
modes, thus decreasing public transport’s energy efficiency and
increasing its carbon intensity.93 (p See Sidebar 7.) Restrictive
measures encouraging remote working also impacted energy
consumption in the sector.94
Note: The countries included are Australia, Austria, Belgium, Canada, the Czech Republic, Denmark, Finland, France, Germany, Greece, Ireland, Italy, Japan,
the Netherlands, New Zealand, Portugal, the Republic of Korea, the Slovak Republic, Spain, Switzerland, the United Kingdom and the United States.
Source: See endnote 77 for this chapter.
FIGURE 61.
Indexed Carbon Intensity and Kilometres Travelled, Passenger Vehicles in Selected Countries, 2008-2018
The life-cycle emissions of
EVs are typically
much lower
than those of internal
combustion engine
vehicles.
227
IKEA has invested heavily in wind and solar power over the past decade alongside other sustainability
initiatives, such as sourcing all of its cotton from sustainable agriculture.
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usiness has a significant role to play in renewable
energy deployment. Companies worldwide are
contributing in various ways, including through
manufacturing and production, research and development,
installation, project financing and energy infrastructure, as well
as by procuring their energy from renewable sources. Despite
the impacts of the COVID-19 pandemic and related recession,
corporate sourcing of renewable electricity through power
purchase agreements (PPAs) rose 18% in 2020.1 Businesses
also increased their use of renewables for heat and transport,
although to a far lesser extent.2
Firms and industries have different energy needs, and uneven
patterns of business demand for renewables exist depending
on the sector, technology and geography. Whereas corporate
sourcing of renewable electricity is advancing quickly, the use
of renewable energy in industrial heat and transport is not.3
However, innovations in markets, financing mechanisms, policies
and technologies (such as renewable hydrogen) are helping to
close gaps and facilitate greater demand.
FEATURE:
BUSINESS DEMAND
FOR RENEWABLES
K E Y FA C T S
08
B
Businesses are increasing their uptake
of renewables across power, heating and
cooling, and transport needs. Company
membership in business coalitions promoting
renewable energy procurement surged across
sectors.
Despite a challenging business year, the
new renewable energy capacity that
businesses sourced through power purchase
agreements increased 18% in 2020.
Corporations increasingly sourced low-
temperature renewable energy for
heating and cooling from solar thermal heat,
geothermal heat and bioenergy, as well as
renewables-based electrification.
Businesses source renewable energy for
their transport needs mainly from biofuels,
renewables-based electricity and renewable
hydrogen across the road, rail, maritime and
aviation sectors.
229
i Clean energy firms refer here to those with activities in renewable energy, energy efficiency, emission abatement or other technology-based decarbonisation sectors.
RENEWABLES 2021 GLOBAL STATUS REPORT
DRIVERS OF BUSINESS
DEMAND FOR RENEWABLE ENERGY
A combination of factors is contributing to growing business
demand for renewables across all sectors. These include
environmental and ethical considerations, cost savings,
competitiveness, risk mitigation, and business coalitions and
collaboration. Government policy also continues to play a key
role in incentivising business demand for renewable energy on
various fronts. (p See Policy Landscape chapter.)
Renewables are central to companies’ efforts to achieve their zero-
emission or other ambitious emission reduction goals. For some
companies, the drive to increase the use of renewable energy
is part of larger environmental goals and, often, a fundamental
element of a broader sustainability strategy.4 Stakeholders
such as customers, workers, local communities, suppliers and
shareholders increasingly expect companies to play their part in
climate action and to become more accountable as well as more
publicly transparent about their sustainability practices.5
Renewable energy is a core area of business sustainability
reporting (for example, providing updates on current use of
renewables and on targets set for future use); this has become
more standardised worldwide through the efforts of the Global
Reporting Initiative, the Carbon Disclosure Project (CDP) and
similar entities.6 Investor and shareholder interest in renewable
energy companies also is burgeoning. Investment in sustainability-
related funds surged around 300% in 2020, and share prices in
renewables and other clean energy firmsi rose 142%; meanwhile,
share prices for oil and gas companies fell 38%.7
Cost savings and competitiveness are another key driver
of business demand for renewables. Renewable electricity in
particular has become increasingly attractive commercially
compared to new and existing fossil fuels, and has been cost
competitive compared to nuclear power for some time.8 In some
cases, it can be less expensive for companies to source their
own renewable electricity directly from suppliers or to produce it
themselves than to buy it from the grid.9 In electricity generation,
renewables now offer more attractive cost options for at least
two-thirds of the global population.10 (p See Sidebar 6 in Market
and Industry chapter.)
Risk mitigation objectives also drive companies to adopt
renewables, as these energy sources can help reduce energy
supply risks, price risks and reputational risks as environmental
values take deeper root in global society.11 In addition, renewables
can reduce policy and regulatory risks arising from potential
future changes, such as carbon taxes and the market transition
towards a low-carbon economy. Firms have come under growing
pressure to disclose and address climate-related financial risk,
particularly for credit rating agency assessments.12
Business coalitions promoting greater demand for renewables
have grown quickly. The RE100 group of companies, committed
to achieving 100% renewable electricity, nearly doubled its
membership in just over two years, from 155 members in January
2019 to 309 members by May 2021.13 Membership in EV100 – a
group of companies committed to transitioning their vehicle fleets
to electric vehicles (although without a direct link to renewables)
– grew similarly.14 Other organisations are providing leadership
and support frameworks to help leverage business demand for
renewables.15 (p See Box 9.)
Renewables are central
to companies’ efforts to
achieve
emission
reduction
goals.
230
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BOX 9. Organisations Leveraging Business
Demand for Renewables
The Renewable Energy Buyers Alliance is an association
of energy buyers seeking to procure renewable energy
across the United States. Its goal is to reach 60 GW
of new renewable energy projects by 2025 by unlocking
procurement options for large-scale energy buyers.
The Alliance counts more than 200 members, including
stakeholders from energy companies, commercial and
industrial businesses, and nonprofit organisations.
The RE-Source Platform is a global alliance of stakeholders
representing clean energy buyers and suppliers. It
co-ordinates activities to promote a better framework for
corporate renewable energy sourcing in the European Union
(EU) and at national levels. Its goal is to increase the number
of active corporates using renewable energy sourcing from
100 to 100,000.
The Renewable Thermal Collaborative is a global coalition
of companies, institutions and governments committed to
scaling up renewable heating and cooling at their facilities.
Its members identify market barriers and aim to use their
collective purchasing power to reduce costs and scale
deployment of these technologies.
Additional organisations leveraging business demand for
renewables include:
We Mean Business, a global non-profit coalition working
with businesses to set science-based emission reduction
targets, to identify and prioritise government policies, and to
organise public-private partnerships;
the Mission Possible Partnership, which aims to decarbonise
some of the highest-emitting sectors by convening coalitions
such as Clean Skies for Tomorrow (aviation), the Getting to
Zero Coalition (shipping), the Clean Cement and Concrete
Coalition, the Net-Zero Steel Initiative and more;
the RE-Users platform in Japan, which allows corporate
energy users to share information and best practices to
accelerate renewable procurement in the country and also
organises annual summits; and
four initiatives by The Climate Group – RE100, EV100, EP100
and SteelZero – that aim to source renewable electricity, buy
electric vehicles, improve energy productivity and create
demand for low-carbon steel.
Source: See endnote 15 for this chapter.
RENEWABLE ELECTRICIT Y
Business demand for renewable energy is most common
in the electricity sector. The four main categories of such
“corporate sourcing” of renewable electricity are:
Self-generation and consumption: Companies develop their
own renewable energy projects and use the electricity
generated. These installations may be on site (for example,
rooftop solar) or off site (such as a wind power project built
relatively near the firm’s facilities).
Power purchase agreements (PPAs): Companies sign long-
term contracts (typically 10 years) with an independent
power producer or utility that commits them to procure
a specific amount of renewable energy at a fixed price
for a specified duration. Virtual PPAs are more popular in
larger markets due to their flexibility, as buyers and sellers
do not need to be connected to the same grid provider.
One advantage that corporate PPAs offer is “aggregation”,
where smaller purchasing companies form a consortium
and aggregate their demand to secure more competitively
priced deals and reduce financial risk.16
Utility green procurement: Companies buy renewable
electricity through green premium products (green label-
certified and -priced) or bespoke contract arrangements,
such as green tariffs (special rates). Energy utilities offer
both options, allowing their business customers to buy
renewable energy directly through billing and without
requiring a long-term contractual commitment. However,
the trade-off is a less competitive price than that offered
by PPAs.17
Environmental attribute certificates (EACs): Companies
purchase EACs from energy suppliers or brokers,
effectively buying ownership rights to a specified amount
of renewable electricity. The certificates are primarily
“unbundled”, meaning that they are bought and sold
separately from the associated electricity generated.18
These certificates, referred to as renewable energy
certificates (RECs) in North America and Guarantees of
Origin (GOs) in Europe, are the most common corporate
sourcing method.19
By the end of 2020, the only available global-level
aggregated data on corporate sourcing covered PPAs.
Despite a challenging business environment during the year,
the capacity of new renewable corporate PPAs sourced
by businesses worldwide increased 18% in 2020, reaching
23.7 gigawatts (GW) of additional renewable power capacity
that year.20 This compares to added capacity of just 0.1 GW
in 2010 and 4.7 GW in 2015.21 (p See Figure 62.) The fourth
quarter of 2020 alone saw a record 7.3 GW of contracts
signed globally.22
North America continued to dominate the corporate PPA
market in 2020, accounting for 57% (13.6 GW) of the global
total, although this share fell from 81% (16.3 GW) in 2019.23
Renewable capacity procured in 2020 nearly tripled in
countries across Europe, the Middle East and Africa, surging
from 2.6 GW to 7.2 GW.24 Procurement in the Asia-Pacific
region grew from 1.2 GW to 2.9 GW.25
231
100
80
60
40
20
0
Gigawatts
Previous year’s capacity
Annual additions
Previous year’s
capacity
2015 2016 2017 2018 2019 2020
+23.7
Gigawatts
increase in
2020
RENEWABLES 2021 GLOBAL STATUS REPORT
Trends in corporate sourcing markets that began two or three
years ago continued in 2020.26 Companies had already started
to seek more flexible terms in PPA contracts to account for
potential changes in technology, policy and new generating
capacity that could affect market prices over the lifespan of the
agreement. In addition, buyers began demanding that energy
providers offer contracts for a shorter term than the standard
10-year agreement.27
An increasing number of companies began adopting a “24/7
consumption matching” approach, where the supply of electricity
matches real-time demand.28 This load balancing depends on
the smart management of wind and solar energy supported by
energy storage.29 Deals in 2020 included agreements between
Microsoft (US) and Swedish energy provider Vattenfall, and
between Daimler (Germany) and Norwegian energy company
Statkraft.30 Also during the year, Google announced a goal to
source its power on a 24/7 basis and introduced a new computing
system, shifting data centre tasks to optimal times for wind and
solar power generation.31
Companies also have started attempting to decarbonise their
supply chains, addressing emissions for which they are
indirectly responsible. Corporate sourcing previously had focused
mainly on emissions generated directly by a company, as well
as emissions from energy producers that supply the company’s
energy needs. However, a growing number of large companies
are requiring their supply chain partners, both upstream and
downstream, to power their operations with renewable energy.32
As of early 2021, more than 40 of Apple’s major suppliers had
signed on to the company’s Supplier Clean Energy Programme,
which covered 4 GW of power capacity in 2020.33 For smaller
supplier companies, however, securing PPAs on the same
favourable terms as large
companies has been a
challenge, due to a lack
of resources and market
leverage.34 Aggregation
deals involving the major
company itself have
provided one solution.35
Regionally, national energy
regulators across the EU
further harmonised their
rules to enable the use of cross-border PPAs, with the aim
of creating a unified large market similar to that in the United
States.36 In Europe, corporate buyers and energy suppliers are
often in different countries, and they face different national
regulations that may be incompatible; they also may be hindered
by the lack of cross-border grid connections.37 To address some
of these challenges, a single European market for cross-border
PPAs was under development at the end of 2020, spurred by
the EU’s new Renewable Energy Directive and by the European
Green Deal.38
Challenges remain to corporate sourcing in regions beyond the
leading markets of the United States and Europe. While the Asia-
Pacific region reported the largest increase in RE100 membership
in both 2019 and 2020, companies in the region identified
regulatory and market barriers, including the relatively high costs
of renewable power technologies as a result of unfavourable
policy frameworks.39 Elsewhere, a major challenge has been
limited or no availability of corporate sourcing mechanisms,
such as in Argentina, China, Chinese Taipei, New Zealand, the
Republic of Korea, the Russian Federation and Singapore.40
Note: Data are provided in direct current (DC) and do not include on-site power purchase agreements (PPAs).
Source: BloombergNEF. See endnote 21 for this chapter.
FIGURE 62.
Corporate Renewable Energy PPAs, Global Capacity and Annual Additions, 2015-2020
Capacity of new
renewable
corporate PPAs
increased 18% in 2020.
232
i Renewable hydrogen refers to hydrogen produced through water electrolysis using renewable electricity. (p See Systems Integration chapter.)
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COMPANY E X AMPLES AND BUSINESS GROUPS
Corporate sourcing of renew able electricity increased in 2020,
particularly among larger firms. Many are part of the RE100
group, whose membership grew by more than 60 companies
in 2020.41 Amazon was the leading corporate PPA buyer in
2020 with 5.1 GW (3.1 GW of solar photovoltaic (PV) power and
2.0 GW of wind power) (p see Box 10), followed by Total (3.0 GW)
and Taiwan Semiconductor Manufacturing Company (TSMC,
1.2 GW).42 TSMC signed the world’s largest PPA on record
(920 megawatts, MW) with the Danish energy provider Ørsted
for an offshore wind power project to be built off the coast of
Chinese Taipei.43
On a cumulative basis, Amazon moved into first place during the
year with 7.5 GW of corporate PPAs, ahead of Google (6.6 GW)
and Facebook (5.9 GW).44 Also notable was an aggregation PPA
involving Honda, AT&T, McDonald’s, Google and several other
firms for 1.3 GW of solar power from the US developer Invenergy.45
Information and communication technology (ICT) companies
have accounted for around half of the global corporate sourcing
of renewables in recent years.46 The burgeoning growth in
their data centres and data transmission networks has created
a rapidly expanding demand for electricity, accounting for
around 1% of global electricity consumption in 2020.47 The
ICT sector has become a focus of both corporate sourcing
activity and innovation. For example, in 2020, Microsoft
experimented with using renewable hydrogeni to power fuel cells
at some of its data centres, and plans to use it instead of diesel
generators to provide back-up power capacity.48
BOX 10. Amazon’s Sourcing of Renewable Electricity
Amazon (US) became the world’s leading corporate
sourcing firm in 2020, completing 26 new projects across
eight countries and four continents during the year, for a
total of 127 projects worldwide. The largest deal signed
in 2020 (and the largest offshore wind corporate PPA in
Europe to date) was a 10-year PPA for 250 MW from Ørsted’s
planned 900 MW Borkum Riffgrund 3 offshore wind farm in
Germanyi. Amazon also signed PPAs for 650 MW of solar
PV from French utility ENGIE. In February 2021, Amazon’s
largest single renewable energy investment to date was a
PPA with the Shell-HKN Offshore Wind project for 380 MW
(half the project’s total capacity) in the Netherlands,
expected to come online in 2024.
Amazon’s stated objective is to power all of its offices and
distribution and data centres with renewables by 2030 and
to become net zero in its energy needs by 2040. In 2019, the
company co-founded The Climate Pledge, a coalition of more
than 50 large firms (as of early 2021) that are committed to
becoming net zero carbon emission businesses by 2040.
This includes meeting requirements for regular reporting on
progress, decarbonisation strategies in line with the Paris
Agreement (including renewable energy use across all
sectors), and additional and quantifiable offsets. The initiative
also includes a USD 2 billion fund to bring to market new
renewable energy and energy efficiency technologies.
i The project is expected to be operational by 2025. In 2020, Ørsted also
signed a large offshore wind PPA with TSMC.
Source: See endnote 42 for this chapter.
233
i See Glossary.
ii The costs of converting these high-temperature processes to renewables are a major barrier, as the predominant energy source has been low-cost coal and
coke, which are much less expensive than, for example, pelletised biomass fuels. The very large scale is also a barrier; for example, a large steel plant uses
more energy than a large power station. (p See Industry section in Global Overview chapter.)
RENEWABLES 2021 GLOBAL STATUS REPORT
RENEWABLE HEATING
AND COOLING IN INDUSTRY
Several key industries use heating and cooling (thermal energy)
processes, mainly for transforming raw material inputs into
products. These include iron and steel, chemicals, cement,
aluminium, paper and pulp, and food and tobacco. Renewables
have made only limited inroads into many of these industrial
sectors, representing around 10% of the total industrial thermal
energy demand; of this renewable share, 90% comes from
bioenergy sources.49
In 2020, industry accounted for 34% of total final energy
consumption; of this, around three-quarters is in the form of
direct thermal demand, with the rest in the form of electricity
(some of it used to produce thermal energy).50 Virtually all cooling
in industry is done with electricity.51 (p See Industry section in
Global Overview chapter.)
A range of renewable energy technologies exist for meeting
industrial heating and cooling needs; they include renewables-
based electrification,
renewable gases, and
direct-use applications
through geothermal heat,
solar thermal heat and
modern bioenergy.52
Commercially and tech-
nically viable options for
bioenergy use already
exist in the food and
tobacco and pulp and
paper industries, thanks to the availability of organic waste
by-products and the lower process temperatures required.53 In
the aluminium and non-ferrous metals industry, both the use
of electric arc furnaces and “sector couplingi” opportunities for
utilising renewable electricity are growing.54
However, the most energy-intensive industry sectors, such as
steel, chemicals and cement, currently do not rely significantly on
renewable heat. Each has its own specific thermal energy needs.
Those with the highest temperature requirements generally have
tended to rely heavily on fossil fuels, which have reached shares
exceeding 80% in each of these three sectorsii.55
The business dynamics of industrial thermal energy are notably
different from power generation, due mainly to the inherently high
levels of self-consumption in industry.56 Firms in the heating and
cooling sector often operate in local markets, and energy often
is produced directly at the point of demand.57 As such, industrial
energy users simultaneously produce and consume the thermal
energy they need for heating and cooling on-site, without having
to procure it from the market. Self-generation is thus the norm
for thermal energy.
In thermal processes, procurement mechanisms for renewables
that are similar to corporate sourcing of renewable electricity
are rare, although some developments have emerged. Most
projects for industrial renewable heat have involved the use of
bioenergy and solar thermal heat. For example, in 2020 Elpitiya
Plantations (Sri Lanka) met 87% of its heat demand using locally
sourced modern bioenergy and third-party suppliers (p see
Box 11), and Goess Brewery (Austria) met 42% of its heat demand
using renewables, including from solar thermal installations.58
Worldwide, nearly 900 solar thermal systems totalling more than
792 megawatts-thermal were supplying industrial process heat
by the end of 2020, with new projects concentrated in China,
Mexico and Germany. (p See Solar Thermal section in Market
and Industry chapter.)
Another option for industry sectors that have lower-temperature
heat requirements is to procure renewable thermal energy from
district heating providers.59 In 2020, Denmark’s largest industrial
company, Danfoss, sourced 11% of the industrial thermal
demand for its production processes from renewable district
heating and recovery.60 The company procures renewable
thermal energy for many of its factories that manufacture
energy efficiency technology and other products, with the aim
of becoming carbon neutral in its heating and cooling needs
globally by 2030.61
In 2020, the EU announced that its GO certificate system
would extend beyond renewable electricity as of mid-
2021 to include renewable heating and cooling, in line
with the region’s Renewable Energy Directive and the
European Green Deal.62 In North America, a REC market
for industrial thermal energy using biomethane and other
“low-carbon fuels” was under development in 2020.63
The market ’s Green-e certified fuel certificate standard
was being trialled on a small pilot basis in the region.64
Environmental attribute
certificate markets
expanded to
include
thermal energy
during 2020.
234
i See Glossary.
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COMPANY E X AMPLES AND BUSINESS GROUPS
The highest renewable energy shares in process heat are found in
industries with lower temperature needs. However, some energy-
intensive sectors that require high-temperature heat have launched
initiatives to increase the use of renewables in some markets. Actions
in the aluminium industry as of early 2021 included a commitment by
BMW (Germany) to source aluminium produced using solar power,
and the announcement by Norsk Hydro (Norway), an aluminium and
renewable energy company, that it was exploring the development
and use of renewable hydrogen for some of its aluminium plants.65
Projects to produce steel from renewable hydrogen were under
development in Germany and Sweden, among other countries.
In early 2021, German steel producer Salzgitter began operations
using hydrogen produced from wind energy.66 In Sweden, the
HYBRIT demonstration plant is scheduled to start producing steel
based on the direct reduced iron process using renewable hydrogen
in 2026.67 The commercial venture received strong state backing
when it was launched in 2016 and is a 20-year, USD 46 billion
collaboration among steel maker SSAB, the state-owned iron ore
producer LKAB and the utility company Vattenfall.68 In early 2021,
Swedish firm H2 Green Steel announced that it also would produce
steel using renewable hydrogen, beginning in 2024.69
A few business coalitions exist to support the use of renewables
in industry. The Renewable Thermal Collaborative (RTC)
commits members from both the public and private sectors to
procure renewable thermal heat from suppliers, as well as to
help promote the RTC’s work in developing corporate sourcing
markets and mechanisms for renewable heat.70 In December
2020, Stanley Black and Decker (US) became the RTC’s 21st
member company.71
Also in December, The Climate Group, in partnership with
the Responsible Steel initiative, launched SteelZero, the first
business coalition of its kind in the industrial thermal energy
sector.72 SteelZero comprises firms that have committed to
procure 100% net zeroi steel by 2050 and that have made an
intermediate commitment to procuring, specifying or stocking
50% of their net zero steel requirement by 2030.73 SteelZero
began with eight steel-buying company members, from sectors
including construction, real estate and property development,
steel production and renewable energy development.74 While
it aims primarily to drive business on the demand side, it also
is lobbying for greater investment in renewable technologies
and policies to facilitate the steel industry’s transition to zero
carbon.75
BOX 11. Elpitiya Plantations’ Sourcing of Renewable Heat
Elpitiya Plantations PLC (EPP) is a Sri Lankan plantation
firm operating across 13 estates and focused primarily on
manufacturing tea and crepe rubber. EPP’s main thermal
energy need is heated air to wither and dry tea leaves.
Operating temperatures for these processes range between
50 degrees Celsius (°C) and 100 °C. In rubber production,
process heat is used to evaporate the surface moisture from
the material.
EPP has developed a sustainability strategy formulated
around six relevant United Nations Sustainable Development
Goals, including Goal 7 on affordable and clean energy. EPP’s
target is to source 100% of its thermal energy consumption
from self-produced sustainable biomass feedstocks by 2030.
In 2020, EPP’s annual biomass use for thermal applications
represented 88% of the company’s total energy consumption.
EPP sourced 23% of this from its own biomass material –
mainly uprooted rubber and eucalyptus trees – and procured
the rest from other sustainable biomass suppliers.
EPP aims to increase reliance on its own biomass fuelwood
through its Forestry Management Plan. By 2020, nearly 400
hectares of tree species had been grown for this purpose.
However, given space constraints and the need to use the
company’s existing land to grow its commercial crops, EPP,
like many plantation firms with similar renewable thermal
energy goals, will still have to purchase significant biomass
feedstocks from other suppliers.
Source: See endnote 58 for this chapter.
235
RENEWABLES 2021 GLOBAL STATUS REPORT
RENEWABLES
IN TRANSPORT
Energy use for transport comprises four main sectors: road,
rail, maritime shipping and aviation. Although these sectors use
varying amounts of renewable energy and face unique challenges,
business demand for renewables generally increased across all
sectors in 2020. (p See Transport section in Global Overview
chapter, and Reference Table R19 in GSR 2021 Data Pack.)
ROAD TRANSPORT
Business demand for renewables in road transport mainly involves
company vehicle fleets, including company cars, rental vehicles,
short-haul or “last-mile” delivery vans, heavy-duty vehicles (such
as long-haul freight trucks and refuse trucks), buses, taxis and
special purpose vehicles. Fleet vehicles contribute half of all
emissions from road transport worldwide, despite accounting for
only 20% of global vehicle sales.76
Renewable energy can fuel road vehicles through the combustion
of biofuels or renewable hydrogen in an internal engine, or by
powering the vehicles with renewable-based electricity. Most
business demand during 2020 was for electric vehicles (EVs),
with many companies scaling up their fleets and committing
to a shift to 100% EVs (although this was not necessarily linked
directly to renewable electricity).77 Demand from businesses
seeking to use biofuels in commercial fleets also grew in
certain markets, and bioenergy remained the largest renewable
energy contributor in the transport sector.
In Europe, 6 out of 10 cars sold are company cars, but less than
4% of these were EVs in 2020.78 By early 2021, fleet vehicles
represented 59% of the EVs on European roads, but very few
of these were electric heavy-duty vehicles, due mainly to a
lack of such models in the market.79 However, in early 2021 a
range of new electric heavy-duty vehicles were scheduled for
launch, including the Tesla Semi.80 Uptake of liquefied biogas in
heavy-duty vehicles also increased in 2020, as infrastructure and
investment in the technology grew, particularly in Scandinavia.81
Where companies have shown interest in electrifying their fleets,
they have tended to first electrify a small share of vehicles to
test driver sentiment and comfort, vehicle suitability, and depot
charging capabilities (including the availability of charging station
infrastructure). They also consider factors such as vehicle costs
(especially relative to petrol/diesel fuel alternatives) and the
total cost of ownership, as well as vehicle range, the operational
considerations of integrating EVs into their fleets and financing
models best suited to vehicle procurement.82
Emission standards also have helped to accelerate fleet
electrification, especially among companies operating in the
more than 300 “zero-emission zones” in cities worldwide.83 Such
standards and restrictions have influenced business decisions
to invest in biogas for trucks as well in many regions.84
Company vehicle fleets have certain unique characteristics
that make scaling up electrification particularly advantageous.
These include the predictability of journeys, the constancy
of distances travelled, fixed destinations and stopovers that
support electric charging management. Given the high use
rates for corporate fleet vehicles, their transition to electric also
can make long-term economic sense because of the reduced
servicing, maintenance and fuel costs associated with EVs.85
For hydrogen fuel cell vehicles, the business demand has been
mainly for buses. As of early 2020, nearly all of the hydrogen
produced worldwide was based on fossil fuels. However, some
countries have begun adopting targets and policies to support
renewable hydrogen specifically. (p See Systems Integration
chapter, and Table 5 in Policy chapter.) Investment in hydrogen
fell 20% in 2020, to an estimated USD 1.5 billion.86 This was
driven by a COVID-induced slump in demand for hydrogen
fuel cell buses, with investment falling from USD 865 million to
USD 400 million.87
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Company Examples and Business Groups
Some companies took action to increase their direct use
of renewables in road transport. In 2020, “MY Renewable
Diesel”, produced by Neste (Finland) from waste and residue
raw materials, became available to businesses and private
consumers at more than 500 fuelling stations across Europe
and in the US states of California and Oregon.88 IKEA Finland
partnered with Neste to begin using MY Renewable Diesel as
part of its broader strategy to achieve emission-free deliveries by
2025.89 McDonald’s Netherlands and the logistics company HAVI
(Germany) also partnered with Neste to supply used cooking
oil from McDonald’s to make MY Renewable Diesel for HAVI’s
delivery trucks.90 In addition, companies expanded their use of
biogas: for example, Lidl partnered with IVECO, LC3 and Edison
in early 2020 to introduce five biomethane-fuelled vehicles for
use in Lidl’s Italian fleet.91
Many companies also were using electric fleet vehicles based on
renewable electricity. As of 2020, Deutsche Post DHL operated
the largest EV fleet in Germany, and in early 2021 the company
announced that it would power its entire delivery fleet of more
than 80,000 vehicles with renewable electricity by 2030.92 In the
United States, a joint venture among First Student, First Transit
and NextEra Energy Resources announced a plan in January
2021 to transition more than 55,000 buses across North America
to renewably powered EVs.93
Business coalitions and collaborations have emerged to support
decarbonised and electrified transport. As of early 2021, more
than 100 companies had committed through EV100 to switching
their fleets to electric and/or installing charging infrastructure
by 2030.94 The Transport Decarbonisation Alliance targets
emission reductions in the road freight sector, which accounts
for more than 60% of freight transport emissions; due to
rising freight demand, these emissions are on track to double
by 2050.95 In the United States, the Drive to Zero programme
works with buyer companies, energy providers and government
agencies at the city, regional and national levels to promote
business demand for zero-emission and near-zero-emission
trucks, buses and other vehicles.96
RAIL TRANSPORT
The rail transport industry comprises a mix of state-owned
enterprises and private sector companies that develop and
provide rail network infrastructure, manufacture trains and provide
both passenger and freight services.97 Rail is the most electrified
transport sector globally, with around 75% of passenger rail and
50% of rail freight running on electric power as of 2019.98 More
than one-quarter of rail electricity worldwide is estimated to be
renewable.99 Business demand for renewables in rail transport
has focused almost entirely on the direct use of biofuels and on
renewable electricity, but developments also have occurred in
renewable hydrogen.100 At least two companies set targets for net
zero carbon emissions during 2020: Indian Railways by 2030 and
UK-based Network Rail by 2050.101
Company Examples and Business Groups
Direct use of renewables in trains has been under way for some
time. In 2007, Virgin Group (UK) launched Europe’s first regular
biofuel-powered passenger train service in the United Kingdom,
and trains in parts of India have been running on biodiesel since
at least 2015.102 Florida Power and Light (US) began supplying
biodiesel for high-speed inter-city rail service in 2017.103 Also that
year, Arriva (France) won a contract to provide 18 new biodiesel
trains to the Netherlands starting in 2020, and successful trials
were completed in July 2020.104
Rail freight companies that seek to decarbonise using renewable
electricity can opt to procure electric-power trains from
manufacturers; however, if they wish to source their electricity
from renewables, they may have to depend on network
infrastructure providers. In some cases, companies have invested
directly in renewable power capacity to provide electricity for
their activities. In early 2020, Amp Energy (India) partnered with
Hyderabad Metro Rail to install a 7.8 MW solar PV plant to power
the railway’s operations.105 Japan’s largest railway company,
East Japan Railway, began investing in solar power in 2013 for
operational use, and in early 2021 the company announced plans
to increase its share of renewable power in order to reach its
target of zero carbon dioxide emissions by 2050.106
A growing number of rail companies have experimented with
green hydrogen. Between February and March 2020, testing
advanced on the world’s first renewable hydrogen passenger
train, as a group of French and Dutch companiesi was able
to successfully refuel the train in Groningen (Netherlands).107
Energy company ENGIE (France) continued working with
Gasunie (Netherlands) to develop a large-scale renewable
hydrogen plant in Groningen, as a part of a long-term push to
shift passenger trains in the northern Netherlands from diesel to
green hydrogen.108 In Italy, Enel Green Power and the transport
firm FNM formed a joint venture in early 2021 to develop green
hydrogen options for the rail network of Lombardy, as part of the
H2IseO project to create a Hydrogen Valley in the province.109
i ENGIE refuelled the train, working alongside French train manufacturer
Alstom, French rail services company Arriva, Dutch railway infrastructure
agency ProRail and the independent testing organisation DEKRA.
237
i Members include: Antwerp, Barcelona, Gothenburg, Hamburg, Le Havre, Long Beach, Los Angeles, New York and New Jersey, Rotterdam, Valencia, Vancouver
and Yokohama.
ii In 2018, the International Maritime Organization, the international shipping regulatory body, set a goal of reducing greenhouse gas emissions in the sector 50%
by 2050 (compared to 2008 levels), with carbon intensity reduction targets also set for 2030 and 2050.
RENEWABLES 2021 GLOBAL STATUS REPORT
MARITIME SHIPPING
Business demand for renewables in maritime shipping has focused
primarily on biofuels, with interest also growing in renewable
hydrogen and ammonia.110 In 2020, biofuels accounted for around
0.1% of the total global demand for shipping fuel.111 Although biofuels
have been more expensive compared to fossil-based options, cost
differentials continued to narrow, leading them to be considered
both a commercially and technically viable alternative.112
Company Examples and Business Groups
A growing number of shipping companies have shown interest in
increasing their use of renewable fuels, and some have completed
successful voyages with them. In June 2020, a dredging vessel
operated by Jan De Nul Group (Belgium) was the first to sail
2,000 hours on 100% renewable fuels, in collaboration with
MAN Energy Solutions (Germany) and GoodFuels (Netherlands),
marking the longest continuous use of 100% renewable fuels in
the sector.113 In March 2021, a Höegh Autoliners (Norway) vessel
completed its first nearly carbon-neutral voyage between South
Africa and Europe using advanced biofuels – reducing carbon
emissions around 90% – and the company announced plans to
scale up its procurement of shipping biofuels.114
Other companies were in the testing phase during 2020. The
cargo firm Stena Bulk (Sweden) conducted a test voyage on a
medium-range tanker ship using 100% biofuel (MR1-100) – based
on waste cooking oil supplied by GoodFuels – and was able to
reduce overall carbon emissions more than 80%.115 Eastern
Pacific Shipping (Singapore) also contracted with GoodFuels
to supply biofuel bunkers for a medium-range tanker, with the
aim of trialling biofuels in other classes of ships in the near
future.116 Under the GoodShipping programme, automaker BMW
(Germany) partnered with the shipping firm UECC (Norway) to
test marine biofuel on UECC ships carrying BMW cars, with the
goal of reducing emissions 80-90%.117 Also in 2020, the Finnish
firms SSAB Raahe, Gasum and ESL Shipping began testing the
use of liquefied biogas in shipping, following agreements signed
in 2019 by several Scandinavian shipping companies, including
Preem (Sweden) and Hurtigruten (Norway), to use the fuel.118
Interest and activity in renewable hydrogen and ammonia
also increased in the maritime sector.119 In 2020, the HySHIP
consortium, led by Norwegian shipping company Wilhelmsen,
obtained EUR 8 million (USD 9.8 million) in EU funding to build a
prototype ship powered by renewable hydrogen.120 In addition, the
ShipFC consortium of 14 European companies and institutions
received EUR 10 million (USD 12.3 million) in EU funding to
retrofit (in 2024) an offshore vessel with the world’s first fuel cell
powered by green ammonia.121
Maritime ports are working with shipping companies (and each
other) to promote increased demand for renewable fuels. The
World Ports Climate Action Programme, a coalition of 12 leading
portsi, aims to reduce carbon emissions from shipping and ports
through the accelerated development of commercially viable
“low-carbon fuels”, among other steps.122 In a different approach,
26 global shipping banks and top industry players from Asia,
Europe and North America developed the Poseidon Principles
to encourage more sustainable shipping practices, including
greater use of renewables, in alignment with the International
Maritime Organization’s emission reduction goalsii.123
238
i SAF are produced from renewable sustainable feedstocks from bioenergy sources.
ii These are customised contracts between two parties to buy or sell an asset at a specified price on a future date.
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AVIATION
Business demand for renewable energy in aviation comes mainly
from airline and airport companies. Sustainable aviation fuels
(SAF)i have been developed primarily from bioenergy sources
and technology, and e-fuels are produced from synthesising
carbon dioxide (such as synthetic paraffinic kerosene, or SPK)
and renewable hydrogen. The latter also can be used in fuel cells
to power aviation systems based on electric propulsion.
The first flight using aviation biofuel was made in 2008, and by
the end of 2020 more than 40 airlines had used SAF.124 Since 2011,
more than 315,000 commercial flights have flown on a blend of
SAF, and 6 billion litres of the fuels have been purchased through
forward purchase agreementsii.125 However, SAF accounted
for less than 0.1% of total aviation fuel demand in 2020.126
Biofuels used in aviation typically must be combined with fossil-
based jet kerosene to achieve certain blend rates.127 These
blends could potentially reach 50% but in practice tend to be
less than 1%, due to the relatively high cost of SAF (some of the
fuels can cost five times their kerosene equivalent) and to the
limited availability of even the most commercially viable aviation
biofuels.128 By the end of 2020, most SAF demand was in Europe
and California (US), where dedicated policy incentives exist for
SAF and other “low-carbon fuels”.129 Five airports worldwide –
in Bergen, Brisbane, Los Angeles, Oslo and Stockholm – had
facilities that regularly distributed SAF, while others offered
semi-regular supply.130
Interest in the electrification of aviation has increased. As of May
2021, mostly just drones or small planes had been developed,
although some companies were planning fully electric airliners
to carry more than 120 passengers.131 Others are aiming for
hydrogen-powered electric planes.132 So far, none of these
ventures has had a direct link to renewable energy.
Company Examples and Business Groups
Some airlines are boosting their sustainable aviation ambitions.
In 2020, Scandinavian Airlines committed to running all
domestic flights (representing less than 20% of the company’s
total fuel demand) on SAF by 2030.133 KLM (Netherlands) is
working with Amsterdam’s Schiphol airport and fuel producer
Neste to develop SAF supply facilities by 2022.134 In 2020, British
Airways, FinnAir, Lufthansa (Germany) and Virgin (UK) pledged
to scale up their demand for aviation biofuel, as have air cargo
carriers Amazon Air, FedEx and UPS (all US).135 In addition, a
few countries have conditioned their allocation of COVID-19
bailout funds to the aviation industry on a stronger commitment
to renewable fuels. (p See Sidebar 3 in Policy chapter.)
Companies also continued to develop electric and hydrogen
aircraft, although in most cases these efforts do not specify the
use of renewable energy. In 2020, Wright Electric announced the
launch of an electric propulsion programme to develop a 186-
seat aircraft for the carrier EasyJet.136
The business-based coalition Clean Skies for Tomorrow
(CST) is committed to achieving broad adoption of SAF by
2030 and includes nearly 90 aviation companies, among
them Airbus, Boeing, KLM Royal Dutch Airlines, Amsterdam’s
Schiphol Airport, London’s Heathrow Airport, Shell, SkyNRG
and SpiceJet.137 CST is part of the broader Mission Possible
Partnership developed by the World Economic Forum, the
We Mean Business coalition, RMI and the Energy Transitions
Commission. Its plan includes developing a mechanism
to aggregate airline demand for aviation biofuel, similar to
an aggregated corporate PPA for renewable electricity.138
Business demand for
renewables
in aviation and
shipping
continued to advance at a
slow pace.
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RENEWABLES 2021 GLOBAL STATUS REPORT
ENERGY UNITS AND CONVERSION FACTORS
Example: 1 TJ = 1,000 GJ = 1,000,000 MJ = 1,000,000,000 kJ = 1,000,000,000,000 J
METRIC PREFIXES
kilo (k) = 103
mega (M) = 106
giga (G) = 109
tera (T) = 1012
peta (P) = 1015
exa (E) = 1018
VOLUME
1 m3 = 1,000 litres (l)
1 US gallon = 3.785412 l
1 Imperial gallon = 4.546090 l
Note on Biofuels:
1) These values can vary with fuel and temperature.
2) Around 1.7 litres of ethanol is energy equivalent to 1 litre of petrol, and around 1.2 litres of biodiesel (FAME) is energy equivalent
to 1 litre of diesel.
3) Energy values from http://ec.europa.eu/eurostat/statistics-explained/index.php/Glossary:Tonnes_of_oil_equivalent_(toe)
except HVO, which is from Neste Renewable Diesel Handbook, p. 15, https://www.neste.com/sites/default/files/attachments/
neste_renewable_diesel_handbook .
BIOFUELS CONVERSION
Ethanol: 21.4 MJ/l
Biodiesel (FAME): 32.7 MJ/l
Biodiesel (HVO): 34.4 MJ/l
Petrol: 36 MJ/l
Diesel: 41 MJ/l
SOL AR THERMAL HEAT SYSTEMS
1 million m2 = 0.7 GWth
Used where solar thermal heat data have been converted
from square metres (m2) into gigawatts thermal (GWth), by
accepted convention.
ENERGY UNIT CONVERSION
Example: 1 MWh x 3.600 = 3.6 GJ
Toe = tonnes (metric) of oil equivalent
1 Mtoe = 41.9 PJ
Multiply by: GJ Toe MBtu MWh
GJ 1 0.024 0.948 0.278
Toe 41.868 1 39.683 11.630
MBtu 1.055 0.025 1 0.293
MWh 3.600 0.086 3.412 1
240
MN
DATA COLLECTION AND VALIDATION
REN21 has developed a unique renewable energy reporting culture, allowing it to become recognised as a neutral data and knowledge
broker that provides credible and widely accepted information. Transparency is at the heart of the REN21 data and reporting culture,
and the following text explains some of the GSR’s key processes for data collection and validation.
DATA COLLECTION
Production of REN21’s GSR is a continuous process occurring
on an annual basis. The data collection process begins following
the launch of the previous year’s report with an Expression of
Interest form to mobilise REN21’s GSR contributors. During
this time, the GSR team also prepares the questionnaires that
will be filled in by contributors. The questionnaires are updated
each year with emerging and relevant topics as identified by
the REN21 Secretariat.
REN21 collects data in five main ways:
1. Country questionnaire. In the country questionnaire,
contributors from around the world submit data on renewable
energy in their respective countries or countries of interest. This
covers information about annual developments for renewable
energy technologies, market trends, policy developments
and local perspectives. The questionnaire also collects data
related to energy access from respondents with a focus on
developing and emerging countries, covering the status of
electrification and clean cooking, as well as policies and
programmes for energy access and markets for distributed
renewables. Each data point is provided with a source and
verified independently by the GSR team. Data collection with
the country questionnaire typically begins in October.
2. Peer review. To further collect data and project examples
and to ensure that significant developments have not been
overlooked, GSR contributors and reviewers participate in
an open peer review process that takes place twice during
each report cycle. The first round typically occurs in January
and includes Round 1 chapters such as Policy Landscape,
while the second round is held typically in March/April
and includes Round 2 chapters such as Global Overview
and Market and Industry Trends. Peer review is open to all
interested experts.
3. Expert interviews. REN21’s global community consists of a
wide range of professionals who provide their expert input on
renewable energy trends in the target year through interviews
and personal communication with the REN21 GSR team and
chapter authors. The vast majority of the information is backed
up by primary sources.
4. Desk research. To fill in remaining gaps in the GSR and to
pursue new topics, the REN21 GSR team and chapter authors
conduct extensive desk research. Topics of research vary
widely between GSR years and depend on emerging topics,
important trends and annual availability of formal or informal
data in the target sector.
5. Data sharing agreements. REN21 holds several data
sharing agreements with some of the largest and most
reliable data providers/aggregators in the energy sector.
These formal data are used exclusively in some cases or, in
others, form the foundation of calculations and estimations
presented in the GSR.
DATA VALIDATION
REN21 ensures the accuracy and reliability of its reports by conducting data validation and fact-checking as a continuous process.
Beginning during the first submission of the country questionnaires, data are continually verified up through the design period and until
the final report is published. All data provided by contributors, whether written or verbal, are validated by primary sources,
which are published alongside the full report.
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RENEWABLES 2021 GLOBAL STATUS REPORT
METHODOLOGICAL NOTES
This 2021 report is the 16th edition of the Renewables Global
Status Report (GSR), which has been produced annually since
2005 (with the exception of 2008). Readers are directed to the
previous GSR editions for historical details.
Most 2020 data for national and global capacity, output, growth
and investment provided in this report are preliminary. Where
necessary, information and data that are conflicting, partial
or older are reconciled by using reasoned expert judgment.
Endnotes provide additional details, including references,
supporting information and assumptions where relevant.
Each edition draws from thousands of published and unpublished
references, including: official government sources; reports from
international organisations and industry associations; input from
the GSR community via hundreds of questionnaires submitted
by country, regional and technology contributors as well as
feedback from several rounds of formal and informal reviews;
additional personal communications with scores of international
experts; and a variety of electronic newsletters, news media and
other sources.
Much of the data found in the GSR is built from the ground
up by the authors with the aid of these resources. This often
involves extrapolation of older data, based on recent changes in
key countries within a sector or based on recent growth rates
and global trends. Other data, often very specific and narrow in
scope, come more-or-less prepared from third parties. The GSR
attempts to synthesise these data points into a collective whole
for the focus year.
The GSR endeavours to provide the best data available in each
successive edition; as such, data should not be compared with
previous versions of this report to ascertain year-by-year changes.
NOTE ON ESTABLISHING RENEWABLE ENERGY SHARES OF
TOTAL FINAL ENERGY CONSUMPTION (TFEC)
Assumptions Related to Renewable Electricity Shares of TFEC
When estimating electricity consumption from renewable
sources, the GSR must make certain assumptions about how
much of the estimated gross output from renewable electricity
generating resources actually reaches energy consumers, as part
of total final energy consumption.
The International Energy Agency’s (IEA) World Energy Statistics
and Balances reports electricity output by individual technology.
However, it does not report electricity consumption by technology
– only total consumption of electricity.
The difference between gross output and final consumption is
determined by:
n The energy industry’s own-use, including electricity used for
internal operations at power plants. This includes the power
consumption of various internal loads, such as fans, pumps
and pollution controls at thermal plants, and other uses such
as electricity use in coal mining and fossil fuel refining.
n Transmission and distribution losses that occur as electricity
finds its way to consumers.
Industry’s own-use. The common method is to assume that
the proportion of consumption by technology is equal to the
proportion of output by technology. This is problematic because
logic dictates that industry’s own-use cannot be proportionally
the same for every generating technology. Further, industry’s
own-use must be somewhat lower for some renewable
generating technologies (particularly non-thermal renewables
such as hydropower, solar PV and wind power) than is the case
for fossil fuel and nuclear power technologies. Such thermal
power plants consume significant amounts of electricity to meet
their own internal energy requirements (see above).
Therefore, the GSR has opted to apply differentiated “industry
own-use” by generating technology. This differentiation is based
on explicit technology-specific own-use (such as pumping at
hydropower facilities) as well as on the apportioning of various
categories of own-use by technology as deemed appropriate.
For example, industry own-use of electricity at coal mines and oil
refineries is attributed to fossil fuel generation.
Differentiated own-uses by technology, combined with global
average losses, are as follows: solar PV, ocean energy and wind
power (8.2%); hydropower (10.1%); concentrating solar thermal
power (CSP) (14.2%); and bio-power (15.2%). For comparison, the
undifferentiated (universal) combined losses and industry own-
use would be 16.7% of gross generation. Estimated technology-
specific industry own-use of electricity from renewable sources
is based on data for 2018 from IEA, World Energy Balances, 2020
edition (Paris: 2020).
Transmission and distribution losses. Such losses may differ
(on average) by generating technology. For example, hydropower
plants often are located far from load centres, incurring higher
than average transmission losses, whereas some solar PV
generation may occur near to (or at) the point of consumption,
incurring little (or zero) transmission losses. However, specific
information by technology on a global scale is not available.
Therefore, the GSR has opted to apply a global average for
transmission and distribution losses. Global average electricity
losses are based on data for 2018 from IEA, World Energy
Balances, 2020 edition (Paris: 2020).
NOTES ON RENEWABLE ENERGY IN TOTAL FINAL ENERGY
CONSUMPTION, BY ENERGY USE
GSR 2021 presents an illustration of the share of renewable energy
in total final energy consumption (TFEC) by sector in 2018. (p See
Figure 4 in Global Overview chapter.) The share of TFEC consumed
in each sector is provided as follows: thermal (51%), transport
(32%) and electricity (17%). There are three important points about
this figure and about how the GSR treats end-use TFEC in general:
1. Definition of Heating and Cooling and Thermal Applications
In the GSR, the term “heating and cooling” refers to applications
of thermal energy including space and water heating, space
cooling, refrigeration, drying and industrial process heat, as well
as any use of energy other than electricity that is used for motive
power in any application other than transport. In other words,
thermal demand refers to all end-uses of energy that cannot be
classified as electricity demand or transport.
242
MN
2. Sectoral Shares of TFEC
In Figure 4, each sectoral share of TFEC portrays the energy
demand for all end-uses within the sector. The shares of TFEC
allocated to thermal and to transport also account for the electricity
consumed in these sectors – that is, electricity for space heating
and space cooling, industrial process heat, etc., and electricity
for transport. These amounts have been reallocated from final
demand in the electricity sector. Therefore, the share of TFEC
allocated to the electricity sector comprises all final end-uses of
electricity that are not used for heating, cooling or transport. This
is a methodological change from GSR 2018 that was intended to
strengthen the accuracy of the representation. In total, the final
energy consumption of all electrical energy accounted for 25.6%
of TFEC in 2018.
3. Shares of Non-renewable Electricity
Figure 3 illustrates the share of non-renewable electricity in
thermal and in transport to emphasise that electricity demand
is being allocated to each sector. The share of non-renewable
electricity is not critical to the figure content, so the percentage
value of non-renewable electricity in each sector is not explicitly
shown, but it is included in this note. In 2018, all electricity for
heating and cooling met 7.8% of final energy demand in the
sector (2.1% renewable and 5.7% non-renewable electricity). All
electricity for transport met 1.1% of final energy demand in the
sector (0.3% renewable and 0.8% non-renewable electricity).
NOTES ON RENEWABLE ENERGY CAPACITIES AND ENERGY
OUTPUT
A number of issues arise when counting renewable energy
capacities and energy output. Some of these are discussed below:
1. Capacity versus Energy Data
The GSR aims to give accurate estimates of capacity additions
and totals, as well as of electricity, heat and transport fuel
production in the focus year. These measures are subject to
some uncertainty, which varies by technology. The Market and
Industry chapter includes estimates for energy produced where
possible, but it focuses mainly on power or heat capacity data.
This is because capacity data generally can be estimated with a
greater degree of confidence than generation data. Official heat
and electricity generation data often are not available for the
target year within the production time frame of the GSR.
2. Constructed Capacity versus Connected Capacity and
Operational Capacity
Over a number of years in the past decade, the solar PV and wind
power markets saw increasing amounts of capacity that was
connected to the grid but not yet deemed officially operational,
or constructed capacity that was not connected to the grid by
year’s end. Therefore, since the 2012 edition the GSR has aimed
to count only capacity additions that were grid-connected or
that otherwise went into service (e.g., capacity intended for off-
grid use) during the previous calendar (focus) year. However, it
appears that this phenomenon is no longer an issue, with the
exception of wind power installations in China, where it was
particularly evident over the period 2009-2019. For details on the
situation in China and on the reasoning for capacity data used
in this GSR, see endnote 24 in the Wind Power section of the
Market and Industry chapter.
3. Retirements and Replacements
Data on capacity retirements and replacements (re-powering)
are incomplete for many technologies, although data on several
technologies do attempt to account for these directly. It is not
uncommon for reported new capacity installations to exceed the
implied net increase in cumulative capacity; in some instances, this
is explained by revisions to data on installed capacity, while in others
it is due to capacity retirements and replacements. Where data are
available, they are provided in the text or relevant endnotes.
4. Bioenergy Data
Given existing complexities and constraints, the GSR strives to
provide the best and latest data available regarding bioenergy
developments. The reporting of biomass-fired combined heat
and power (CHP) systems varies among countries; this adds
to the challenges experienced when assessing total heat and
electricity capacities and total bioenergy outputs.
Wherever possible, the bio-power data presented include
capacity and generation from both electricity-only and CHP
systems using solid biomass, landfill gas, biogas and liquid
biofuels. Electricity generation and capacity numbers are based
on national data for the focus year in the major producing
countries and on forecast data for remaining countries for the
focus year from the IEA.
The methodology is similar for biofuels production data, with data
for most countries (not major producers) from the IEA; however,
data for hydrotreated vegetable oil (HVO) are estimated based
on production statistics for the (relatively few) major producers.
Bio-heat data are based on an extrapolation of the latest data
available from the IEA based on recent growth trends. (p See
Bioenergy section in Market and Industry chapter.)
5. Hydropower Data and Treatment of Pumped Storage
Starting with the 2012 edition, the GSR has made an effort to
report hydropower generating capacity without including pure
pumped storage capacity (the capacity used solely for shifting
water between reservoirs for storage purposes). The distinction is
made because pumped storage is not an energy source but rather
a means of energy storage. It involves conversion losses and can
be fed by all forms of electricity, renewable and non-renewable.
Some conventional hydropower facilities do have pumping
capability that is not separate from, or additional to, their normal
generating capability. These facilities are referred to as “mixed”
plants and are included, to the extent possible, with conventional
hydropower data. It is the aim of the GSR to distinguish and
separate only the pure (or incremental) pumped storage
component.
Where the GSR presents data for renewable power capacity
not including hydropower, the distinction is made because
hydropower remains the largest single component by far of
renewable power capacity, and thus can mask developments
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RENEWABLES 2021 GLOBAL STATUS REPORT
in other renewable energy technologies if included. Investments
and jobs data separate out large-scale hydropower where original
sources use different methodologies for tracking or estimating
values. Footnotes and endnotes provide additional details.
6. Solar PV Capacity Datai
The capacity of a solar PV panel is rated according to direct
current (DC) output, which in most cases must be converted
by inverters to alternating current (AC) to be compatible with
end-use electricity supply. No single equation is possible for
calculating solar PV data in AC because conversion depends on
many factors, including the inverters used, shading, dust build-up,
line losses and temperature effects on conversion efficiency. The
difference between DC and AC power can range from as little as
5% (conversion losses or inverter set at the DC level) to as much
as 40% (due to grid regulations limiting output or to the evolution
of utility-scale systems), and most utility-scale plants built in 2019
have ratios in the range of 1.1 to 1.6ii.
The GSR attempts to report all solar PV capacity data on the basis
of DC output (where data are known to be provided in AC, this is
specified) for consistency across countries. Some countries (for
example, Canada, Chile, India, Japan, Malaysia, Spain, Sweden
and the United States) report official capacity data on the basis
of output in AC; these capacity data were converted to DC
output by data providers (see relevant endnotes) for the sake
of consistency. Global renewable power capacity totals in this
report include solar PV data in DC; as with all statistics in this
report, they should be considered as indicative of global capacity
and trends rather than as exact statistics.
7. Concentrating Solar Thermal Power (CSP) Data
Global CSP data are based on commercial facilities only.
Demonstration or pilot facilities and facilities of 5 MW or
less are excluded. Discrepancies between REN21 data and
other reference sources are due primarily to differences in
categorisation and thresholds for inclusion of specific CSP
facilities in overall global totals. The GSR aims to report net CSP
capacities for specific CSP plants that are included. In certain
cases, it may not be possible to verify if the reported capacity
of a given CSP plant is net or gross capacity. In these cases net
capacity is assumed.
8. Solar Thermal Heat Data
Starting with GSR 2014, the GSR includes all solar thermal
collectors that use water as the heat transfer medium (or heat
carrier) in global capacity data and the ranking of top countries.
Previous GSRs focused primarily on glazed water collectors
(both flat plate and evacuated tube); the GSR now also includes
unglazed water collectors, which are used predominantly for
swimming pool heating. Since the GSR 2018, data for concentrating
collectors are available. These include new installations overall as
well as in key markets and total in operation by year’s end. The
market for solar air collectors (solar thermal collectors that use
air as the heat carrier) and hybrid or PV-thermal technologies
(elements that produce both electricity and heat) is small and the
data rather uncertain. All three collector types – air, concentrating
and hybrid collectors – are included where specified.
Revised gross additions for 2019 included in this GSR (26.1 GWth)
are significantly lower than those published in GSR 2020 (31.3
GWth) for two reasons: First, the Chinese Solar Thermal Industry
Federation (CSTIF) adjusted downwards its number for China’s
new additions in 2019, from 22.75 GWth (a preliminary figure,
available as of early 2020) to 20 GWth. Second, data for new
additions in China are based on produced collector area, rather
than on annual installations in China; as a result, export volumes
have been included in China’s national statistics for 2020 and
earlier years. In past editions of the GSR, this has resulted in a
double counting of some collector area because the majority
of coated vacuum tubes installed worldwide are purchased
from China. For more details, see endnotes 1 and 5 in the Solar
Thermal Heating section of the Market and Industry chapter.
OTHER NOTES
Editorial content of this report closed by 31 May 2021 for
technology data, and by 15 May 2021 or earlier for other content.
Growth rates in the GSR are calculated as compound annual growth
rates (CAGR) rather than as an average of annual growth rates.
All exchange rates in this report are as of 31 December 2020
and are calculated using the OANDA currency converter (http://
www.oanda.com/currency/converter).
Corporate domicile, where noted, is determined by the location
of headquarters.
i See Solar PV section of the Market and Industry chapter for sources on capacity data.
ii See IEA PVPS, Trends in Photovoltaic Applications 2019, p. 9, and IEA PVPS, Snapshot of Global PV Markets 2020, p. 11.
244
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GL
GLOSSARY
Absorption chillers. Chillers that use heat energy from any
source (solar, biomass, waste heat, etc.) to drive air conditioning or
refrigeration systems. The heat source replaces the electric power
consumption of a mechanical compressor. Absorption chillers
differ from conventional (vapour compression) cooling systems in
two ways: 1) the absorption process is thermochemical in nature
rather than mechanical, and 2) the substance that is circulated
as a refrigerant is water rather than chlorofluorocarbons (CFCs)
or hydrochlorofluorocarbons (HCFCs), also called Freon. The
chillers generally are supplied with district heat, waste heat or
heat from co-generation, and they can operate with heat from
geothermal, solar or biomass resources.
Adsorption chillers. Chillers that use heat energy from any
source to drive air conditioning or refrigeration systems. They
differ from absorption chillers in that the adsorption process
is based on the interaction between gases and solids. A solid
material in the chiller’s adsorption chamber releases refrigerant
vapour when heated; subsequently, the vapour is cooled
and liquefied, providing a cooling effect at the evaporator by
absorbing external heat and turning back into a vapour, which is
then re-adsorbed into the solid.
Auction. See Tendering.
Bagasse. The fibrous matter that remains after extraction of
sugar from sugar cane.
Behind-the-meter system. Any power generation capacity,
storage or demand management on the customer side of the
interface with the distribution grid (i.e., the meter). (Also see
Front-of-meter system.)
Biodiesel. A fuel produced from oilseed crops such as soy,
rapeseed (canola) and palm oil, and from other oil sources such
as waste cooking oil and animal fats. Biodiesel is used in diesel
engines installed in cars, trucks, buses and other vehicles, as
well as in stationary heat and power applications. Most biodiesel
is made by chemically treating vegetable oils and fats (such as
palm, soy and canola oils, and some animal fats) to produce fatty
acid methyl esters (FAME). (Also see Hydrotreated vegetable oil
(HVO) and hydrotreated esters and fatty acids (HEFA).)
Bioeconomy (or bio-based economy). Economic activity
related to the invention, development, production and use of
biomass resources for the production of food, fuel, energy,
chemicals and materials.
Bioenergy. Energy derived from any form of biomass (solid, liquid
or gaseous) for heat, power and transport. (Also see Biofuel.)
Biofuel. A liquid or gaseous fuel derived from biomass, primarily
ethanol, biodiesel and biogas. Biofuels can be combusted in
vehicle engines as transport fuels and in stationary engines
for heat and electricity generation. They also can be used for
domestic heating and cooking (for example, as ethanol gels).
Conventional biofuels are principally ethanol produced by
fermentation of sugar or starch crops (such as wheat and corn),
and FAME biodiesel produced from oil crops such as palm oil
and canola and from waste oils and fats. Advanced biofuels are
made from feedstocks derived from the lignocellulosic fractions of
biomass sources or from algae. They are made using biochemical
and thermochemical conversion processes, some of which are
still under development.
Biogas/Biomethane. Biogas is a gaseous mixture consisting
mainly of methane and carbon dioxide produced by the anaerobic
digestion of organic matter (broken down by microorganisms
in the absence of oxygen). Organic material and/or waste is
converted into biogas in a digester. Suitable feedstocks include
agricultural residues, animal wastes, food industry wastes,
sewage sludge, purpose-grown green crops and the organic
components of municipal solid wastes. Raw biogas can be
combusted to produce heat and/or power. It also can be refined
to produce biomethane.
Biomass. Any material of biological origin, excluding fossil
fuels or peat, that contains a chemical store of energy (originally
received from the sun) and that is available for conversion to a
wide range of convenient energy carriers.
Biomass, traditional (use of). Solid biomass (including fuel
wood, charcoal, agricultural and forest residues, and animal
dung), that is used in rural areas of developing countries with
traditional technologies such as open fires and ovens for cooking
and residential heating. Often the traditional use of biomass leads
to high pollution levels, forest degradation and deforestation.
Biomass energy, modern. Energy derived from combustion
of solid, liquid and gaseous biomass fuels in high-efficiency
conversion systems, which range from small domestic appliances
to large-scale industrial conversion plants. Modern applications
include heat and electricity generation, combined heat and
power (CHP) and transport.
Biomass gasification. In a biomass gasification process,
biomass is heated with a constrained amount of air or oxygen,
leading to the partial combustion of the fuels and production of a
mix of combustion gases that, depending on the conditions, can
include carbon monoxide and dioxide, methane, hydrogen and
more complex materials such as tars. The resulting gas can either
be used for power generation (e.g., in an engine or turbine) or else
further purified and treated to form a “synthesis gas”. This can
then be used to produce fuels including methane, alcohols, and
higher hydrocarbon fuels, including bio-gasoline or jet fuel. While
gasification for power or heat production is relatively common,
there are few examples of operating plants producing gas of high
enough quality for subsequent synthesis to more complex fuels.
Biomass pellets. Solid biomass fuel produced by compressing
pulverised dry biomass, such as waste wood and agricultural
residues. Pellets typically are cylindrical in shape with a diameter
of around 10 millimetres and a length of 30-50 millimetres.
Pellets are easy to handle, store and transport and are used as
fuel for heating and cooking applications, as well as for electricity
generation and CHP. (Also see Torrefied wood.)
Biomethane. Biogas can be turned into biomethane by removing
impurities including carbon dioxide, siloxanes and hydrogen
sulphides, followed by compression. Biomethane can be injected
directly into natural gas networks and used as a substitute
for natural gas in internal combustion engines without risk of
corrosion. Biomethane is often known as renewable natural gas
(RNG), especially in North America.
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Blockchain. A decentralised ledger in which digital transactions
(such as the generation and sale of a unit of solar electricity) are
anonymously recorded and verified. Each transaction is securely
collected and linked, via cryptography, into a time-stamped
“block”. This block is then stored on distributed computers as a
“chain”. Blockchain may be used in energy markets, including for
micro-trading among solar photovoltaic (PV) prosumers.
Building energy codes and standards. Rules specifying the
minimum energy standards for buildings. These can include
standards for renewable energy and energy efficiency that are
applicable to new and/or renovated and refurbished buildings.
Capacity. The rated power of a heat or electricity generating
plant, which refers to the potential instantaneous heat or
electricity output, or the aggregate potential output of a
collection of such units (such as a wind farm or set of solar
panels). Installed capacity describes equipment that has
been constructed, although it may or may not be operational
(e.g., delivering electricity to the grid, providing useful heat or
producing biofuels).
Capacity factor. The ratio of the actual output of a unit of
electricity or heat generation over a period of time (typically one
year) to the theoretical output that would be produced if the unit
were operating without interruption at its rated capacity during
the same period of time.
Capital subsidy. A subsidy that covers a share of the upfront
capital cost of an asset (such as a solar water heater). These include,
for example, consumer grants, rebates or one-time payments by a
utility, government agency or government-owned bank.
Carbon neutrality. See Net zero emissions.
Combined heat and power (CHP) (also called co-generation).
CHP facilities produce both heat and power from the combustion
of fossil and/or biomass fuels, as well as from geothermal and
solar thermal resources. The term also is applied to plants that
recover “waste heat” from thermal power generation processes.
Community energy. An approach to renewable energy
development that involves a community initiating, developing,
operating, owning, investing and/or benefiting from a project.
Communities vary in size and shape (e.g., schools, neighbourhoods,
partnering city governments, etc.); similarly, projects vary in
technology, size, structure, governance, funding and motivation.
Competitive bidding. See Tendering.
Concentrating photovoltaics (CPV). Technology that uses
mirrors or lenses to focus and concentrate sunlight onto a
relatively small area of photovoltaic cells that generate electricity
(see Solar photovoltaics). Low-, medium- and high-concentration
CPV systems (depending on the design of reflectors or lenses
used) operate most efficiently in concentrated, direct sunlight.
Concentrating solar collector technologies. Technologies
that use mirrors to focus sunlight on a receiver (see Concentrating
solar thermal power). These are usually smaller-sized modules
that are used for the production of heat and steam below 400°C
for industrial applications, laundries and commercial cooking.
Concentrating solar thermal power (CSP) (also called solar
thermal electricity, STE). Technology that uses mirrors to focus
sunlight into an intense solar beam that heats a working fluid
in a solar receiver, which then drives a turbine or heat engine/
generator to produce electricity. The mirrors can be arranged
in a variety of ways, but they all deliver the solar beam to the
receiver. There are four types of commercial CSP systems:
parabolic troughs, linear Fresnel, power towers and dish/engines.
The first two technologies are line-focus systems, capable of
concentrating the sun’s energy to produce temperatures of
400°C, while the latter two are point-focus systems that can
produce temperatures of 800°C or higher.
Conversion efficiency. The ratio between the useful energy
output from an energy conversion device and the energy input
into it. For example, the conversion efficiency of a PV module
is the ratio between the electricity generated and the total solar
energy received by the PV module. If 100 kWh of solar radiation
is received and 10 kWh of electricity is generated, the conversion
efficiency is 10%.
Crowdfunding. The practice of funding a project or venture
by raising money – often relatively small individual amounts –
from a relatively large number of people (“crowd”), generally
using the Internet and social media. The money raised through
crowdfunding does not necessarily buy the lender a share in the
venture, and there is no guarantee that money will be repaid if
the venture is successful. However, some types of crowdfunding
reward backers with an equity stake, structured payments and/
or other products.
Curtailment. A reduction in the output of a generator, typically on
an involuntary basis, from what it could produce otherwise given
the resources available. Curtailment of electricity generation has
long been a normal occurrence in the electric power industry and
can occur for a variety of reasons, including a lack of transmission
access or transmission congestion.
Degression. A mechanism built into policy design establishing
automatic rate revisions, which can occur after specific thresholds
are crossed (e.g., after a certain amount of capacity is contracted,
or a certain amount of time passes).
Demand-side management. The application of economic
incentives and technology in the pursuit of cost-effective energy
efficiency measures and load-shifting on the customer side, to
achieve least-cost overall energy system optimisation.
Demand response. Use of market signals such as time-of-use
pricing, incentive payments or penalties to influence end-user
electricity consumption behaviours. Usually used to balance
electrical supply and demand within a power system.
Digitalisation. The application of digital technologies across the
economy, including energy.
Digitisation. The conversion of something (e.g., data or an
image) from analogue to digital.
Distributed generation. Generation of electricity from
dispersed, generally small-scale systems that are close to the
point of consumption.
Distributed renewable energy. Energy systems are considered
to be distributed if 1) the systems are connected to the distribution
network rather than the transmission network, which implies
that they are relatively small and dispersed (such as small-scale
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solar PV on rooftops) rather than relatively large and centralised;
or 2) generation and distribution occur independently from a
centralised network. Specifically for the purpose of the chapter
on Distributed Renewables for Energy Access, “distributed
renewable energy” meets both conditions. It includes energy
services for electrification, cooking, heating and cooling that
are generated and distributed independent of any centralised
system, in urban and rural areas of the developing world.
Distribution grid. The portion of the electrical network that takes
power off the high-voltage transmission network via sub-stations
(at varying stepped-down voltages) and distributes electricity to
customers.
Drop-in biofuel. A liquid biofuel that is functionally equivalent
to a liquid fossil fuel and is fully compatible with existing fossil
fuel infrastructure.
Electric vehicle (EV). Includes any road-, rail-, sea- and air-
based transport vehicle that uses electric drive and can take an
electric charge from an external source, or from hydrogen in the
case of a fuel cell electric vehicle (FCEV). Electric road vehicles
encompass battery electric vehicles (BEVs), plug-in hybrids
(PHEVs) and FCEVs, all of which can include passenger vehicles
(i.e., electric cars), commercial vehicles including buses and
trucks, and two- and three-wheeled vehicles.
Energy. The ability to do work, which comes in a number of forms
including thermal, radiant, kinetic, chemical, potential and electrical.
Primary energy is the energy embodied in (energy potential of)
natural resources, such as coal, natural gas and renewable sources.
Final energy is the energy delivered for end-use (such as electricity
at an electrical outlet). Conversion losses occur whenever primary
energy needs to be transformed for final energy use, such as
combustion of fossil fuels for electricity generation.
Energy audit. Analysis of energy flows in a building, process
or system, conducted with the goal of reducing energy inputs
into the system without negatively affecting outputs.
Energy conservation. Any change in behaviour of an energy-
consuming entity for the specific purpose of affecting an energy
demand reduction. Energy conservation is distinct from energy
efficiency in that it is predicated on the assumption that an
otherwise preferred behaviour of greater energy intensity is
abandoned. (See Energy efficiency and Energy intensity.)
Energy efficiency. The measure that accounts for delivering
more services for the same energy input, or the same amount of
services for less energy input. Conceptually, this is the reduction
of losses from the conversion of primary source fuels through
final energy use, as well as other active or passive measures to
reduce energy demand without diminishing the quality of energy
services delivered. Energy efficiency is technology-specific and
distinct from energy conservation, which pertains to behavioural
change. Both energy efficiency and energy conservation can
contribute to energy demand reduction.
Energy intensity. Primary energy consumption per unit of
economic output. Energy intensity is a broader concept than
energy efficiency in that it is also determined by non-efficiency
variables, such as the composition of economic activity. Energy
intensity typically is used as a proxy for energy efficiency in
macro-level analyses due to the lack of an internationally agreed-
upon high-level indicator for measuring energy efficiency.
Energy service company (ESCO). A company that provides a
range of energy solutions including selling the energy services
from a (renewable) energy system on a long-term basis while
retaining ownership of the system, collecting regular payments
from customers and providing necessary maintenance service. An
ESCO can be an electric utility, co-operative, non-governmental
organisation or private company, and typically installs energy
systems on or near customer sites. An ESCO also can advise on
improving the energy efficiency of systems (such as a building or
an industry) as well as on methods for energy conservation and
energy management.
Energy subsidy. A government measure that artificially reduces
the price that consumers pay for energy or that reduces energy
production cost.
Energy sufficiency. Entails a change or shift in actions and
behaviours (at the individual and collective levels) in the way energy
is used. Results in access to energy for everyone while limiting the
impacts of energy use on the environment. For example, avoiding
the use of cars and spending less time on electrical devices.
Ethanol (fuel). A liquid fuel made from biomass (typically corn,
sugar cane or small cereals/grains) that can replace petrol in
modest percentages for use in ordinary spark-ignition engines
(stationary or in vehicles), or that can be used at higher blend
levels (usually up to 85% ethanol, or 100% in Brazil) in slightly
modified engines, such as those provided in “flex-fuel” vehicles.
Ethanol also is used in the chemical and beverage industries.
Fatty acid methyl esters (FAME). See Biodiesel.
Feed-in policy (feed-in tariff or feed-in premium). A policy
that typically guarantees renewable generators specified
payments per unit (e.g., USD per kWh) over a fixed period.
Feed-in tariff (FIT) policies also may establish regulations by
which generators can interconnect and sell power to the grid.
Numerous options exist for defining the level of incentive, such
as whether the payment is structured as a guaranteed minimum
price (e.g., a FIT), or whether the payment floats on top of the
wholesale electricity price (e.g., a feed-in premium).
Final energy. The part of primary energy, after deduction of
losses from conversion, transmission and distribution, that
reaches the consumer and is available to provide heating, hot
water, lighting and other services. Final energy forms include,
among others, electricity, district heating, mechanical energy,
liquid hydrocarbons such as kerosene or fuel oil, and various
gaseous fuels such as natural gas, biogas and hydrogen.
(Total) Final energy consumption (TFEC). Energy that is
supplied to the consumer for all final energy services such as
transport, cooling and lighting, building or industrial heating or
mechanical work. Differs from total final consumption (TFC),
which includes all energy use in end-use sectors (TFEC) as well
as for non-energy applications, mainly various industrial uses,
such as feedstocks for petrochemical manufacturing.
Fiscal incentive. An incentive that provides individuals,
households or companies with a reduction in their contribution
to the public treasury via income or other taxes.
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Flywheel energy storage. Energy storage that works by
applying available energy to accelerate a high-mass rotor
(flywheel) to a very high speed and thereby storing energy in the
system as rotational energy.
Front-of-meter system. Any power generation or storage
device on the distribution or transmission side of the network.
(Also see Behind-the-meter system.)
Generation. The process of converting energy into electricity
and/or useful heat from a primary energy source such as wind,
solar radiation, natural gas, biomass, etc.
Geothermal energy. Heat energy emitted from within the
earth’s crust, usually in the form of hot water and steam. It can be
used to generate electricity in a thermal power plant or to provide
heat directly at various temperatures.
Green bond. A bond issued by a bank or company, the proceeds
of which will go entirely into renewable energy and other
environmentally friendly projects. The issuer will normally label it
as a green bond. There is no internationally recognised standard
for what constitutes a green bond.
Green building. A building that (in its construction or operation)
reduces or eliminates negative impacts and can create positive
impacts on the climate and natural environment. Countries and
regions have a variety of characteristics that may change their
strategies for green buildings, such as building stock, climate,
cultural traditions, or wide-ranging environmental, economic
and social priorities – all of which shape their approach to green
building.
Green energy purchasing. Voluntary purchase of renewable
energy – usually electricity, but also heat and transport fuels – by
residential, commercial, government or industrial consumers, either
directly from an energy trader or utility company, from a third-party
renewable energy generator or indirectly via trading of renewable
energy certificates (such as renewable energy credits, green tags
and guarantees of origin). It can create additional demand for
renewable capacity and/or generation, often going beyond that
resulting from government support policies or obligations.
Heat pump. A device that transfers heat from a heat source to
a heat sink using a refrigeration cycle that is driven by external
electric or thermal energy. It can use the ground (geothermal/
ground-source), the surrounding air (aerothermal/air-source) or
a body of water (hydrothermal/water-source) as a heat source in
heating mode, and as a heat sink in cooling mode. A heat pump’s
final energy output can be several multiples of the energy input,
depending on its inherent efficiency and operating condition. The
output of a heat pump is at least partially renewable on a final
energy basis. However, the renewable component can be much
lower on a primary energy basis, depending on the composition
and derivation of the input energy; in the case of electricity, this
includes the efficiency of the power generation process. The
output of a heat pump can be fully renewable energy if the input
energy is also fully renewable.
Hydropower. Electricity derived from the potential energy of
water captured when moving from higher to lower elevations.
Categories of hydropower projects include run-of-river, reservoir-
based capacity and low-head in-stream technology (the least
developed). Hydropower covers a continuum in project scale from
large (usually defined as more than 10 MW of installed capacity,
but the definition varies by country) to small, mini, micro and pico.
Hydrotreated vegetable oil (HVO) and hydrotreated esters
and fatty acids (HEFA). Biofuels produced by using hydrogen
to remove oxygen from waste cooking oils, fats and vegetable
oils. The result is a hydrocarbon that can be refined to produce
fuels with specifications that are closer to those of diesel and jet
fuel than is biodiesel produced from triglycerides such as fatty
acid methyl esters (FAME).
Inverter (and micro-inverter), solar. Inverters convert the direct
current (DC) generated by solar PV modules into alternating
current (AC), which can be fed into the electric grid or used by
a local, off-grid network. Conventional string and central solar
inverters are connected to multiple modules to create an array
that effectively is a single large panel. By contrast, micro-inverters
convert generation from individual solar PV modules; the output of
several micro-inverters is combined and often fed into the electric
grid. A primary advantage of micro-inverters is that they isolate
and tune the output of individual panels, reducing the effects that
shading or failure of any one (or more) module(s) has on the output
of an entire array. They eliminate some design issues inherent to
larger systems, and allow for new modules to be added as needed.
Investment. Purchase of an item of value with an expectation
of favourable future returns. In this report, new investment
in renewable energy refers to investment in: technology
research and development, commercialisation, construction of
manufacturing facilities and project development (including the
construction of wind farms and the purchase and installation of
solar PV systems). Total investment refers to new investment plus
merger and acquisition (M&A) activity (the refinancing and sale
of companies and projects).
Investment tax credit. A fiscal incentive that allows investments
in renewable energy to be fully or partially credited against the tax
obligations or income of a project developer, industry, building
owner, etc.
Joule. A joule (J) is a unit of work or energy equal to the work
done by a force equal to one newton acting over a distance of
one metre. One joule is equal to one watt-second (the power of
one watt exerted over the period of one second). The potential
chemical energy stored in one barrel of oil and released when
combusted is approximately 6 gigajoules (GJ); a tonne of oven-
dry wood contains around 20 GJ of energy.
Levelised cost of energy/electricity (LCOE). The cost per
unit of energy from an energy generating asset that is based on
the present value of its total construction and lifetime operating
costs, divided by total energy output expected from that asset
over its lifetime.
Long-term strategic plan. A strategy to achieve energy savings
over a specified period of time (i.e., several years), including
specific goals and actions to improve energy efficiency, typically
spanning all major sectors.
Mandate/Obligation. A measure that requires designated
parties (consumers, suppliers, generators) to meet a minimum –
and often gradually increasing – standard for renewable energy
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(or energy efficiency), such as a percentage of total supply, a
stated amount of capacity, or the required use of a specified
renewable technology. Costs generally are borne by consumers.
Mandates can include renewable portfolio standards (RPS);
building codes or obligations that require the installation of
renewable heat or power technologies (often in combination
with energy efficiency investments); renewable heat purchase
requirements; and requirements for blending specified shares of
biofuels (biodiesel or ethanol) into transport fuel.
Market concession model. A model in which a private
company or non-governmental organisation is selected through
a competitive process and given the exclusive obligation to
provide energy services to customers in its service territory,
upon customer request. The concession approach allows
concessionaires to select the most appropriate and cost-effective
technology for a given situation.
Merit order. A way of ranking available sources of energy
(particularly electricity generation) in ascending order based on
short-run marginal costs of production, such that those with the
lowest marginal costs are the first ones brought online to meet
demand, and those with the highest are brought on last. The
merit-order effect is a shift of market prices along the merit-order
or supply curve due to market entry of power stations with lower
variable costs (marginal costs). This displaces power stations with
the highest production costs from the market (assuming demand
is unchanged) and admits lower-priced electricity into the market.
Mini-grid / Micro-grid. For distributed renewable energy
systems for energy access, a mini-grid/micro-grid typically
refers to an independent grid network operating on a scale of
less than 10 MW (with most at very small scale) that distributes
electricity to a limited number of customers. Mini-/micro-grids
also can refer to much larger networks (e.g., for corporate or
university campuses) that can operate independently of, or
in conjunction with, the main power grid. However, there is no
universal definition differentiating mini- and micro-grids.
Molten salt. An energy storage medium used predominantly
to retain the thermal energy collected by a solar tower or solar
trough of a concentrating solar power plant, so that this energy
can be used at a later time to generate electricity.
Monitoring. Energy use is monitored to establish a basis for
energy management and to provide information on deviations
from established patterns.
Municipal solid waste. Waste materials generated by
households and similar waste produced by commercial, industrial
or institutional entities. The wastes are a mixture of renewable
plant and fossil-based materials, with the proportions varying
depending on local circumstances. A default value that assumes
that at least 50% of the material is “renewable” is often applied.
Net metering / Net billing. A regulated arrangement in which utility
customers with on-site electricity generators can receive credits for
excess generation, which can be applied to offset consumption
in other billing periods. Under net metering, customers typically
receive credit at the level of the retail electricity price. Under net
billing, customers typically receive credit for excess power at a rate
that is lower than the retail electricity price. Different jurisdictions
may apply these terms in different ways, however.
Net zero emissions. Can refer to all greenhouse gas emissions
or only carbon emissions, and involves emissions declining to
zero. Carbon neutral refers to the balancing of carbon emissions
caused by an entity with funding an equivalent amount of carbon
savings elsewhere. Although carbon neutrality is sometimes
considered to be a synonym for net zero carbon emissions,
carbon neutrality can be achieved at the domestic level by
using offsets from other jurisdictions, whereas net zero does not
necessarily include this feature.
Net zero carbon building / Net zero energy building / Nearly
zero energy building. Various definitions have emerged of
buildings that achieve high levels of energy efficiency and meet
remaining energy demand with either on-site or off-site renewable
energy. For example, the World Green Building Council’s Net Zero
Carbon Buildings Commitment considers use of renewable energy
as one of five key components that characterise a net zero building.
Definitions of net zero carbon, net zero energy and nearly zero
energy buildings can vary in scope and geographic relevance.
Ocean power. Refers to technologies used to generate
electricity by harnessing from the ocean the energy potential
of ocean waves, tidal range (rise and fall), tidal streams, ocean
(permanent) currents, temperature gradients (ocean thermal
energy conversion) and salinity gradients. The definition of ocean
power used in this report does not include offshore wind power
or marine biomass energy.
Off-take agreement. An agreement between a producer of
energy and a buyer of energy to purchase/sell portions of the
producer’s future production. An off-take agreement normally is
negotiated prior to the construction of a renewable energy project
or installation of renewable energy equipment in order to secure
a market for the future output (e.g., electricity, heat). Examples of
this type of agreement include power purchase agreements and
feed-in tariffs.
Off-taker. The purchaser of the energy from a renewable energy
project or installation (e.g., a utility company) following an off-take
agreement. (See Off-take agreement.)
Pay-As-You-Go (PAYGo). A business model that gives customers
(mainly in areas without access to the electricity grid) the possibility
to purchase small-scale energy-producing products, such as
solar home systems, by paying in small instalments over time.
Peaker generation plant. Power plants that run predominantly
during peak demand periods for electricity. Such plants exhibit
the optimum balance – for peaking duty – of relatively high
variable cost (fuel and maintenance cost per unit of generation)
relative to fixed cost per unit of energy produced (low capital cost
per unit of generating capacity).
Pico solar devices / pico solar systems. Small solar systems
such as solar lanterns that are designed to provide only a limited
amount of electricity service, usually lighting and in some cases
mobile phone charging. Such systems are deployed mainly in areas
that have no or poor access to electricity. The systems usually have
a power output of 1-10 watts and a voltage of up to 12 volts.
Plug-in hybrid electric vehicle. This differs from a simple
hybrid vehicle, as the latter uses electric energy produced only
by braking or through the vehicle’s internal combustion engine.
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Therefore, only a plug-in hybrid electric vehicle allows for the
use of electricity from renewable sources. Although not an
avenue for increased penetration of renewable electricity, hybrid
vehicles contribute to reduced fuel demand and remain far more
numerous than EVs.
Power. The rate at which energy is converted into work,
expressed in watts (joules/second).
Power purchase agreement (PPA). A contract between two
parties, one that generates electricity (the seller) and one that is
looking to purchase electricity (the buyer).
Power-to-gas (P2G). The conversion of electricity, either
from renewable or conventional sources, to a gaseous fuel (for
example, hydrogen or methane).
Primary energy. The theoretically available energy content of
a naturally occurring energy source (such as coal, oil, natural
gas, uranium ore, geothermal and biomass energy, etc.) before
it undergoes conversion to useful final energy delivered to the
end-user. Conversion of primary energy into other forms of useful
final energy (such as electricity and fuels) entails losses. Some
primary energy is consumed at the end-user level as final energy
without any prior conversion.
Primary energy consumption. The direct use of energy at the
source, or supplying users with unprocessed fuel.
Product and sectoral standards. Rules specifying the
minimum standards for certain products (e.g., appliances) or
sectors (industry, transport, etc.) for increasing energy efficiency.
Production tax credit. A tax incentive that provides the investor
or owner of a qualifying property or facility with a tax credit based
on the amount of renewable energy (electricity, heat or biofuel)
generated by that facility.
Productive use of energy. Often used in the context of distributed
renewables for energy access to refer to activities that use energy
to generate income, increase productivity, enhance diversity and
create economic value. Productive uses of energy may include local
activities such as agriculture, livestock and fishing; light mechanical
works such as welding, carpentry and water pumping; small retail
and commercial activities such as tailoring, printing, catering and
entertainment; and small and medium-scale production such as
agro-processing (grinding, milling and husking), refrigeration and
cold storage, drying, preserving and smoking.
Property Assessed Clean Energy (PACE) financing. Provides
access to low-interest loans for renewable energy and energy
efficiency improvements that can be repaid through increases on
property taxes. It was originally conceived of in the United States
but has been expanding worldwide.
Prosumer. An individual, household or small business that not
only consumes energy but also produces it. Prosumers may play
an active role in energy storage and demand-side management.
Public financing. A type of financial support mechanism
whereby governments provide assistance, often in the form of
grants or loans, to support the development or deployment of
renewable energy technologies.
Pumped storage. Plants that pump water from a lower reservoir
to a higher storage basin using surplus electricity, and that
reverse the flow to generate electricity when needed. They are
not energy sources but means of energy storage and can have
overall system efficiencies of around 80-90%.
Regulatory policy. A rule to guide or control the conduct of those
to whom it applies. In the renewable energy context, examples
include mandates or quotas such as renewable portfolio standards,
feed-in tariffs and technology/fuel-specific obligations.
Renewable energy certificate (REC). A certificate awarded to
certify the generation of one unit of renewable energy (typically
1 MWh of electricity but also less commonly of heat). In systems
based on RECs, certificates can be accumulated to meet
renewable energy obligations and also provide a tool for trading
among consumers and/or producers. They also are a means of
enabling purchases of voluntary green energy.
Renewable hydrogen. Hydrogen produced from renewable
energy, most commonly through the use of renewable electricity
to split water into hydrogen and oxygen in an electrolyser. The
vast majority of hydrogen is still produced from fossil fuels, and
the majority of policies and programmes focused on hydrogen do
not include a focus on renewables-based production.
Renewable natural gas (RNG). Gas that is produced through
the anaerobic digestion of organic matter and processed to
remove the carbon dioxide and other gases, leaving methane that
meets a high specification and that can be interchangeable with
conventional natural gas. See Biomethane.
Renewable portfolio standard (RPS). An obligation placed
by a government on a utility company, group of companies
or consumers to provide or use a predetermined minimum
targeted renewable share of installed capacity, or of electricity
or heat generated or sold. A penalty may or may not exist for
non-compliance. These policies also are known as “renewable
electricity standards”, “renewable obligations” and “mandated
market shares”, depending on the jurisdiction.
Reverse auction. See Tendering.
Sector integration (also called sector coupling). The
integration of energy supply and demand across electricity,
thermal and transport applications, which may occur via
co-production, combined use, conversion and substitution.
Smart energy system. An energy system that aims to optimise
the overall efficiency and balance of a range of interconnected
energy technologies and processes, both electrical and non-
electrical (including heat, gas and fuels). This is achieved through
dynamic demand- and supply-side management; enhanced
monitoring of electrical, thermal and fuel-based system assets;
control and optimisation of consumer equipment, appliances
and services; better integration of distributed energy (on both
the macro and micro scales); and cost minimisation for both
suppliers and consumers.
Smart grid. Electrical grid that uses information and
communications technology to co-ordinate the needs and
capabilities of the generators, grid operators, end-users and
electricity market stakeholders in a system, with the aim of
operating all parts as efficiently as possible, minimising costs
and environmental impacts and maximising system reliability,
resilience and stability.
250
GL
Smart grid technology. Advanced information and control
technology that is required for improved systems integration and
resource optimisation on the grid.
Smart inverter. An inverter with robust software that is capable
of rapid, bidirectional communications, which utilities can control
remotely to help with issues such as voltage and frequency
fluctuations in order to stabilise the grid during disruptive events.
Solar collector. A device used for converting solar energy to
thermal energy (heat), typically used for domestic water heating but
also used for space heating, for industrial process heat or to drive
thermal cooling machines. Evacuated tube and flat plate collectors
that operate with water or a water/glycol mixture as the heat-transfer
medium are the most common solar thermal collectors used
worldwide. These are referred to as glazed water collectors because
irradiation from the sun first hits a glazing (for thermal insulation)
before the energy is converted to heat and transported away by the
heat transfer medium. Unglazed water collectors, often referred to
as swimming pool absorbers, are simple collectors made of plastics
and used for lower-temperature applications. Unglazed and glazed
air collectors use air rather than water as the heat-transfer medium
to heat indoor spaces or to pre-heat drying air or combustion air for
agriculture and industry purposes.
Solar cooker. A cooking device for household and institutional
applications that converts sunlight to heat energy that is retained
for cooking. There are several types of solar cookers, including
box cookers, panel cookers, parabolic cookers, evacuated tube
cookers and trough cookers.
Solar home system. A stand-alone system composed of
a relatively low-power photovoltaic module, a battery and
sometimes a charge controller that can provide modest amounts
of electricity for home lighting, communications and appliances,
usually in rural or remote regions that are not connected to the
electricity grid. The term solar home system kit is also used to
define systems that usually are branded and have components
that are easy for users to install and use.
Solar photovoltaics (PV). A technology used for converting
light directly into electricity. Solar PV cells are constructed from
semiconducting materials that use sunlight to separate electrons
from atoms to create an electric current. Modules are formed by
interconnecting individual cells. Building-integrated PV (BIPV)
generates electricity and replaces conventional materials in parts
of a building envelope, such as the roof or facade.
Solar photovoltaic-thermal (PV-T). A solar PV-thermal hybrid
system that includes solar thermal collectors mounted beneath
PV modules to convert solar radiation into electrical and thermal
energy. The solar thermal collector removes waste heat from the
PV module, enabling it to operate more efficiently.
Solar-plus-storage. A hybrid technology of solar PV with
battery storage. Other types of renewable energy-plus-storage
plants also exist.
Solar water heater. An entire system consisting of a solar
collector, storage tank, water pipes and other components. There
are two types of solar water heaters: pumped solar water heaters
use mechanical pumps to circulate a heat transfer fluid through
the collector loop (active systems), whereas thermosyphon solar
water heaters make use of buoyancy forces caused by natural
convection (passive systems).
Storage battery. A type of battery that can be given a new charge
by passing an electric current through it. A lithium-ion battery
uses a liquid lithium-based material for one of its electrodes. A
lead-acid battery uses plates made of pure lead or lead oxide
for the electrodes and sulphuric acid for the electrolyte, and
remains common for off-grid installations. A flow battery uses
two chemical components dissolved in liquids contained within
the system and most commonly separated by a membrane.
Flow batteries can be recharged almost instantly by replacing
the electrolyte liquid, while simultaneously recovering the spent
material for re-energisation.
Sustainable aviation fuel. According to the International Civil
Aviation Organization, such fuels are produced from three families
of bio-feedstock: the family of oils and fats (or triglycerides), the
family of sugars and the family of lignocellulosic feedstock.
Target. An official commitment, plan or goal set by a government
(at the local, state, national or regional level) to achieve a certain
amount of renewable energy or energy efficiency by a future date.
Targets may be backed by specific compliance mechanisms or
policy support measures. Some targets are legislated, while
others are set by regulatory agencies, ministries or public officials.
Tender (also called auction / reverse auction or tender). A
procurement mechanism by which renewable energy supply or
capacity is competitively solicited from sellers, who offer bids at
the lowest price that they would be willing to accept. Bids may be
evaluated on both price and non-price factors.
Thermal energy storage. Technology that allows the transfer
and storage of thermal energy. (See Molten salt.)
Torrefied wood. Solid fuel, often in the form of pellets, produced
by heating wood to 200-300°C in restricted air conditions. It has
useful characteristics for a solid fuel including relatively high energy
density, good grindability into pulverised fuel and water repellency.
Transmission grid. The portion of the electrical supply
distribution network that carries bulk electricity from power
plants to sub-stations, where voltage is stepped down for further
distribution. High-voltage transmission lines can carry electricity
between regional grids in order to balance supply and demand.
Variable renewable energy (VRE). A renewable energy source
that fluctuates within a relatively short time frame, such as wind
and solar energy, which vary within daily, hourly and even sub-
hourly time frames. By contrast, resources and technologies that
are variable on an annual or seasonal basis due to environmental
changes, such as hydropower (due to changes in rainfall) and
thermal power plants (due to changes in temperature of ambient
air and cooling water), do not fall into this category.
Vehicle fuel standard. A rule specifying the minimum fuel
economy of automobiles.
Vehicle-to-grid (V2G). A system in which electric vehicles –
whether battery electric or plug-in hybrid – communicate with
the grid in order to sell response services by returning electricity
from the vehicles to the electric grid or by altering the rate
of charging.
251
RENEWABLES 2021 GLOBAL STATUS REPORT
Virtual net metering. Virtual (or group) net metering allows
electricity utility consumers to share the output of a renewable
power project. By receiving “energy credits” based on project
output and their ownership share of the project, consumers are
able to offset costs on their electricity utility bill.
Virtual power plant (VPP). A network of decentralised,
independently owned and operated power generating units
combined with flexible demand units and possibly also with
storage facilities. A central control station monitors operation,
forecasts demand and supply, and dispatches the networked
units as if they were a single power plant. The aim is to smoothly
integrate a high number of renewable energy units into existing
energy systems; VPPs also enable the trading or selling of power
into wholesale markets.
Virtual power purchase agreement (PPA). A contract under
which the developer sells its electricity in the spot market. The
developer and the corporate off-taker then settle the difference
between the variable market price and the strike price, and the
off-taker receives the electricity certificates that are generated.
This is in contrast to more traditional PPAs, under which the
developer sells electricity to the off-taker directly.
Voltage and frequency control. The process of maintaining
grid voltage and frequency stable within a narrow band through
management of system resources.
Watt. A unit of power that measures the rate of energy conversion
or transfer. A kilowatt is equal to 1 thousand watts; a megawatt to
1 million watts; and so on. A megawatt-electrical (MWe) is used
to refer to electric power, whereas a megawatt-thermal (MWth)
refers to thermal/heat energy produced. Power is the rate at
which energy is consumed or generated. A kilowatt-hour is the
amount of energy equivalent to steady power of 1 kW operating
for one hour.
252
GL
LIST OF ABBREVIATIONS
AC Alternating current
AfDB African Development Bank
AUD Australian dollar
BEV Battery electric vehicle
BloombergNEF Bloomberg New Energy Finance
CCA Community choice aggregation
CHP Combined heat and power
CNY Chinese yuan
CO2 Carbon dioxide
COP Conference of the Parties
CSP Concentrating solar thermal power
DC Direct current
DFI Development finance institution
DHC District heating and cooling
DOE US Department of Energy
DRE Distributed renewable energy
DREA Distributed renewables for energy access
EC European Commission
ECOWAS Economic Community of West African States
EGS Enhanced (or engineered) geothermal systems
EIA Environmental impact assessment
EJ Exajoule
ESCO Energy service company
EU European Union (specifically the EU-27)
EUR Euro
EV Electric vehicle
FAME Fatty acid methyl esters
FCEV Fuel cell electric vehicle
FIT Feed-in tariff
FS Frankfurt School
G20 Group of Twenty
GDP Gross domestic product
GO Guarantee of origin
GOGLA Global association for the off-grid solar energy
industry
GNI Gross national income
GSR Global Status Report
GW/GWh Gigawatt/gigawatt-hour
GWth Gigawatt-thermal
GWEC Global Wind Energy Council
HEFA Hydrotreated esters and fatty acids
HJT Heterojunction cell technology
HVAC Heating, ventilation, and air-conditioning
HVO Hydrotreated vegetable oil
ICAO International Civil Aviation Organization
ICE Internal combustion engine
IDCOL Infrastructure Development Company Limited
IEC International Electrotechnical Commission
IEA International Energy Agency
IEA PVPS IEA Photovoltaic Power Systems Programme
IEA SHC IEA Solar Heating and Cooling Programme
IFC International Finance Corporation
IHA International Hydropower Association
IPP Independent power producer
ISCC Integrated solar combined-cycle
IRENA International Renewable Energy Agency
ITC Investment Tax Credit
ktoe Kilotonne of oil equivalent
kW/kWh Kilowatt/kilowatt-hour
kWth kilowatt-thermal
LBG Liquefied biogas
LCOE Levelised cost of energy (or electricity)
LPG Liquefied petroleum gas
LNG Liquefied natural gas
M&A Mergers and acquisitions
m2 Square metre
m3 Cubic metre
MENA Middle East and North Africa
MJ Megajoule
MSW Municipal solid waste
Mtoe Megatonne of oil equivalent
MW/MWh Megawatt/megawatt-hour
MWth Megawatt-thermal
NDC Nationally Determined Contribution
O&M Operations and maintenance
OECD Organisation for Economic Co-operation
and Development
OTEC Ocean thermal energy conversion
P2G Power-to-gas
PACE Property Assessed Clean Energy
PAYGo Pay-as-you-go
PERC Passivated Emitter Rear Cell
PHEV Plug-in hybrid electric vehicle
PJ Petajoule
PPA Power purchase agreement
PPP Purchasing power parity
PTC Production Tax Credit
PV Photovoltaic
R&D Research and development
REC Renewable electricity certificate
RED EU Renewable Energy Directive
RFS US Renewable Fuel Standard
RNG Renewable natural gas
RPS Renewable portfolio standard
SDG Sustainable Development Goal
SEforALL Sustainable Energy for All
SEK Swedish krona
SHC Solar heating and cooling
SHIP Solar heat for industrial processes
SUV Sport utility vehicle
TES Thermal energy storage
TFC Total final consumption
TFEC Total final energy consumption
Toe Tonne of oil equivalent
TW/TWh Terawatt/terawatt-hour
UAE United Arab Emirates
UN United Nations
UNDP United Nations Development Programme
UNEP United Nations Environment Programme
UNFCCC United Nations Framework Convention
on Climate Change
dUSD United States dollar
V2G Vehicle-to-grid
VAT Value-added tax
VNM Virtual net metering
VRE Variable renewable electricity
W/Wh Watt/watt-hour
Yieldco Yield company
ZEV Zero emission vehicle
USD United States dollar
V2G Vehicle-to-grid
VAT Value-added tax
VC/PE Venture capital and private equity
VNM Virtual net metering
VRE Variable renewable electricity
W/Wh Watt/watt-hour
WTO World Trade Organization
ZEV Zero emission vehicle
253
RENEWABLES 2021 GLOBAL STATUS REPORT
PHOTO CREDITS
page 04: © yangna; iStock
page 14: © Aliaksei Charapanau; shutterstock
page 16: © ictor; iStock
page 16: Biofuel boiler house, storage of wood chips;
© imantsu; iStock
page 17: Austin, Texas, USA; © RoschetzkyIstockPhoto; iStock
page 18: Rooftop Air System, Hong Kong; © 4FR; iStock
page 18: © kontrast-fotodesign; iStock
page 19: Train station, Hamburg, Germany; © mf-guddyx; iStock
page 20: © Hirurg; iStock
page 21: Hydro Electric Dam in Turkey; © ugurhan; iStock
page 21: Tidal power turbine test platform; © shaunl; iStock
page 22: © c1a1p1c1o1m1; iStock
page 23: Solar process heat for brewery in Germany;
© Brauerei Rothaus
page 23: © jonathanfilskov-photography; iStock
page 24: Solar panel in a Tuareg village southern Algeria;
© SeppFriedhuber; iStock
page 25: Alberta, Canada; © laughingmango; iStock
page 25: © SimonSkafar; iStock
page 26: Construction parts for offshore wind farms, port of
Rostock, Germany; © dannymark; iStock
page 27: © Sky_Blue; iStock
page 28: Singapore; © Hendry Poh; iStock
page 30: © danishkhan; iStock
page 31: © Petmal; iStock
page 34: © piola666; iStock
page 34: © MarkHatfield; iStock
page 35: Grande Dixence Dam in Swiss Alps, the tallest
gravity dam in the world; © Cerise HUA; iStock
page 38: Texas, USA; © Aneese; iStock
page 42: © Tamara Dragovic; iStock
page 45: © jhorrocks; iStock
page 45: © MEDITERRANEAN; iStock
page 46: © imantsu; iStock
page 49: © onurdongel; iStock
page 49: © 3alexd; iStock
page 51: Valencia, Spain; © supermimicry; iStock
page 51: London, United Kingdom; © miroslav_1; iStock
page 55: © Berk Toluk; iStock
page 55: © moisseyev; iStock
page 57: © andreswd; iStock
page 57: Honolulu, Hawaii; © Eric Broder Van Dyke; iStock
page 58: Munich, Germany; © bortnikau; iStock
page 59: © tunart; iStock
page 60: Electric-powered vehicle named Kavalir (Cavaliers);
Ljubljana, Slovenia; © kendoNice; iStock
page 62: © PhotoByToR; shutterstock
page 63: © Saurabhkumar Singh; iStock
page 64: © amriphoto; iStock
page 67: New Delhi, India; © PradeepGaurs; shutterstock
page 68: Aguascalientes, Mexico; © Mikel Dabbah; shutterstock
page 69: © struvictory; iStock
page 71: © Gengwit Wattakawigran; shutterstock
page 72: © Petmal; iStock
page 75: Normandie, France; © Photoagriculture; shutterstock
page 77: © JARAMA; iStock
page 77: Port Victoria, Seychelles island; © Reiner; iStock
page 78: Salto, Uruguay; © reisegraf.ch; shutterstock
page 81: © AleksandarGeorgiev; iStock
page 81: © Evgeniy Alyoshin; iStock
page 81: © LeoPatrizi; iStock
page 82: California, USA; © adamkaz; iStock
page 83: © Deyana Stefanova Robova; shutterstock
page 83: © Petmal; iStock
page 88: Transfer vessel Normand Jarstein standing by
Orsted wind turbine farm Borkum Riffgrund;
© CharlieChesvick; iStock
page 92: Biogas plant; © ollo; iStock
page 92: District heating and power plant using bio fuel to
produce heat and electricity; © Imfoto; shutterstock
page 94: Sugar cane harvest plantation; © mailsonpignata;
shutterstock
page 96: © A-Nurak; shutterstock
page 96: © Photoagriculture; shutterstock
page 98: Landfill employee measures methane gas produced
on site, Salvador, Bahia, Brazil; © Joa Souza;
shutterstock
page 99: Biomethane plant; © Ralf Geithe; shutterstock
page 101: Geothermal plant, Iceland; © Rhoberazzi; iStock
page 102: © MiguelMalo; iStock
page 105: Geothermal power station, Turkey; © temizyurek; iStock
page 105: © Rhoberazzi; iStock
page 106: © leezsnow; iStock
page 107: Hydro electric dam; © HenrikNorway; iStock
page 108: © CHUNYIP WONG; iStock
page 109: Bhulbhule, Nepal; © olli0815; iStock
page 110: Clyde, New Zealand; © DoraDalton; iStock
page 111: © Chris James; iStock
page 112: Xiluodu Dam and Hydropower Plant on Yangtze
River, China; © burakyalcin; shutterstock
page 113: Tidal turbines; © Glen Wright/Simec Atlantis Energy
page 113: Tidal turbines; © Glen Wright/Simec Atlantis Energy
page 114: © Glen Wright
page 116: Tidal turbines; © Glen Wright/Simec Atlantis Energy
page 117: © Appfind; iStock
page 121: © Nicholas Smith; iStock
page 122: © Jenson; iStock
page 123: © ollo; iStock
page 125: Australia; © SolStock; iStock
page 126: © janssenkruseproductions; iStock
page 127: © Karl-Friedrich Hohl; iStock
page 128: © alvarez; iStock
page 129: © Orietta Gaspari; iStock
page 130: © adamkaz; iStock
page 130: © Bilanol; iStock
page 131: Chile; © abriendomundo; iStock
page 132: Recovered aluminum from PV module recycling;
©PV CYCLE
page 132: Frameless PV modules; ©PV CYCLE
page 133: © c1a1p1c1o1m1; iStock
page 134: Madinat Zayed, Abu Dhabi, United Arab Emirates;
© Michael Xiaos; shutterstock
page 135: © prognone; iStock
page 136: Seville, Spain; © amoklv; iStock
page 137: Solar process heat for brewery in Germany;
© Brauerei Rothaus
254
PHOTO CREDITS
page 140: Parabolic trough collector field in Izmir, Turkey,
provides heat for packaging business; © Soliterm
page 141: Tracked flat plate collectors provide heat to paper
mill in France; © NewHeat
page 143: © Solar Heat Europe
page 144: © Greenonetec
page 145: © Absolicon Solar Collectors
page 148: © CreativeNature_nl; iStock
page 149: © NanoStockk; iStock
page 150: © mikulas1; iStock
page 151: © CharlieChesvick; iStock
page 152: © jimiknightley; iStock
page 155: Palmer, Colorado, USA; © milehightraveler; iStock
page 156: © TimSiegert-batcam; iStock
page 157: © NiseriN; iStock
page 158: © CharlieChesvick; iStock
page 159: Almere, the Netherlands; © ErikdeGraaf; iStock
page 159: © dja65; iStock
page 160: © kruwt; iStock
page 160: © SavoSolar
page 162: © Oorja Development Solutions India Private Limited
page 164: © SolStock; iStock
page 166: © nattrass; iStock
page 167: Varanasi, Uttar Pradesh, India; © balajisrinivasan;
shutterstock
page 168: Biogas unit digester under construction;
© wakahembe; shutterstock
page 169: Sine-Saloum, Senegal; © Salvador Aznar; shutterstock
page 172: Bengaluru, Karnataka, India; © Kaarthikeyan.SM;
shutterstock
page 172: © Oorja Development Solutions India Private Limited
page 173: © krithnarong; iStock
page 174: © Sistema.bio
page 176: Kigali, Rwanda; © Sarine Arslanian; shutterstock
page 177: Madagascar; © MyImages_Micha; iStock
page 178: © GCShutter; iStock
page 179: © Sistema.bio
page 179: © jonathanfilskov-photography; iStock
page 182: © Capuski; iStock
page 184: © masy100; shutterstock
page 185: lijiaxia reservoir in Kanbula national forest park,
China; © 1970s; iStock
page 186: © kynny; iStock
page 188: © Vadzim Kushniarou; iStock
page 190: © greenaperture; iStock
page 191: Jaisalmer, India; © Donyanedomam; iStock
page 192: Jambyl Province, Kazakhstan; © Vladimir Tretyakov;
shutterstock
page 194: Lower Saxony, Germany; © Ingo Bartussek;
shutterstock
page 195: Geothermic power station; © Rhoberazzi; iStock
page 196: © Apple Inc.
page 198: © coldsnowstorm; iStock
page 200: © yangna; iStock
page 203: © imantsu; iStock
page 204: © wilpunt; iStock
page 205: © Vladdeep; iStock
page 205: © Studio Harmony; shutterstock
page 205: © Virrage Images; shutterstock
page 206: © Uroš Medved; shutterstock
page 207: Heat pump at a residential home; © Palatinate Stock;
shutterstock
page 209: Manchester, UK; © Madrugada Verde; shutterstock
page 210: Copenhagen, Denmark; © oleschwander; shutterstock
page 212: © HenrikNorway; iStock
page 212: Natural gas-fired power station; © ricochet64; iStock
page 213: © audioundwerbung; iStock
page 214: © EXTREME-PHOTOGRAPHER; iStock
page 214: © loonger; iStock
page 215: © Petmal; iStock
page 216: Los Angeles, USA; © Fabian Gysel; iStock
page 218: © JulieanneBirch; iStock
page 218: © wmaster890; iStock
page 219: © winhorse; iStock
page 222: Yeosu City, South Korea; © Panwasin seemala;
shutterstock
page 224: © baona; iStock
page 226: © B4LLS; iStock
page 227: © SimonSkafar; iStock
page 228: © LindaPerez; shutterstock
page 229: Hannover, Germany; © Tramino; iStock
page 230: © kiruk; iStock
page 233: Amazon Headquarters; Seattle, Washington, USA;
© SEASTOCK; iStock
page 233: © double_p; iStock
page 233: © CharlieChesvick; iStock
page 234: Thermal power plant; © annavaczi; iStock
page 235: © hadynyah; iStock
page 236: © Spiderplay; iStock
page 236: © Scharfsinn86; iStock
page 237: © ollo; iStock
page 238: © Kisa_Markiza; iStock
page 239: © aapsky; iStock
page 252: © yangphoto; iStock
COPYRIGHT & IMPRINT
Renewable Energy Policy Network REN21 Secretariat
for the 21st Century c/o UN Environment Programme
1 rue Miollis, Building VII
75015 Paris
France
ENDNOTES · GLOBAL OVERVIEW 01
EN
DN
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ES
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OB
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RV
IE
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GLOBAL OVERVIEW
1 International Energy Agency (IEA), Global Energy Review 2021 (Paris:
2021), https://www.iea.org/reports/global-energy-review-2021.
2 Ember, Global Electricity Review 2021 (London: 2021), https://
ember-climate.org/project/global-electricity-review-2021. For
further discussion, see Power section in this chapter, and Market
and Industry chapter.
3 IEA, “Electricity”, in Global Energy Review 2020 (Paris: April 2020),
https://www.iea.org/reports/global-energy-review-2020/electricity.
4 See Power section in this chapter and related endnotes.
5 IEA, Renewables 2020 (Paris: 2020), https://www.iea.org/reports/
renewables-2020; Organisation for Economic Co-operation and
Development (OECD), “The impact of coronavirus (COVID-19) and
the global oil price shock on the fiscal position of oil-exporting
developing countries”, 30 September 2020, https://www.oecd.org/
coronavirus/policy-responses/the-impact-of-coronavirus-covid-
19-and-the-global-oil-price-shock-on-the-fiscal-position-of-oil-
exporting-developing-countries-8bafbd95.
6 International Renewable Energy Agency (IRENA), Renewable
Power Generation Costs in 2020 (Abu Dhabi: 2021); Lazard, Lazard’s
Levelized Cost of Energy Analysis – Version 14.0 (New York: 2020),
https://www.lazard.com/media/451419/lazards-levelized-cost-of-
energy-version-140 ; J. Hodges, “Wind, solar are cheapest power
source in most places, BNEF says”, BloombergNEF, 19 October
2020, https://www.bloomberg.com/news/articles/2020-10-19/wind-
solar-are-cheapest-power-source-in-most-places-bnef-says; Global
Wind Energy Council (GWEC), Global Wind Report 2021 (London:
2021), https://gwec.net/wp-content/uploads/2021/03/GWEC-
Global-Wind-Report-2021 , p. 12; SolarPower Europe, Global
Market Outlook for Solar Power 2020-2024 (Brussels: 2020), https://
www.solarpowereurope.org/global-market-outlook-2020-2024.
7 Ibid, all sources.
8 Ibid, all sources.
9 See Transport section in this chapter.
10 Ibid.
11 Ibid.
12 IEA, “Renewable heat”, in Renewables 2020 (Paris: 2020), https://
www.iea.org/reports/renewables-2020/renewable-heat.
13 See Buildings, Industry and Transport sections in this chapter, and
Policy chapter.
14 M. Rowling, “Powerless in a pandemic: Solar energy prescribed for
off-grid healthcare”, Reuters, 3 July 2020, https://www.reuters.com/
article/us-health-coronavirus-energy-solar-featu-idUSKBN24414T.
See also Distributed Renewables chapter.
15 EnDev, “COVID-19 Energy Access Industry Barometer –
presentation of results in a webinar hosted by EnDev”, 7 August
2020, https://endev.info/covid-19-energy-access-industry-
barometer-presentation-of-results-in-a-webinar-hosted-by-endev.
16 Data are for affiliates of the Global Off-Grid Lighting Association
(GOGLA). GOGLA, Global Off-Grid Solar Market Report Semi-
Annual Sales and Impact Data, July-December 2020 (Amsterdam:
2020), https://www.gogla.org/sites/default/files/resource_docs/
global_off-grid_solar_market_report_h2_2020 .
17 IEA, “Access to electricity”, https://www.iea.org/reports/sdg7-
data-and-projections/access-to-electricity#abstract, viewed 6
December 2020.
18 IEA, “The Covid-19 crisis is reversing progress on energy access
in Africa”, 20 November 2020, https://www.iea.org/articles/the-
covid-19-crisis-is-reversing-progress-on-energy-access-in-africa.
19 See Distributed Renewables chapter.
20 S. Modi and R. Postaria, “How COVID-19 deepens the digital
education divide in India”, World Economic Forum, 5 October 2020,
https://www.weforum.org/agenda/2020/10/how-covid-19-deepens-
the-digital-education-divide-in-india; B. Rochelle Parry and E. Gordon,
“The shadow pandemic: Inequitable gendered impacts of COVID-19
in South Africa”, Gender, Work & Organization, vol. 28 (March 2021),
https://onlinelibrary.wiley.com/doi/full/10.1111/gwao.12565.
21 IEA, World Energy Investment 2020 (Paris: 2020), https://
www.iea.org/reports/world-energy-investment-2020/
power-sector#overview-of-power-investment.
22 Ibid.; BloombergNEF, Energy Transition Investment Trends.
Tracking Global Investment in the Low-carbon Energy Transition
(London: 2021), p. 1, https://assets.bbhub.io/professional/sites/24/
EnergyTransition-Investment-Trends_Free-Summary_Jan2021 ;
total investment from idem, slide 2.
23 IEA, “Global investment in the power sector by technology, 2017-2020”,
https://www.iea.org/data-and-statistics/charts/global-investment-in-
the-power-sector-by-technology-2017-2020 (viewed 15 May 2021).
24 IEA, op. cit. note 21.
25 “Denmark set to end all new oil and gas exploration”, BBC News,
4 December 2020, https://www.bbc.com/news/business-55184580;
I. Slav, “Denmark to end oil production in 2050”, Oilprice.com,
4 December 2020, https://oilprice.com/Latest-Energy-News/World-
News/Denmark-To-End-Oil-Production-In-2050.html.
26 C. Nugent, “U.K. says it will end support for overseas oil, gas and
coal projects with ‘very limited exceptions’”, Time, 11 December
2020, https://time.com/5920475/u-k-fossil-fuels-overseas;
Government of the UK, “PM announces the UK will end support for
fossil fuel sector overseas”, press release (London: 12 December
2020), https://www.gov.uk/government/news/pm-announces-the-
uk-will-end-support-for-fossil-fuel-sector-overseas; T. Helm and R.
McKie, “UK urged to follow Denmark in ending North Sea oil and
gas exploration”, The Guardian (UK), 6 December 2020, https://
www.theguardian.com/environment/2020/dec/06/uk-urged-to-
follow-denmark-in-ending-north-sea-oil-and-gas-exploration;
World Oil, “UK projects up to 20 billion barrels of oil remain to be
found offshore”, 14 September 2020, https://www.worldoil.com/
news/2020/9/14/uk-projects-up-to-20-billion-barrels-of-oil-
remain-to-be-found-offshore.
27 Nikkei Asia, “Japan looks to end support for overseas
coal power projects”, 29 March 2021, https://asia.
nikkei.com/Spotlight/Environment/Climate-Change/
Japan-looks-to-end-support-for-overseas-coal-power-projects.
28 Energy Policy Tracker, “Multilateral Development Banks Analysis”,
viewed 21 March 2021.
29 See, for example: S. Kiderlin, “HSBC will end all funding for the
coal industry by 2040, narrowly avoiding revolt among climate
conscious-investors”, Business Insider France, 11 March 2021,
https://www.businessinsider.fr/us/hsbc-stop-funding-coal-
industry-following-investor-pressure-2021-3; T. Sims and S. Jessop,
“Deutsche Bank tightens fossil fuel lending policies”, Reuters, 27
July 2020,https://www.reuters.com/article/us-deutsche-bank-
coal-idUSKCN24S17G; A. Ellfeldt, “America’s biggest banks
promise to fight climate change”, Scientific American, 9 March 2021,
https://www.scientificamerican.com/article/americas-biggest-
banks-promise-to-fight-climate-change; A. Frangoul, “Swedish
pension fund with billions of assets under management to stop
fossil fuel investments”, CNBC, 17 March 2020, https://www.
cnbc.com/2020/03/17/swedish-pension-fund-to-stop-fossil-fuel-
investments.html; G. Readfearn, “Insurance giant Suncorp to end
coverage and finance for oil and gas industry”, The Guardian (UK),
21 August 2020, https://www.theguardian.com/environment/2020/
aug/21/insurance-giant-suncorp-to-end-coverage-and-finance-
for-oil-and-gas-industry. For other examples going back to
mid-December 2019, see J. Axelrod, “The energy shift approaches
as fossil finance dries up”, Natural Resources Defense Council,
27 February 2020, https://www.nrdc.org/experts/josh-axelrod/
fossil-finance-drying-energy-shift-finally-coming.
30 BloombergNEF, “Corporate clean energy buying grew 18% in 2020,
despite mountain of adversity”, 26 February 2021, https://about.
bnef.com/blog/corporate-clean-energy-buying-grew-18-in-2020-
despite-mountain-of-adversity.
31 Ibid.
32 Current membership from RE100, “RE100 members”, https://www.
there100.org/re100-members, viewed 6 May 2020; 2019 members
from idem, viewed 20 May 2019; RE100, “235 RE100 companies
have made a commitment to go ‘100% renewable’. Read about the
actions they are taking and why”, http://there100.org/companies,
viewed 26 March 2021.
33 As with RE100, at least 126 corporations had joined EP100 (up from
123 in 2019), committing to improving their energy productivity to
lower emissions, while at least 108 had joined EV100 (up from 67
in early 2020), committing to transitioning their vehicle fleets to
EVs. RE100, op. cit. note 32; The Climate Group, “EP100 members”,
https://www.theclimategroup.org/ep100-members, viewed 21
May 2021; The Climate Group, “EV100 members”, https://www.
theclimategroup.org/ev100-members, viewed 21 May 2021; The
Climate Group, “SteelZero FAQs”, https://www.theclimategroup.
org/media/6841/download, viewed 21 May 2021.
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https://www.there100.org/re100-members
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http://there100.org/companies
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https://www.theclimategroup.org/ev100-members
https://www.theclimategroup.org/media/6841/download
https://www.theclimategroup.org/media/6841/download
ENDNOTES · GLOBAL OVERVIEW 01
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34 See Feature chapter and Policy Landscape chapter.
35 Race to Zero, https://racetozero.unfccc.int, viewed 24 May 2021;
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https://www.repsol.com/en/press-room/press-releases/2019/repsol-will-be-a-net-zero-emissions-company-by-2050.cshtml
https://www.repsol.com/en/press-room/press-releases/2019/repsol-will-be-a-net-zero-emissions-company-by-2050.cshtml
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https://reports.shell.com/sustainability-report/2019/introduction/our-approach-to-sustainability/executive-remuneration.html
https://www.bloomberg.com/news/articles/2021-03-18/total-ties-customers-emissions-reductions-to-executive-bonuses
https://www.bloomberg.com/news/articles/2021-03-18/total-ties-customers-emissions-reductions-to-executive-bonuses
https://www.bloomberg.com/news/articles/2021-03-18/total-ties-customers-emissions-reductions-to-executive-bonuses
https://www.total.com/sites/g/files/nytnzq111/files/documents/2020-10/total-climate-report-2020
https://www.total.com/sites/g/files/nytnzq111/files/documents/2020-10/total-climate-report-2020
https://www.chevron.com/-/media/chevron/sustainability/documents/climate-change-resilience-report
https://www.chevron.com/-/media/chevron/sustainability/documents/climate-change-resilience-report
https://corporate.exxonmobil.com/News/Newsroom/News-releases/2020/1214_ExxonMobil-announces-2025-emissions-reductions_expects-to-meet-2020-plan
https://corporate.exxonmobil.com/News/Newsroom/News-releases/2020/1214_ExxonMobil-announces-2025-emissions-reductions_expects-to-meet-2020-plan
https://corporate.exxonmobil.com/News/Newsroom/News-releases/2020/1214_ExxonMobil-announces-2025-emissions-reductions_expects-to-meet-2020-plan
https://corporate.exxonmobil.com/News/Newsroom/News-releases/2020/1214_ExxonMobil-announces-2025-emissions-reductions_expects-to-meet-2020-plan
https://www.ft.com/content/32f5e2cd-4689-4434-9da0-d97d46673eaf
https://www.ft.com/content/32f5e2cd-4689-4434-9da0-d97d46673eaf
https://www.economist.com/business/2021/02/06/shareholders-are-pushing-exxonmobil-to-go-green
https://www.economist.com/business/2021/02/06/shareholders-are-pushing-exxonmobil-to-go-green
https://www.reuters.com/business/energy/chevron-shareholders-approve-proposal-cut-customer-emissions-2021-05-26
https://www.reuters.com/business/energy/chevron-shareholders-approve-proposal-cut-customer-emissions-2021-05-26
https://www.reuters.com/business/energy/chevron-shareholders-approve-proposal-cut-customer-emissions-2021-05-26
https://www.reuters.com/business/sustainable-business/shareholder-activism-reaches-milestone-exxon-board-vote-nears-end-2021-05-26
https://www.reuters.com/business/sustainable-business/shareholder-activism-reaches-milestone-exxon-board-vote-nears-end-2021-05-26
https://www.reuters.com/business/sustainable-business/shareholder-activism-reaches-milestone-exxon-board-vote-nears-end-2021-05-26
https://energywatch.eu/EnergyNews/Renewables/article12695415.ece
https://energywatch.eu/EnergyNews/Renewables/article12695415.ece
ENDNOTES · GLOBAL OVERVIEW 01
EN
DN
OT
ES
I
GL
OB
AL
O
VE
RV
IE
W
https://www.pv-magazine.com/2018/01/18/uk-shell-signs-5-year-
ppa-with-bsr-for-69-8-mw-solar-project-comment; C. Martin and
K. Crowley, “Exxon will use wind, solar to produce crude oil in
Texas”, Industry Week, 30 November 2018, https://www.
industryweek.com/leadership/companies-executives/
article/22026765/exxon-will-use-wind-solar-to-produce-crude-oil-
in-texas; SunPower, “SunPower building new 35-megawatt DC
solar project to supply renewable energy to Chevron’s Lost Hills Oil
Field”, 29 October 2019, https://newsroom.sunpower.com/2019-10-
29-SunPower-Building-New-35-Megawatt-DC-Solar-Project-to-
Supply-Renewable-Energy-to-Chevrons-Lost-Hills-Oil-Field; T.
Tsanova, “Chevron to get wind power for Permian operations”,
Renewables Now, 23 August 2019, https://renewablesnow.com/
news/chevron-to-get-wind-power-for-permian-operations-666287;
Chevron, “Investing in low-carbon technologies to enable
commercial solutions”, https://www.chevron.com/sustainability/
environment/innovation, viewed 15 May 2021; “Chevron launches
$300 million fund for energy transition technology”, Hart Energy, 26
February 2021, https://www.hartenergy.com/exclusives/chevron-
launches-300-million-fund-energy-transition-technology-192622;
ExxonMobil, “ExxonMobil invests $1 billion per year in energy
research, emerging technologies”, 18 September 2018, https://
corporate.exxonmobil.com/Energy-and-innovation/University-and-
National-Labs-partnerships/ExxonMobil-invests-1-billion-per-year-
in-energy-research-emerging-technologies; M. DiLallo, “ExxonMobil
to create a new low-carbon business unit”, The Motley Fool, 2
February 2021, https://www.fool.com/investing/2021/02/02/
exxonmobil-to-create-a-new-low-carbon-business-uni; A. Raval, “Oil
majors switch on to a future in power generation”, Financial Times, 13
November 2018, https://www.ft.com/content/699584f4-e36e-11e8-
a6e5-792428919cee; Total, “Total et Sunpower créent un nouveau
leader mondial de l’industrie solaire”, 15 June 2011,https://www.total.
com/media/news/press-releases/total-et-sunpower-creent-un-
nouveau-leader-mondial-de-lindustrie-solaire; R. Bousso and S.
Twidale, “BP returns to solar with investment in Lightsource”,
Reuters, 15 December 2017, https://www.reuters.com/article/
us-lightsource-bp-stake-idUSKBN1E90H9; “BP to increase stake in
Lightsource BP to 50%”, NS Energy, 6 December 2019, https://www.
nsenergybusiness.com/news/bp-lightsource-bp; R. Bousso and S.
Twidale, “Shell goes green as it rebrands UK household power
supplier”, Reuters, 24 March 2019, https://www.reuters.com/article/
us-shell-power-idUSKCN1R50ON; J. Pyper, “Shell takes a major
stake in US solar developer Silicon Ranch”, Greentech Media, 15
January 2018, https://www.greentechmedia.com/articles/read/
shell-takes-major-stake-in-us-solar-developer; J. Deign, “Shell
Technology Ventures leads $20 million investment in minigrid
specialist Husk”, Greentech Media, 18 January 2018, https://www.
greentechmedia.com/articles/read/shell-ventures-leads-20-million-
investment-in-minigrid-specialist-husk. Accounting for currently
contracted renewable capacity, the share of oil and gas majors in
total renewable capacity is expected to reach 2.1% by 2025 from
0.3% in 2020. ”, IEA, “Installed and contracted renewable capacity by
major oil and gas companies, 2018-2025”, https://www.iea.org/
data-and-statistics/charts/installed-and-contracted-renewable-
capacity-by-major-oil-and-gas-companies-2018-2025, updated 9
November 2020; M. J. Coren, “This is the year oil companies finally
invest in geothermal”, Quartz, 19 January 2021, https://
qz.com/1958041/oil-companies-may-finally-invest-in-
geothermal-in-2021; L. Collins, “Oil giants BP and Chevron become
part-owners of ‘world-changing’ deep-geothermal innovator Eavor”,
Recharge News, 18 February 2021, https://www.rechargenews.com/
technology/oil-giants-bp-and-chevron-become-part-owners-of-
world-changing-deep-geothermal-innovator-eavor/2-1-963275; P.
Lee, “Unocal’s geothermal projects are gaining steam”, Los Angeles
Times, 23 October 1989, https://www.latimes.com/archives/
la-xpm-1989-10-23-fi-379-story.html; “Oil majors are driving wind
energy revolution”, RT, 14 February 2021, https://www.rt.com/
business/515529-oil-majors-wind-enrgy-revolution; S. Reed, “Oil
giants win offshore wind leases in Britain”, New York Times, 8
February 2021, https://www.nytimes.com/2021/02/08/business/
oil-companies-offshore-wind-britain.html; J. St. John, “New York’s
latest clean energy push includes 2.5GW of offshore wind contracts
for Equinor and BP”, Greentech Media, 13 January 2021, https://
www.greentechmedia.com/articles/read/new-yorks-new-green-
push-includes-2.5gw-of-offshore-wind-contracts-for-equinor-
and-bp; BP, “BP and Equinor form strategic partnership to develop
offshore wind energy in US”, 10 September 2020, https://www.
bp.com/en/global/corporate/news-and-insights/press-releases/
bp-and-equinor-form-strategic-partnership-to-develop-offshore-
wind-energy-in-us.html; IEA, The Oil and Gas Industry in Energy
Transitions (Paris: January 2020), https://www.iea.org/reports/
the-oil-and-gas-industry-in-energy-transitions; L. Carter, Z. Boren
and A. Kaufman, “Revealed: BP and Shell back anti-climate lobby
groups despite pledges”, Unearthed, 28 September 2020, https://
unearthed.greenpeace.org/2020/09/28/bp-shell-climate-lobby-
groups; “How some international treaties threaten the environment”,
The Economist, 5 October 2020, https://www.economist.com/
finance-and-economics/2020/10/05/how-some-international-
treaties-threaten-the-environment; K. Taylor, “Energy Charter Treaty
strikes again as Uniper sues Netherlands over coal phase-out”,
EURACTIV, 20 April 2021, https://www.euractiv.com/section/energy/
news/energy-charter-treaty-strikes-again-as-uniper-sues-
netherlands-over-coal-phase-out; K. Taylor, “Germany’s RWE uses
Energy Charter Treaty to challenge Dutch coal phase-out”,
EURACTIV, 5 February 2021, https://www.euractiv.com/section/
energy/news/germanys-rwe-uses-energy-charter-treaty-to-
challenge-dutch-coal-phase-out; F. Simon, “France puts EU
withdrawal from Energy Charter Treaty on the table”, EURACTIV, 3
February 2021, https://www.euractiv.com/section/energy/news/
france-puts-eu-withdrawal-from-energy-charter-treaty-on-the-
table; K. Taylor, “EU pushes for fossil fuel phase-out in ‘last chance’
energy charter treaty talks”, EURACTIV, 18 February 2021, https://
www.euractiv.com/section/energy/news/eu-pushes-for-fossil-fuel-
phase-out-in-last-chance-energy-charter-treaty-talks; ODI, “G20
governments have committed USD 151 billion to fossil fuels in
COVID-19 recovery packages”, 15 July 2020, https://www.odi.org/
news/17179-g20-governments-have-committed-usd-151-billion-
fossil-fuels-covid-19-recovery-packages. Note on Figure 5: For all
companies except Eni, the amount spent on renewables is difficult to
isolate. Oil and gas companies do not explicitly report on renewable
energy spending in their financial statements. Of the companies
represented in the figure, Eni was the only one that provided this
number, under “Business of increasing renewable installed capacity”
for 2020. Equinor’s spending was calculated based on its self-
reported 4% share of “Renewables and low carbon solutions” in its
gross capital expenditure. ExxonMobil and Chevron reported on
“Environmental capital expenditures” without clarifying what is
included in this spending category. BP’s renewables spending was
reported under “non-oil and gas expenditure”, which may conflate a
range of spending categories including electric mobility. Shell
reported on “Renewables and energy solutions”, which includes
power generation, trading and supply; hydrogen; and nature-based
solutions. Total reported on renewables under “Integrated gas,
renewables and power”, both of which include spending on fossil gas
for power generation. Figure 5 based on the following sources: Eni,
2020 Annual Report on Form 20F (Rome: 2021), pp. 2 and 120, https://
www.eni.com/assets/documents/eng/reports/2020/Annual-Report-
On-Form-20-F-2020 ; Equinor total capital expenditure from
Equinor, 2020 Annual Report on Form 20F (Stavanger: 2021), p. 88,
https://www.equinor.com/en/investors/our-dividend/annual-
reports-archive.html; spending on low-carbon solutions calculated
based on self-reported share of “Renewables and low carbon
solutions” in gross capital expenditure, from Equinor, “Equinor annual
and sustainability reports for 2020”, 19 March 2021, https://www.
equinor.com/en/news/20210319-annual-sustainability-reports-2020.
html; Chevron, 2020 Annual Report (San Ramon: 2021), pp. 40, 69,
https://www.chevron.com/-/media/chevron/annual-report/2020/
documents/2020-Annual-Report ; BP, 2020 Annual Report on
Form 20F (London: 2021), pp. 22, 46, https://www.bp.com/content/
dam/bp/business-sites/en/global/corporate/pdfs/investors/
bp-annual-report-and-form-20f-2020 , Royal Dutch Shell, 2020
Form 20-F (The Hague: 2021), pp. 26, 34, https://www.shell.com/
about-us/annual-publications/annual-reports-download-centre/_
jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_
d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b
760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020 ;
ExxonMobil, 2020 Annual Report (Irving: 2021), pp. 52, 54, https://
corporate.exxonmobil.com/-/media/Global/Files/investor-relations/
annual-meeting-materials/annual-report-summaries/2020-Annual-
Report ; Total, 2020 Form 20-F (Paris: 2021), pp. 1, 4, https://www.
total.com/system/files/documents/2021-03/2020-total-form-20-f .
38 H. L. Brumberg, “AAP policy: Ambient air pollution a preventable
risk factor in pediatric health concerns”, AAP News, 17 May 2021,
https://www.aappublications.org/news/2021/05/17/air-pollution-
child-health-policy-051721; COBENEFITS, “Why co-benefits?”,
https://www.cobenefits.info/our-work/project, viewed 27 May 2021.
Sidebar 2 from the following sources: IRENA, The Post-COVID
Recovery: An Agenda for Resilience, Development and Equality
(Abu Dhabi: 2020), www.irena.org/-/media/Files/IRENA/Agency/
Publication/2020/Jun/IRENA_Post-COVID_Recovery_2020 ;
258
UK: Shell signs 5 year private PPA with BSR for 69.8 MW solar project – comment
UK: Shell signs 5 year private PPA with BSR for 69.8 MW solar project – comment
https://www.industryweek.com/leadership/companies-executives/article/22026765/exxon-will-use-wind-solar-to-produce-crude-oil-in-texas
https://www.industryweek.com/leadership/companies-executives/article/22026765/exxon-will-use-wind-solar-to-produce-crude-oil-in-texas
https://www.industryweek.com/leadership/companies-executives/article/22026765/exxon-will-use-wind-solar-to-produce-crude-oil-in-texas
https://www.industryweek.com/leadership/companies-executives/article/22026765/exxon-will-use-wind-solar-to-produce-crude-oil-in-texas
https://newsroom.sunpower.com/2019-10-29-SunPower-Building-New-35-Megawatt-DC-Solar-Project-to-Supply-Renewable-Energy-to-Chevrons-Lost-Hills-Oil-Field
https://newsroom.sunpower.com/2019-10-29-SunPower-Building-New-35-Megawatt-DC-Solar-Project-to-Supply-Renewable-Energy-to-Chevrons-Lost-Hills-Oil-Field
https://newsroom.sunpower.com/2019-10-29-SunPower-Building-New-35-Megawatt-DC-Solar-Project-to-Supply-Renewable-Energy-to-Chevrons-Lost-Hills-Oil-Field
https://renewablesnow.com/news/chevron-to-get-wind-power-for-permian-operations-666287
https://renewablesnow.com/news/chevron-to-get-wind-power-for-permian-operations-666287
https://www.chevron.com/sustainability/environment/innovation
https://www.chevron.com/sustainability/environment/innovation
https://www.hartenergy.com/exclusives/chevron-launches-300-million-fund-energy-transition-technology-192622
https://www.hartenergy.com/exclusives/chevron-launches-300-million-fund-energy-transition-technology-192622
https://corporate.exxonmobil.com/Energy-and-innovation/University-and-National-Labs-partnerships/ExxonMobil-invests-1-billion-per-year-in-energy-research-emerging-technologies
https://corporate.exxonmobil.com/Energy-and-innovation/University-and-National-Labs-partnerships/ExxonMobil-invests-1-billion-per-year-in-energy-research-emerging-technologies
https://corporate.exxonmobil.com/Energy-and-innovation/University-and-National-Labs-partnerships/ExxonMobil-invests-1-billion-per-year-in-energy-research-emerging-technologies
https://corporate.exxonmobil.com/Energy-and-innovation/University-and-National-Labs-partnerships/ExxonMobil-invests-1-billion-per-year-in-energy-research-emerging-technologies
https://www.fool.com/investing/2021/02/02/exxonmobil-to-create-a-new-low-carbon-business-uni
https://www.fool.com/investing/2021/02/02/exxonmobil-to-create-a-new-low-carbon-business-uni
https://www.ft.com/content/699584f4-e36e-11e8-a6e5-792428919cee
https://www.ft.com/content/699584f4-e36e-11e8-a6e5-792428919cee
https://www.total.com/media/news/press-releases/total-et-sunpower-creent-un-nouveau-leader-mondial-de-lindustrie-solaire
https://www.total.com/media/news/press-releases/total-et-sunpower-creent-un-nouveau-leader-mondial-de-lindustrie-solaire
https://www.total.com/media/news/press-releases/total-et-sunpower-creent-un-nouveau-leader-mondial-de-lindustrie-solaire
https://www.reuters.com/article/us-lightsource-bp-stake-idUSKBN1E90H9
https://www.reuters.com/article/us-lightsource-bp-stake-idUSKBN1E90H9
https://www.nsenergybusiness.com/news/bp-lightsource-bp
https://www.nsenergybusiness.com/news/bp-lightsource-bp
https://www.reuters.com/article/us-shell-power-idUSKCN1R50ON
https://www.reuters.com/article/us-shell-power-idUSKCN1R50ON
https://www.greentechmedia.com/articles/read/shell-takes-major-stake-in-us-solar-developer
https://www.greentechmedia.com/articles/read/shell-takes-major-stake-in-us-solar-developer
https://www.greentechmedia.com/articles/read/shell-ventures-leads-20-million-investment-in-minigrid-specialist-husk
https://www.greentechmedia.com/articles/read/shell-ventures-leads-20-million-investment-in-minigrid-specialist-husk
https://www.greentechmedia.com/articles/read/shell-ventures-leads-20-million-investment-in-minigrid-specialist-husk
https://www.iea.org/data-and-statistics/charts/installed-and-contracted-renewable-capacity-by-major-oil-and-gas-companies-2018-2025
https://www.iea.org/data-and-statistics/charts/installed-and-contracted-renewable-capacity-by-major-oil-and-gas-companies-2018-2025
https://www.iea.org/data-and-statistics/charts/installed-and-contracted-renewable-capacity-by-major-oil-and-gas-companies-2018-2025
https://qz.com/1958041/oil-companies-may-finally-invest-in-geothermal-in-2021
https://qz.com/1958041/oil-companies-may-finally-invest-in-geothermal-in-2021
https://qz.com/1958041/oil-companies-may-finally-invest-in-geothermal-in-2021
https://www.rechargenews.com/technology/oil-giants-bp-and-chevron-become-part-owners-of-world-changing-deep-geothermal-innovator-eavor/2-1-963275
https://www.rechargenews.com/technology/oil-giants-bp-and-chevron-become-part-owners-of-world-changing-deep-geothermal-innovator-eavor/2-1-963275
https://www.rechargenews.com/technology/oil-giants-bp-and-chevron-become-part-owners-of-world-changing-deep-geothermal-innovator-eavor/2-1-963275
https://www.latimes.com/archives/la-xpm-1989-10-23-fi-379-story.html
https://www.latimes.com/archives/la-xpm-1989-10-23-fi-379-story.html
https://www.rt.com/business/515529-oil-majors-wind-enrgy-revolution
https://www.rt.com/business/515529-oil-majors-wind-enrgy-revolution
https://www.greentechmedia.com/articles/read/new-yorks-new-green-push-includes-2.5gw-of-offshore-wind-contracts-for-equinor-and-bp
https://www.greentechmedia.com/articles/read/new-yorks-new-green-push-includes-2.5gw-of-offshore-wind-contracts-for-equinor-and-bp
https://www.greentechmedia.com/articles/read/new-yorks-new-green-push-includes-2.5gw-of-offshore-wind-contracts-for-equinor-and-bp
https://www.greentechmedia.com/articles/read/new-yorks-new-green-push-includes-2.5gw-of-offshore-wind-contracts-for-equinor-and-bp
https://www.bp.com/en/global/corporate/news-and-insights/press-releases/bp-and-equinor-form-strategic-partnership-to-develop-offshore-wind-energy-in-us.html
https://www.bp.com/en/global/corporate/news-and-insights/press-releases/bp-and-equinor-form-strategic-partnership-to-develop-offshore-wind-energy-in-us.html
https://www.bp.com/en/global/corporate/news-and-insights/press-releases/bp-and-equinor-form-strategic-partnership-to-develop-offshore-wind-energy-in-us.html
https://www.bp.com/en/global/corporate/news-and-insights/press-releases/bp-and-equinor-form-strategic-partnership-to-develop-offshore-wind-energy-in-us.html
https://www.iea.org/reports/the-oil-and-gas-industry-in-energy-transitions
https://www.iea.org/reports/the-oil-and-gas-industry-in-energy-transitions
Revealed: BP and Shell back anti-climate lobby groups despite pledges
Revealed: BP and Shell back anti-climate lobby groups despite pledges
Revealed: BP and Shell back anti-climate lobby groups despite pledges
https://www.economist.com/finance-and-economics/2020/10/05/how-some-international-treaties-threaten-the-environment
https://www.economist.com/finance-and-economics/2020/10/05/how-some-international-treaties-threaten-the-environment
https://www.economist.com/finance-and-economics/2020/10/05/how-some-international-treaties-threaten-the-environment
Energy Charter Treaty strikes again as Uniper sues Netherlands over coal phase-out
Energy Charter Treaty strikes again as Uniper sues Netherlands over coal phase-out
Energy Charter Treaty strikes again as Uniper sues Netherlands over coal phase-out
Germany’s RWE uses Energy Charter Treaty to challenge Dutch coal phase-out
Germany’s RWE uses Energy Charter Treaty to challenge Dutch coal phase-out
Germany’s RWE uses Energy Charter Treaty to challenge Dutch coal phase-out
France puts EU withdrawal from Energy Charter Treaty on the table
France puts EU withdrawal from Energy Charter Treaty on the table
France puts EU withdrawal from Energy Charter Treaty on the table
EU pushes for fossil fuel phase-out in ‘last chance’ energy charter treaty talks
EU pushes for fossil fuel phase-out in ‘last chance’ energy charter treaty talks
EU pushes for fossil fuel phase-out in ‘last chance’ energy charter treaty talks
https://www.odi.org/news/17179-g20-governments-have-committed-usd-151-billion-fossil-fuels-covid-19-recovery-packages
https://www.odi.org/news/17179-g20-governments-have-committed-usd-151-billion-fossil-fuels-covid-19-recovery-packages
https://www.odi.org/news/17179-g20-governments-have-committed-usd-151-billion-fossil-fuels-covid-19-recovery-packages
https://www.eni.com/assets/documents/eng/reports/2020/Annual-Report-On-Form-20-F-2020
https://www.eni.com/assets/documents/eng/reports/2020/Annual-Report-On-Form-20-F-2020
https://www.eni.com/assets/documents/eng/reports/2020/Annual-Report-On-Form-20-F-2020
https://www.equinor.com/en/investors/our-dividend/annual-reports-archive.html
https://www.equinor.com/en/investors/our-dividend/annual-reports-archive.html
https://www.equinor.com/en/news/20210319-annual-sustainability-reports-2020.html
https://www.equinor.com/en/news/20210319-annual-sustainability-reports-2020.html
https://www.equinor.com/en/news/20210319-annual-sustainability-reports-2020.html
https://www.chevron.com/-/media/chevron/annual-report/2020/documents/2020-Annual-Report
https://www.chevron.com/-/media/chevron/annual-report/2020/documents/2020-Annual-Report
https://www.bp.com/content/dam/bp/business-sites/en/global/corporate/pdfs/investors/bp-annual-report-and-form-20f-2020
https://www.bp.com/content/dam/bp/business-sites/en/global/corporate/pdfs/investors/bp-annual-report-and-form-20f-2020
https://www.bp.com/content/dam/bp/business-sites/en/global/corporate/pdfs/investors/bp-annual-report-and-form-20f-2020
https://www.shell.com/about-us/annual-publications/annual-reports-download-centre/_jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020
https://www.shell.com/about-us/annual-publications/annual-reports-download-centre/_jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020
https://www.shell.com/about-us/annual-publications/annual-reports-download-centre/_jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020
https://www.shell.com/about-us/annual-publications/annual-reports-download-centre/_jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020
https://www.shell.com/about-us/annual-publications/annual-reports-download-centre/_jcr_content/par/tabbedcontent_f645/tab_7bf9_copy/textimage_d83f.stream/1615464115245/a1e527c87e9d548f6e5e0b760ec92c12464b8b94/royal-dutch-shell-form-20-f-2020
https://corporate.exxonmobil.com/-/media/Global/Files/investor-relations/annual-meeting-materials/annual-report-summaries/2020-Annual-Report
https://corporate.exxonmobil.com/-/media/Global/Files/investor-relations/annual-meeting-materials/annual-report-summaries/2020-Annual-Report
https://corporate.exxonmobil.com/-/media/Global/Files/investor-relations/annual-meeting-materials/annual-report-summaries/2020-Annual-Report
https://corporate.exxonmobil.com/-/media/Global/Files/investor-relations/annual-meeting-materials/annual-report-summaries/2020-Annual-Report
https://www.total.com/system/files/documents/2021-03/2020-total-form-20-f
https://www.total.com/system/files/documents/2021-03/2020-total-form-20-f
https://www.aappublications.org/news/2021/05/17/air-pollution-child-health-policy-051721
https://www.aappublications.org/news/2021/05/17/air-pollution-child-health-policy-051721
http://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Jun/IRENA_Post-COVID_Recovery_2020
http://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Jun/IRENA_Post-COVID_Recovery_2020
ENDNOTES · GLOBAL OVERVIEW 01
EN
DN
OT
ES
I
GL
OB
AL
O
VE
RV
IE
W
Solar Foundation, 11th Annual National Solar Jobs Census 2020
(Washington, DC: May 2021), https://www.thesolarfoundation.
org/wp-content/uploads/2021/05/National-Solar-Jobs-Census-
2020-FINAL ; 2019 off-grid solar jobs estimate from GOGLA
and Vivid Economics, Employment Opportunities in an Evolving
Market (Utrecht: 2018), www.gogla.org/resources/employment-
opportunities-in-an-evolving-market-off-grid-solar-creating-high-
value; 2020 off-grid solar jobs estimated using sales trend data
from GOGLA, op. cit. note 16; Ministry of Labour and Employment
of Brazil, “Annual list of social information: Database including
active and inactive employments for sugarcane cultivation and
alcohol manufacture”, in Relação Anual de Informações Sociais
(Annual Report of Social Information) (Brasilia: 2020); in-person
sales and solar industry job losses from E. F. Merchant, “The highs
and lows for solar in 2020”, Greentech Media, 30 December 2020,
https://www.greentechmedia.com/articles/read/the-highs-and-
lows-for-solar-in-2020, and from E. F. Merchant, “A new response
to coronavirus: Giving solar away for free”, Greentech Media, 23
April 2020, https://www.greentechmedia.com/articles/read/one-
response-to-the-coronavirus-giving-solar-away-for-free; off-grid
finances from Sustainable Energy for All (SEforALL), Energizing
Finance: Understanding the Landscape 2020 (Washington, DC:
2020), https://www.seforall.org/publications/energizing-finance-
understanding-the-landscape-2020; balsa shortages from E. Ng,
“China turbine makers winded after Ecuador lockdown leaves them
without blades”, South China Morning Post, 16 April 2020, https://
www.scmp.com/business/article/3080227/china-turbine-makers-
winded-after-ecuador-lockdown-leaves-them-without.
39 S. Dixon-Fyle et al., “Diversity wins: How inclusion matters”,
McKinsey & Company, 19 May 2020, https://www.mckinsey.
com/featured-insights/diversity-and-inclusion/diversity-
wins-how-inclusion-matters; Global Women’s Network
for the Energy Transition, “News resources”, https://www.
globalwomennet.org/news/resources, viewed 26 May 2021;
Energy Voice, “Renewables ‘early advantage’ in gender equality
could disappear, warns software firm”, 5 May 2021, https://
www.energyvoice.com/renewables-energy-transition/320188/
renewables-gender-diversity; J. Davenport, “Here’s how to fix
renewable energy’s diversity problem”, Forbes, 4 May 2021,
https://www.forbes.com/sites/julietdavenport/2021/05/04/
heres-how-to-fix-renewable-energys-diversity-problem.
40 For example, Enel and Clir Renewables joined in early 2021,
from Enel, “Enel joins Equal by 30 Campaign, confirming its
commitments on gender equality”, press release (Rome: 19
February 2021), https://www.enel.com/media/explore/search-
press-releases/press/2021/02/enel-joins-equal-by-30-campaign-
confirming-its-commitments-on-gender-equality-, and from CLIR,
“Commitments are key for gender equality in the renewables
industry”, pv magazine, 4 May 2021, https://www.pv-magazine.
com/press-releases/commitments-are-key-for-gender-equality-
in-the-renewables-industry. See also: Clean Energy Ministerial,
“Equal by 30”, http://www.cleanenergyministerial.org/campaign-
clean-energy-ministerial/equal-30, viewed 27 May 2021; Equal by
30, “About the campaign”, https://www.equalby30.org/en/content/
about-campaign, viewed 27 May 2021.
41 Equal by 30, “Equal by 30: Countries commitments”, https://www.
equalby30.org/en/countries-commitments, viewed 27 May 2021.
42 For country details, see Table 4 in Policy Landscape chapter,
and GSR 2021 Data Pack. As of 20 May 2021, 121 countries had
joined the Climate Ambition Alliance, from Global Climate Action,
“Climate Ambition Alliance: Net Zero 2050”, https://climateaction.
unfccc.int/views/cooperative-initiative-details.html?id=94,
viewed 24 May 2021. E. Kosolapova, “77 countries, 100+ cities
commit to net zero carbon emissions by 2050 at Climate
Summit”, International Institute for Sustainable Development
(IISD) SDG Knowledge Hub, 24 September 2020, http://sdg.
iisd.org/news/77-countries-100-cities-commit-to-net-zero-
carbon-emissions-by-2050-at-climate-summit; IISD, “European
Commission launches green deal to reset economic growth for
carbon neutrality”, 19 December 2020, https://sdg.iisd.org/news/
european-commission-launches-green-deal-to-reset-economic-
growth-for-carbon-neutrality; “EU carbon neutrality: Leaders
agree 2050 target without Poland”, BBC News, 13 December
2020, https://www.bbc.com/news/world-europe-50778001.
A key principle to decarbonising the EU energy system is to
prioritise energy efficiency and develop a power sector based
on renewable energy, from European Commission (EC), Clean
Energy: The European Green Deal (Brussels: December 2020),
https://ec.europa.eu/commission/presscorner/detail/en/
fs_19_6723. The IEA net zero scenario specifies “no additional
new final investment decisions should be taken for new unabated
coal plants, the least efficient coal plants are phased out by 2030,
and the remaining coal plants still in use by 2040 are retrofitted”,
from IEA, Net Zero by 2050: A Roadmap for the Global Energy
Sector (Paris: May 2021), pp. 18-19, https://www.iea.org/reports/
net-zero-by-2050.
43 United Nations Framework Convention on Climate Change
(UNFCCC), “The Race to Zero”, https://racetozero.unfccc.int/
what-is-the-race-to-zero, viewed 13 November 2020; Global
Covenant of Mayors for Climate & Energy, https://www.
globalcovenantofmayors.org, viewed 3 November 2020; New
Climate Institute and Data-Driven EnviroLab, op. cit. note 35;
UNFCCC, “Net-zero double in less than a year”, press release
(Bonn: 21 September 2020), https://unfccc.int/news/commitments-
to-net-zero-double-in-less-than-a-year; Renewable Energy Policy
Network for the 21st Century (REN21), Renewables in Cities 2021
Global Status Report (Paris: 2021), https://www.ren21.net/reports/
cities-global-status-report. Box 2 from REC 2021 Data Pack,
available at www.ren21.net/cities/datapack. Data are compiled by
REN21 and based on CDP-ICLEI Unified Reporting System, CDP
Open Data, The Global 100% Renewable Energy Platform, Climate
Action Network, C40, ICLEI, IRENA, Sierra Club, UK100 and REN21
data collection. Some research is based on voluntary reporting and
may not be exhaustive.
44 IEA, op. cit. note 1.
45 IEA, “Monthly evolution of global CO2 emissions, 2020 relative
to 2019”, in “Global Energy Review: C02 emissions in 2020”, 2
March 2021, https://www.iea.org/articles/global-energy-review-
co2-emissions-in-2020; National Oceanic and Atmospheric
Administration, “Despite pandemic shutdowns, carbon dioxide and
methane surged in 2020”, 7 April 2021, https://research.noaa.gov/
article/ArtMID/587/ArticleID/2742/Despite-pandemic-shutdowns-
carbon-dioxide-and-methane-surged-in-2020.
46 Ibid. Previously, a flattening in emissions was due mainly to
declines in emissions from the power sector in some countries,
which were related mostly to improvements in energy efficiency
and to rising shares of renewable energy, but also to some extent to
fuel switching from coal to gas, as well as to higher nuclear power
output. From IEA, “Global CO2 emissions in 2019”, 11 February 2020,
https://www.iea.org/articles/global-co2-emissions-in-2019.
47 Share of renewable energy in total final energy consumption
in Brazil, Canada, Turkey, Argentina, India, Australia, China,
Mexico, Indonesia, Japan and South Africa based on IEA, “World
Energy Balances 2021 – Summary energy balances” (Paris:
2021), https://www.iea.org/data-and-statistics/data-product/
world-energy-balances#energy-balances; European countries
and EU-27 from Eurostat, “Share of renewable energy in gross
final energy consumption”, https://ec.europa.eu/eurostat/
databrowser/view/t2020_31/default/table, viewed 21 May 2021;
Russian Federation and Saudi Arabia based on data from IEA,
World Energy Balances 2020 (Paris: 2020), https://www.iea.org/
data-and-statistics/data-product/world-energy-balances. All
rights reserved; as modified by REN21. Targets for renewable
energy by end-2020 from the following sources: IRENA, “Energy
Profile: Canada”, https://www.irena.org/IRENADocuments/
Statistical_Profiles/North%20America/Canada_North%20
America_RE_SP , updated 30 September 2020; EU-27, Italy,
Germany and France from Eurostat, “News release: Share of
renewable energy in the EU up to 18.0%”, 23 January 2020,
https://ec.europa.eu/eurostat/documents/2995521/10335438/8-
23012020-AP-EN /292cf2e5-8870-4525-7ad7-
188864ba0c29?t=1579770240000; IRENA, “Energy
Profile: Turkey”, https://www.irena.org/IRENADocuments/
Statistical_Profiles/Eurasia/Turkey_Eurasia_RE_SP , updated
30 September 2020; IRENA, “Energy Profile: Mexico”, https://
www.irena.org/IRENADocuments/Statistical_Profiles/North%20
America/Mexico_North%20America_RE_SP , updated 30
September 2020.
48 Ibid. Figure 1 based on idem.
49 Box 3 based on the following sources: L. Bennun et al., Mitigating
Biodiversity Impacts Associated with Solar and Wind Energy
Development (Gland, Switzerland: IUCN, 2021), https://portals.
iucn.org/library/sites/library/files/documents/2021-004-En ;
S. Spillias et al., “Renewable energy targets may undermine their
sustainability”, Nature Climate Change, vol. 10 (2020), https://www.
nature.com/articles/s41558-020-00939-x.
259
https://www.thesolarfoundation.org/wp-content/uploads/2021/05/National-Solar-Jobs-Census-2020-FINAL
https://www.thesolarfoundation.org/wp-content/uploads/2021/05/National-Solar-Jobs-Census-2020-FINAL
https://www.thesolarfoundation.org/wp-content/uploads/2021/05/National-Solar-Jobs-Census-2020-FINAL
http://www.gogla.org/resources/employment-opportunities-in-an-evolving-market-off-grid-solar-creating-high-value
http://www.gogla.org/resources/employment-opportunities-in-an-evolving-market-off-grid-solar-creating-high-value
http://www.gogla.org/resources/employment-opportunities-in-an-evolving-market-off-grid-solar-creating-high-value
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https://www.greentechmedia.com/articles/read/the-highs-and-lows-for-solar-in-2020
https://www.greentechmedia.com/articles/read/one-response-to-the-coronavirus-giving-solar-away-for-free
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https://www.scmp.com/business/article/3080227/china-turbine-makers-winded-after-ecuador-lockdown-leaves-them-without
https://www.scmp.com/business/article/3080227/china-turbine-makers-winded-after-ecuador-lockdown-leaves-them-without
https://www.mckinsey.com/featured-insights/diversity-and-inclusion/diversity-wins-how-inclusion-matters
https://www.mckinsey.com/featured-insights/diversity-and-inclusion/diversity-wins-how-inclusion-matters
https://www.mckinsey.com/featured-insights/diversity-and-inclusion/diversity-wins-how-inclusion-matters
Renewables ‘early advantage’ in gender equality could disappear, warns software firm
Renewables ‘early advantage’ in gender equality could disappear, warns software firm
Renewables ‘early advantage’ in gender equality could disappear, warns software firm
https://www.forbes.com/sites/julietdavenport/2021/05/04/heres-how-to-fix-renewable-energys-diversity-problem
https://www.forbes.com/sites/julietdavenport/2021/05/04/heres-how-to-fix-renewable-energys-diversity-problem
https://www.enel.com/media/explore/search-press-releases/press/2021/02/enel-joins-equal-by-30-campaign-confirming-its-commitments-on-gender-equality-
https://www.enel.com/media/explore/search-press-releases/press/2021/02/enel-joins-equal-by-30-campaign-confirming-its-commitments-on-gender-equality-
https://www.enel.com/media/explore/search-press-releases/press/2021/02/enel-joins-equal-by-30-campaign-confirming-its-commitments-on-gender-equality-
Commitments are key for gender equality in the renewables industry
Commitments are key for gender equality in the renewables industry
Commitments are key for gender equality in the renewables industry
http://www.cleanenergyministerial.org/campaign-clean-energy-ministerial/equal-30
http://www.cleanenergyministerial.org/campaign-clean-energy-ministerial/equal-30
https://www.equalby30.org/en/content/about-campaign
https://www.equalby30.org/en/content/about-campaign
https://www.equalby30.org/en/countries-commitments
https://www.equalby30.org/en/countries-commitments
https://climateaction.unfccc.int/views/cooperative-initiative-details.html?id=94
https://climateaction.unfccc.int/views/cooperative-initiative-details.html?id=94
77 Countries, 100+ Cities Commit to Net Zero Carbon Emissions by 2050 at Climate Summit
77 Countries, 100+ Cities Commit to Net Zero Carbon Emissions by 2050 at Climate Summit
77 Countries, 100+ Cities Commit to Net Zero Carbon Emissions by 2050 at Climate Summit
European Commission Launches Green Deal to Reset Economic Growth for Carbon Neutrality
European Commission Launches Green Deal to Reset Economic Growth for Carbon Neutrality
European Commission Launches Green Deal to Reset Economic Growth for Carbon Neutrality
https://www.bbc.com/news/world-europe-50778001
https://ec.europa.eu/commission/presscorner/detail/en/fs_19_6723
https://ec.europa.eu/commission/presscorner/detail/en/fs_19_6723
https://www.iea.org/reports/net-zero-by-2050
https://www.iea.org/reports/net-zero-by-2050
https://racetozero.unfccc.int/what-is-the-race-to-zero
https://racetozero.unfccc.int/what-is-the-race-to-zero
https://www.globalcovenantofmayors.org
https://www.globalcovenantofmayors.org
https://unfccc.int/news/commitments-to-net-zero-double-in-less-than-a-year
https://unfccc.int/news/commitments-to-net-zero-double-in-less-than-a-year
http://www.ren21.net/cities/datapack
https://www.iea.org/articles/global-energy-review-co2-emissions-in-2020
https://www.iea.org/articles/global-energy-review-co2-emissions-in-2020
https://research.noaa.gov/article/ArtMID/587/ArticleID/2742/Despite-pandemic-shutdowns-carbon-dioxide-and-methane-surged-in-2020
https://research.noaa.gov/article/ArtMID/587/ArticleID/2742/Despite-pandemic-shutdowns-carbon-dioxide-and-methane-surged-in-2020
https://research.noaa.gov/article/ArtMID/587/ArticleID/2742/Despite-pandemic-shutdowns-carbon-dioxide-and-methane-surged-in-2020
https://www.iea.org/articles/global-co2-emissions-in-2019
https://www.iea.org/data-and-statistics/data-product/world-energy-balances#energy-balances
https://www.iea.org/data-and-statistics/data-product/world-energy-balances#energy-balances
https://ec.europa.eu/eurostat/databrowser/view/t2020_31/default/table
https://ec.europa.eu/eurostat/databrowser/view/t2020_31/default/table
https://www.iea.org/data-and-statistics/data-product/world-energy-balances
https://www.iea.org/data-and-statistics/data-product/world-energy-balances
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Canada_North%20America_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Canada_North%20America_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Canada_North%20America_RE_SP
https://ec.europa.eu/eurostat/documents/2995521/10335438/8-23012020-AP-EN /292cf2e5-8870-4525-7ad7-188864ba0c29?t=1579770240000
https://ec.europa.eu/eurostat/documents/2995521/10335438/8-23012020-AP-EN /292cf2e5-8870-4525-7ad7-188864ba0c29?t=1579770240000
https://ec.europa.eu/eurostat/documents/2995521/10335438/8-23012020-AP-EN /292cf2e5-8870-4525-7ad7-188864ba0c29?t=1579770240000
https://www.irena.org/IRENADocuments/Statistical_Profiles/Eurasia/Turkey_Eurasia_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/Eurasia/Turkey_Eurasia_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Mexico_North%20America_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Mexico_North%20America_RE_SP
https://www.irena.org/IRENADocuments/Statistical_Profiles/North%20America/Mexico_North%20America_RE_SP
https://portals.iucn.org/library/sites/library/files/documents/2021-004-En
https://portals.iucn.org/library/sites/library/files/documents/2021-004-En
https://www.nature.com/articles/s41558-020-00939-x
https://www.nature.com/articles/s41558-020-00939-x
ENDNOTES · GLOBAL OVERVIEW 01
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50 Estimated shares based on the following sources: total final energy
consumption in 2019 (estimated at 381.1 exajoules, EJ) is based on
377.7 EJ for 2018, from IEA, World Energy Balances 2020, op. cit.
note 47, and escalated by the 0.91% increase in estimated global
total final consumption (including non-energy use) from 2018 to
2019, derived from IEA, World Energy Outlook 2020 (Paris: 2020).
Estimate of traditional biomass from idem. Modern bioenergy for
heat and geothermal heat based on 2018 values from IEA, World
Energy Balances, op. cit. note 47, and escalated to 2019 based
on combined annual average growth rates from 2008 to 2018.
Biofuels used in transport in 2019 from IEA, op. cit. note 5. Solar
thermal heating and cooling from M. Spörk-Dür, AEE-Institute for
Sustainable Technologies (AEE INTEC), Gleisdorf, Austria, personal
communication with REN21, April 2021, and from W. Weiss and M.
Spörk-Dür, Solar Heat Worldwide. Global Market and Development
Trends in 2020, Detailed Market Figures 2019 (Paris: IEA Solar
Heating and Cooling Programme, 2021), http://www.iea-shc.
org/solar-heat-worldwide. Nuclear power final consumption
based on generation of 2,701.4 TWh, from US Energy Information
Administration (EIA) international data browser, https://www.eia.
gov/international/data/world, viewed 14 April 2021, and global
average electricity losses and estimated industry own-use of
nuclear power in 2019 based on IEA, World Energy Balances 2020,
op. cit. note 47. Electricity consumption from renewable sources
based on estimates of 2018 generation from IEA, op. cit. note 5
and global average electricity losses and estimated technology-
specific industry own-use of electricity from renewable sources in
2019, based on IEA, World Energy Balances 2020, op. cit. note 47.
Estimates of industry own-use of electricity are differentiated by
technology based on explicit technology-specific own-use (such as
pumping at hydropower facilities) as well as apportioning of various
categories of own-use by technology as deemed appropriate.
For example, industry own-use of electricity at coal mines and oil
refineries are attributed to fossil fuel generation. Industry own-use
includes the difference between gross and net generation at
thermal power plants (the difference lies in the power consumption
of various internal loads, such as fans, pumps and pollution
controls at thermal plants), and other uses such as electricity use
in coal mining and fossil fuel refining. Differentiated own-use by
technology, combined with global average losses, are as follows:
solar PV, ocean energy and wind power (8.2%); hydropower
(10.1%); CSP and geothermal (14.2%); and biopower (15.2%). See
Methodological Notes. Figure 2 based on Ibid., all sources.
51 Ibid., all sources.
52 Ibid.
53 Ibid.
54 Ibid.
55 Figure 3 based on sources in endnote 47.
56 See Energy Efficiency chapter and IEA, Energy Efficiency 2020
(Paris: 2020), https://www.iea.org/reports/energy-efficiency-2020.
57 Based on IEA, World Energy Balances 2020, op. cit. note 47.
58 Based on Ibid.
59 Ibid.
60 Ibid.
61 Figure 4 based on Ibid.
62 For information on technological innovation in industry and
transport, see IRENA, Reaching Zero With Renewables (Abu Dhabi:
2020), https://www.irena.org/publications/2020/Sep/Reaching-
Zero-with-Renewables, and S. Madeddu et al., “The CO2 reduction
potential for the European industry via direct electrification of
heat supply (power-to-heat)”, Environmental Research Letters,
vol. 15, no. 12 (25 November 2020), https://iopscience.iop.org/
article/10.1088/1748-9326/abbd02.
63 IEA, Electricity Security 2021 (Paris: 2021), https://www.iea.org/
reports/electricity-security-2021; S. Teske, Citizen Power for Grids
(Paris: REN21, 2021), https://www.ren21.net/2021-citizen-power-
for-grids. See also Systems Integration chapter.
64 However, Asia (where coal remains cheaper) is estimated to
see renewables becoming competitive by 2030 or earlier. Wood
Mackenzie, “Renewables in most of Asia Pacific to be cheaper than
coal power by 2030”, 26 November 2020, https://www.woodmac.
com/press-releases/renewables-in-most-of-asia-pacific-to-be-
cheaper-than-coal-power-by-2030.
65 See Table 4 in Policy Landscape chapter.
66 UNFCCC, “Nationally determined contributions under the
Paris Agreement”, 26 February 2021, https://unfccc.int/sites/
default/files/resource/cma2021_02E ; UNFCCC, “NDC
Synthesis Report”, 26 February 2021, https://unfccc.int/process-
and-meetings/the-paris-agreement/nationally-determined-
contributions-ndcs/nationally-determined-contributions-ndcs/
ndc-synthesis-report; UNFCCC, “NDC Registry”, https://www4.
unfccc.int/sites/NDCStaging/Pages/All.aspx, viewed 21 May 2021.
67 Excluding recovery packages. REN21 Policy Database; see GSR
2021 Data Pack at www.ren21.net/gsr-2021.
68 Austria from Klimaaktiv, “E-Mobilitätsoffensive 2021”, https://www.
klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.
html, viewed 21 May 2021; Germany from BMVI, “500 Millionen Euro
zusätzlich für Ladeinfrastruktur – 6. Förderaufruf abgeschlossen”,
https://www.bmvi.de/SharedDocs/DE/Artikel/G/infopapier-
sechster-foerderaufruf-ladeinfrastruktur.html, viewed 21 May 2021;
“Japan to offer up to ¥800,000 in subsidies for electric vehicles”,
Japan Times, 25 November 2020, https://www.japantimes.co.jp/
news/2020/11/25/business/subsidies-electric-vehicles. Previously,
a policy linking renewables and EVs was in place in Luxembourg,
but it was no longer in place as of 2017. IRENA, Energy Subsidies.
Evolution in the Global Energy Transformation to 2050 (Abu Dhabi:
2020), https://www.irena.org/publications/2020/Apr/Energy-
Subsidies-2020; OECD, “Governments should use Covid-19 recovery
efforts as an opportunity to phase out support for fossil fuels, say
OECD and IEA”, 5 June 2020, https://www.oecd.org/environment/
governments-should-use-covid-19-recovery-efforts-as-an-
opportunity-to-phase-out-support-for-fossil-fuels-say-oecd-and-iea.
htm; F. Birol, “Put clean energy at the heart of stimulus plans to
counter the coronavirus crisis”, IEA, 14 March 2020, https://www.
iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-
plans-to-counter-the-coronavirus-crisis; CarbonBrief, “Leading
economists: Green coronavirus recovery also better for economy”,
5 May 2020,https://www.carbonbrief.org/leading-economists-
green-coronavirus-recovery-also-better-for-economy; M. Holder,
“Boris Johnson: ‘We owe it to future generations to build back
better’”, Business Green, 28 May 2020, https://www.businessgreen.
com/news/4015783/boris-johnson-owe-future-generations-build;
Climate Action Network, “CAN position: Who should pay the bill for
covid-19 recovery measures?” April 2021, https://climatenetwork.
org/resource/can-position-who-should-pay-the-bill-for-covid-
19-recovery-measures; United Nations Environment Programme
Finance Initiative, “Position on the coronavirus recovery”, 2021,
https://www.unepfi.org/wordpress/wp-content/uploads/2021/01/
AoA-position-on-the-coronavirus-recovery-21 .
69 In 2019, fossil fuel subsidies totalled more than USD 478
billion, down from USD 582 billion in 2018, due mainly to lower
international oil prices and thus lower costs to governments for
subsidising energy for end-users. However, direct and indirect
subsidies for fossil fuel production increased 38% in 2019 based on
analysis of 77 countries, with a rise also estimated for 2020, nearly
triple the support for renewable electricity generation and biofuels.
OECD, op. cit. note 68; IRENA, op. cit. note 68, p. 8. In Europe, coal
subsidies decreased 9% between 2015 and 2018, while natural gas
subsidies increased 4%, from EC, “Annex to the 2020 report on the
State of the Energy Union pursuant to Regulation (EU) 2018/1999
on Governance of the Energy Union and Climate Action” (Brussels:
14 October 2020), p. 7, https://ec.europa.eu/energy/sites/ener/files/
progress_on_energy_subsidies_in_particular_for_fossil_fuels .
70 The United States saw a net decrease in utility-scale coal-fired
power capacity of over 10 GW in 2020, while more than 20 GW
was planned for decommissioning in the EU and the United
Kingdom during 2020. The US 2020 decommissioned capacity
amounted to the fourth highest annual total since 2009, while
total US coal capacity declined 25% between 2010 and 2019,
from B. Storrow, “With mega-emitters closed, coal’s ‘cleaner fleet’
persists”, E&E News, 9 December 2020, https://www.eenews.
net/stories/1063720241. US net decrease from US EIA, “Electric
Power Monthly with Data for December 2020”, February 2021,
https://www.eia.gov/electricity/monthly/archive/February2021.
pdf; EU and United Kingdom from IEA, “2020 Global overview:
Capacity, supply and emissions”, in Electricity Market Report (Paris:
December 2020), https://www.iea.org/reports/electricity-market-
report-december-2020/2020-global-overview-capacity-supply-
and-emissions; CarbonBrief, “Global coal power”, https://www.
carbonbrief.org/mapped-worlds-coal-power-plants, viewed 26
March 2021. In Europe, operation began at the new unit 6 (660
MW) Ledvice Power Station in the Czech Republic on 1 January
2020, from Ministry of the Environment of the Czech Republic,
“Změna povolení”, https://www.mzp.cz/ippc/ippc4.nsf/$pid/
260
http://www.iea-shc.org/solar-heat-worldwide
http://www.iea-shc.org/solar-heat-worldwide
https://www.eia.gov/international/data/world
https://www.eia.gov/international/data/world
https://www.iea.org/reports/energy-efficiency-2020
https://www.irena.org/publications/2020/Sep/Reaching-Zero-with-Renewables
https://www.irena.org/publications/2020/Sep/Reaching-Zero-with-Renewables
https://iopscience.iop.org/article/10.1088/1748-9326/abbd02
https://iopscience.iop.org/article/10.1088/1748-9326/abbd02
https://www.iea.org/reports/electricity-security-2021
https://www.iea.org/reports/electricity-security-2021
https://www.woodmac.com/press-releases/renewables-in-most-of-asia-pacific-to-be-cheaper-than-coal-power-by-2030
https://www.woodmac.com/press-releases/renewables-in-most-of-asia-pacific-to-be-cheaper-than-coal-power-by-2030
https://www.woodmac.com/press-releases/renewables-in-most-of-asia-pacific-to-be-cheaper-than-coal-power-by-2030
https://unfccc.int/sites/default/files/resource/cma2021_02E
https://unfccc.int/sites/default/files/resource/cma2021_02E
https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs/ndc-synthesis-report
https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs/ndc-synthesis-report
https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs/ndc-synthesis-report
https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs/ndc-synthesis-report
https://www4.unfccc.int/sites/NDCStaging/Pages/All.aspx
https://www4.unfccc.int/sites/NDCStaging/Pages/All.aspx
http://www.ren21.net/gsr-2021
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://www.bmvi.de/SharedDocs/DE/Artikel/G/infopapier-sechster-foerderaufruf-ladeinfrastruktur.html
https://www.bmvi.de/SharedDocs/DE/Artikel/G/infopapier-sechster-foerderaufruf-ladeinfrastruktur.html
https://www.japantimes.co.jp/news/2020/11/25/business/subsidies-electric-vehicles
https://www.japantimes.co.jp/news/2020/11/25/business/subsidies-electric-vehicles
https://www.irena.org/publications/2020/Apr/Energy-Subsidies-2020
https://www.irena.org/publications/2020/Apr/Energy-Subsidies-2020
https://www.oecd.org/environment/governments-should-use-covid-19-recovery-efforts-as-an-opportunity-to-phase-out-support-for-fossil-fuels-say-oecd-and-iea.htm
https://www.oecd.org/environment/governments-should-use-covid-19-recovery-efforts-as-an-opportunity-to-phase-out-support-for-fossil-fuels-say-oecd-and-iea.htm
https://www.oecd.org/environment/governments-should-use-covid-19-recovery-efforts-as-an-opportunity-to-phase-out-support-for-fossil-fuels-say-oecd-and-iea.htm
https://www.oecd.org/environment/governments-should-use-covid-19-recovery-efforts-as-an-opportunity-to-phase-out-support-for-fossil-fuels-say-oecd-and-iea.htm
https://www.iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-plans-to-counter-the-coronavirus-crisis
https://www.iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-plans-to-counter-the-coronavirus-crisis
https://www.iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-plans-to-counter-the-coronavirus-crisis
Leading economists: Green coronavirus recovery also better for economy
Leading economists: Green coronavirus recovery also better for economy
https://www.businessgreen.com/news/4015783/boris-johnson-owe-future-generations-build
https://www.businessgreen.com/news/4015783/boris-johnson-owe-future-generations-build
CAN Position: Who Should Pay The Bill For COVID-19 Recovery Measures?
CAN Position: Who Should Pay The Bill For COVID-19 Recovery Measures?
CAN Position: Who Should Pay The Bill For COVID-19 Recovery Measures?
https://www.unepfi.org/wordpress/wp-content/uploads/2021/01/AoA-position-on-the-coronavirus-recovery-21
https://www.unepfi.org/wordpress/wp-content/uploads/2021/01/AoA-position-on-the-coronavirus-recovery-21
https://ec.europa.eu/energy/sites/ener/files/progress_on_energy_subsidies_in_particular_for_fossil_fuels
https://ec.europa.eu/energy/sites/ener/files/progress_on_energy_subsidies_in_particular_for_fossil_fuels
https://www.eenews.net/stories/1063720241
https://www.eenews.net/stories/1063720241
https://www.eia.gov/electricity/monthly/archive/February2021
https://www.eia.gov/electricity/monthly/archive/February2021
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-capacity-supply-and-emissions
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-capacity-supply-and-emissions
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-capacity-supply-and-emissions
https://www.mzp.cz/ippc/ippc4.nsf/$pid/MZPPRHECJJZW
ENDNOTES · GLOBAL OVERVIEW 01
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MZPPRHECJJZW, viewed 24 May 2021, and at Unit 4 of the
Datteln Power Station in Germany on 30 May 2020, from “Climate
activists protest Germany’s new Datteln 4 coal power plant”, DW,
30 May 2020, https://www.dw.com/en/climate-activists-protest-
germanys-new-datteln-4-coal-power-plant/a-53632887.
71 CarbonBrief, op. cit. note 70. An estimated 46 GW of a new coal
capacity came into service in 2020, while 28 GW of coal capacity
was retired; for natural gas, 50 GW was added and 20 GW was
retired; and for nuclear, some 5 GW came online but 10 GW was
retired, all from Frankfurt School-UNEP Collaborating Centre
for Climate & Sustainable Energy Finance and BloombergNEF,
Global Trends in Renewable Energy Investment (Frankfurt: 2020),
https://wedocs.unep.org/bitstream/handle/20.500.11822/32700/
GTR20 ; China added by far the most capacity during the year,
commissioning an estimated 38.4 GW.
72 Global Energy Monitor, “Global Coal Plant Tracker”, https://
globalenergymonitor.org/projects/global-coal-plant-tracker,
viewed 12 March 2021; J. Purtill, “World is now shutting down
coal plants faster than it’s opening them”, ABC, 4 August
2020, https://www.abc.net.au/triplej/programs/hack/
world-global-coal-power-capacity-has-fell-in-2020/12523904.
73 Global Energy Monitor, Boom and Bust: Tracking the Global Coal
Plant Pipeline (London: 2021), p. 3, https://globalenergymonitor.
org/wp-content/uploads/2021/04/BoomAndBust_2021_final ;
Many countries – notably in Asia – have reconsidered their view
of coal going forward, driven by several factors including lower
electricity demand during the Covid-19 crisis, lower costs for
renewable energy, low natural gas prices, reducing air pollution,
financing difficulties, and rising international pressure, from IEA,
op. cit. note 70. Conversely, natural gas-fired power plant capacity
continued to expand globally during the year, as more than 40
GW was estimated to be commissioned in 2020 driven mainly by
the Middle East, the United States and China, from idem.
74 End Coal, “Global Coal Public Finance Tracker”, https://endcoal.org/
finance-tracker, viewed 6 March 2021; IEA, Chinese Companies
Energy Activities in Emerging Asia (Paris: April 2019), https://www.iea.
org/reports/chinese-companies-energy-activities-in-emerging-asia.
75 Rainforest Action Network, Banking on Climate Change
Fossil Fuel Financial Report (San Francisco: March 2020),
https://www.ran.org/wp-content/uploads/2020/03/
Banking_on_Climate_Change__2020_vF .
76 Energy Policy Tracker, Recovery package database,
www.energypolicytracker.org, viewed on multiple occasions
in March and April 2021.
77 The remaining billions are considered “Other” in the database.
“Governments” include all levels. Energy Policy Tracker, op. cit. note
76.
78 E. Gündüzyeli and J. Flisowska, “Poland goes all out on coal rescue
against EU’s higher climate goal”, EURACTIV, 23 December 2020,
https://www.euractiv.com/section/energy/opinion/poland-goes-
all-out-on-coal-rescue-against-eus-higher-climate-goal.
79 Sectoral energy share based on IEA, World Energy Balances 2020,
op. cit. note 47.
80 Calculations based on Ibid. See Methodological Notes and
GSR 2021 Data Pack.
81 Ibid.
82 Ibid. Renewable contribution to cooling from IRENA, IEA and
REN21, Renewable Energy Policies in a Time of Transition: Heating
and Cooling (Abu Dhabi and Paris: 2020), p. 49, https://www.
ren21.net/wp-content/uploads/2019/05/IRENA_IEA_REN21-
Policies_HC_2020_Full_Report .
83 IEA, “Context: A world in lockdown”, in Global Energy
Review 2020 (Paris: 2020), https://www.iea.org/reports/
global-energy-review-2020/context-a-world-in-lockdown.
84 IEA, Global Energy Review 2020 (Paris: 2020), https://www.iea.org/
reports/global-energy-review-2020.
85 IEA, “Buildings”, in Energy Efficiency 2020 (Paris: 2020), https://www.
iea.org/reports/energy-efficiency-2020/buildings; D. Crow and A. Millot,
“Working from home can save energy and reduce emissions. But how
much?” IEA, 12 June 2020 https://www.iea.org/commentaries/working-
from-home-can-save-energy-and-reduce-emissions-but-how-much.
86 Sectoral energy share based on IEA, World Energy Balances
2020, op. cit. note 47. Emissions include both direct and indirect
emissions, such as power generation for electricity, and exclude
the estimated portion of overall industry devoted to manufacturing
building construction materials such as steel, cement and glass, from
Global Alliance for Buildings and Construction (GlobalABC), IEA
and UNEP, 2020 Global Status Report for Buildings and Construction
(Paris: 2020), p. 12, https://globalabc.org/sites/default/files/inline-
files/2020%20Buildings%20GSR_FULL%20REPORT .
87 Ibid, pp. 20, 23.
88 Ibid, p. 18.
89 Ibid, p. 18. These are global trends, but large variations exist
in different regions where decoupling has been observed.
See, for example, Architecture 2030, “An unprecedented
achievement”, February 2020, https://architecture2030.org/
unprecedented-a-way-forward.
90 GlobalABC, IEA and UNEP, op. cit. note 86, p. 18.
91 See Energy Efficiency chapter.
92 Based on IEA, World Energy Balances 2020, op. cit. note 47.
93 Ibid.
94 Ibid.
95 Ibid.
96 T. Abergel and C. Delmastro, “Is cooling the future of heating?”
IEA, 13 December 2020, https://www.iea.org/commentaries/
is-cooling-the-future-of-heating.
97 Ibid.
98 Ibid.; IEA, The Future of Cooling (Paris: 2018), p. 45, https://www.
iea.org/reports/the-future-of-cooling.
99 Based on IEA, World Energy Balances 2020, op. cit. note 47.
100 R. Lowes et al., “Hot stuff: Research and policy principles for
heat decarbonisation through smart electrification”, Energy
Research and Social Science, vol. 70 (December 2020), https://
www.sciencedirect.com/science/article/pii/S2214629620303108;
Regulatory Assistance Project, Beneficial Electrification of
Space Heating (Brussels: 2018), https://www.raponline.org/
knowledge-center/beneficial-electrification-of-space-heating.
101 Based on IEA, World Energy Balances 2020, op. cit. note 47.
102 Ibid.
103 Ibid.
104 Figure 6 based on Ibid.
105 Eurostat, “Share of energy from renewable sources”, https://
ec.europa.eu/eurostat/data/database, viewed 12 March 2021.
The definition of “renewable heating and cooling” in the EU
also includes waste heat (or “derived” heat) and thermal energy
supplied by aerothermal, hydrothermal or geothermal heat pumps.
106 Government of Iceland, “Energy”, https://www.government.
is/topics/business-and-industry/energy, viewed 12 May 2021;
Eurostat, op. cit. note 105.
107 Abergel and Delmastro, op. cit. note 96.
108 Ibid.
109 IRENA, IEA and REN21, op. cit. note 82, p. 49.
110 Based on IEA, World Energy Balances 2020, op. cit. note 47.
111 See Bioenergy section in Market and Industry chapter.
112 Based on IEA, World Energy Balances 2020, op. cit. note 47.
113 Ibid.
114 Ibid.
115 See Solar Thermal Heating section in Market and Industry chapter.
116 See Market and Industry chapter.
117 Based on IEA, World Energy Balances 2020, op. cit. note 47.
118 Ibid.
119 Ibid.
120 IEA, op. cit. note 5.
121 Based on IEA, World Energy Balances 2020, op. cit. note 47.
122 See Heat Pumps section in Systems Integration chapter.
123 See Heat Pumps section in Systems Integration chapter,
and Table 6 in Policy chapter. The United Kingdom made a
commitment to install 600,000 heat pumps yearly by 2028, a
17-fold increase compared the level of installations in 2019. R.
Lowes, J. Rosenow and P. Guertler, Getting On Track to Net
Zero: A Policy Package for a Heat Pump Mass Market in the
UK (Brussels: 2021), https://www.raponline.org/wp-content/
uploads/2021/03/RAP-Heat-Pump-Policy-0324212 ; Heat
Pump Association, “UK heat pump market set to almost double
261
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https://wedocs.unep.org/bitstream/handle/20.500.11822/32700/GTR20
https://wedocs.unep.org/bitstream/handle/20.500.11822/32700/GTR20
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Poland goes all out on coal rescue against EU’s higher climate goal
Poland goes all out on coal rescue against EU’s higher climate goal
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https://www.iea.org/reports/global-energy-review-2020
https://www.iea.org/reports/global-energy-review-2020
https://www.iea.org/reports/energy-efficiency-2020/buildings
https://www.iea.org/reports/energy-efficiency-2020/buildings
https://www.iea.org/commentaries/working-from-home-can-save-energy-and-reduce-emissions-but-how-much
https://www.iea.org/commentaries/working-from-home-can-save-energy-and-reduce-emissions-but-how-much
https://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT
https://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT
https://www.iea.org/commentaries/is-cooling-the-future-of-heating
https://www.iea.org/commentaries/is-cooling-the-future-of-heating
https://www.iea.org/reports/the-future-of-cooling
https://www.iea.org/reports/the-future-of-cooling
https://www.sciencedirect.com/science/article/pii/S2214629620303108
https://www.sciencedirect.com/science/article/pii/S2214629620303108
https://ec.europa.eu/eurostat/data/database
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ENDNOTES · GLOBAL OVERVIEW 01
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this year”, https://www.heatpumps.org.uk/uk-heat-pump-market-
set-to-almost-double-this-year, viewed 12 March 2021. However,
the United Kingdom’s Green Homes Grant programme, which
supported the installation of heat pumps, was cancelled in March
2021, six months after its launch, from F. Harvey,“UK government
scraps green homes grant after six months”, The Guardian (UK),
27 March 2021, https://www.theguardian.com/environment/2021/
mar/27/uk-government-scraps-green-homes-grant-after-six-
months. International Energy Research Centre, Best Practices
and Policy Solutions for Ireland’s 2030 Heat Pump Target (Dublin:
2020), http://www.ierc.ie/wp-content/uploads/2020/11/Best-
Practices-and-Policy-Solutions-for-Irelands-2030-Heat-Pump-
Target-1 .
124 T. Gruenwald and M. Lee, “2020: Watt a year for building
electrification!” RMI, 16 December 2020, https://rmi.org/2020-
watt-a-year-for-building-electrification. See also: J. Meyers,
Building Electrification: How Cities and Counties Are Implementing
Electrification Policies (Boulder: 2020), https://swenergy.org/pubs/
building_electrification; T. DiChristopher, “’Banning’ natural gas is
out; electrifying buildings is in”, S&P Global, https://www.spglobal.
com/marketintelligence/en/news-insights/latest-news-headlines/
banning-natural-gas-is-out-electrifying-buildings-is-in-59285807;
REN21, op. cit. note 43. RMI was also awarded USD 8 million
from the Bezos Fund to work with local governments and develop
policies and plans to renovate their building stock to be all-electric,
from K. Kroh and J. Mandel, “RMI awarded $8 million to accelerate
carbon-free US buildings”, RMI, 16 November 2020, https://rmi.org/
rmi-awarded-8-million-to-accelerate-carbon-free-us-buildings.
125 Ibid, all references.
126 M. Mazengarb, “ACT Greens pledge to build first zero-emissions,
all-electric business district”, One Step Off the Grid, 23 September
2020, https://onestepoffthegrid.com.au/act-greens-pledge-to-
build-first-zero-emissions-all-electric-business-district.
127 M. Mace, “North of England homes to pilot hydrogen heating”,
EURACTIV, 6 January 2021, https://www.euractiv.com/section/
energy/news/north-of-england-homes-to-pilot-hydrogen-heating;
T. Seskus, “Hydrogen-injected natural gas to heat homes in Alberta
city next year”, CBC News, 21 July 2020, https://www.cbc.ca/news/
canada/calgary/alberta-hydrogen-home-heating-1.5657736.
128 EC, A Hydrogen Strategy for a Climate-Neutral Europe
(Brussels: 2020), p. 6, https://ec.europa.eu/energy/sites/
ener/files/hydrogen_strategy .
129 Fraunhofer Institute for Energy Economics and Energy System
Technology, Hydrogen in the Energy System of the Future: Focus
on Heat in Buildings (Hannover: 2020),https://www.iee.fraunhofer.
de/content/dam/iee/energiesystemtechnik/en/documents/
Studies-Reports/FraunhoferIEE_Study_H2_Heat_in_Buildings_
final_EN_20200619 ; C. Baldino et al., Hydrogen for Heating?
Decarbonization Options for Households in the European Union
in 2050 (Brussels: International Council on Clean Transportation,
2021), https://theicct.org/publications/hydrogen-heating-eu-
feb2021; Agora Energiewende, No-Regret Hydrogen: Charting
Early Steps for H2 Infrastructure in Europe (Berlin: 2021), https://
static.agora-energiewende.de/fileadmin/Projekte/2021/2021_02_
EU_H2Grid/A-EW_203_No-regret-hydrogen_WEB ;
E3G, E3G Hydrogen Factsheet: Building Heat (Brussels: 2021),
https://9tj4025ol53byww26jdkao0x-wpengine.netdna-ssl.com/
wp-content/uploads/E3G_2021_Hydrogen-Factsheet_Heat ;
E. Godsen, “Switching all boilers to hydrogen ‘is impractical’”, The
Times, 7 December 2020, https://www.thetimes.co.uk/article/
switching-all-boilers-to-hydrogen-is-impractical-zw00f3v9l.
130 European Alliance to Save Energy, “Broad coalition
calls on EU not to rely on hydrogen to decarbonise
buildings”, 21 January 2021, https://euase.net/
broad-coalition-calls-eu-not-to-rely-on-hydrogen-buildings.
131 Based on IEA, World Energy Balances 2020, op. cit. note 47.
132 Ibid.
133 The top European countries in 2017 and their respective shares of
renewable district heat in final heat demand were Iceland (89.2%),
Denmark (38.6%), Lithuania (38.5%), Sweden (36.6), Finland
(15.4%) and Norway (3.7%); in Norway, renewable electricity
represented 60% of the heat market, all from Euroheat & Power,
Country by Country 2019 (Brussels: 2019), https://www.euroheat.
org/cbc_publications/cbc-2019.
134 See Solar Thermal Heating section in Market and Industry chapter.
135 World Health Organization, “Household air pollution”, 8 May
2018, https://www.who.int/news-room/fact-sheets/detail/
household-air-pollution-and-health.
136 Energy Sector Management Assistance Program
(ESMAP), The State of Access to Modern Cooking Energy
Services (Washington, DC: 2020), p. 39, http://documents.
worldbank.org/curated/en/937141600195758792/
The-State-of-Access-to-Modern-Energy-Cooking-Services.
137 Ibid.
138 Solar Cookers International, “Distribution of solar cookers”, https://
www.solarcookers.org/partners/distribution-solar-cookers, viewed
31 March 2021.
139 Based on IEA, World Energy Balances 2020, op. cit. note 47.
140 IEA, op. cit. note 63; IEA, Power Systems in Transition (Paris: 2020),
https://www.iea.org/reports/power-systems-in-transition.
141 IEA, op. cit. note 5.
142 See Power section in this chapter. Ember, op. cit. note 1.
143 See Distributed Renewables chapter.
144 GOGLA, Global Off-Grid Solar Market Report Semi-Annual Sales
and Impact Data, January-June 2020, (Amsterdam: 2020), https://
www.gogla.org/sites/default/files/resource_docs/global_off_grid_
solar_market_report_h1_2020 .
145 Mini-Grids Partnership, State of the Global Mini-Grids Market 2020
(BloombergNEF and SEforALL: 1 July 2020), https://minigrids.org/
market-report-2020.
146 See Policy Landscape chapter, pp. 69-71.
147 Ibid.
148 REN21, op. cit. note 43, pp. 58-59.
149 Ibid. pp. 58-59.
150 See Heating and Cooling section in Policy Landscape chapter. The
commitments and bans vary by fuel (e.g., coal, oil or fossil gas), by
building type (e.g., new vs. existing) and by year they will come into
force. The seven national governments were Austria, Denmark,
France, Germany, the Netherlands, Norway, Poland and the United
Kingdom. In 2020, the United Kingdom announced a future ban
of gas boilers in newly built homes. The previous target year was
2023, and is now expected to be 2025, from R. Lowes, University of
Exeter, personal communication with REN21, 26 April 2021. France
also banned the use of gas heating in new homes by mid-2021,
with multi-dwelling buildings targeted for 2024, from M. Chauvot,
S. Wajsbrot and V. Collen, “Le chauffage au gaz bientôt proscrit
des logements neufs”, Les Echos, 24 November 2020,https://
www.lesechos.fr/industrie-services/immobilier-btp/exclusif-
immobilier-le-chauffage-au-gaz-proscrit-des-maisons-neuves-
des-2021-1267599#xtor=CS1-3046; “Réglementation: le chauffage
au gaz interdit dès l’été 2021 pour les maisons neuves”, Journal du
bâtiment et des TP, 1 December 2020, https://www.journal-du-btp.
com/reglementation-le-chauffage-au-gaz-interdit-des-l-ete-
2021-pour-les-maisons-neuves-2265.html. New buildings in the
Netherlands are increasingly using electricity (heat pumps) for
space and water heating following the country’s declaration of a
gas phaseout in 2018, from C. Lyon, “Heating the Netherlands: The
future’s all-electric. Or is it? Delta-EE’s top 10 facts to demystify
the Dutch heating market”, Delta Energy & Environment, 18 June
2020, https://www.delta-ee.com/delta-ee-blog/heating-the-
netherlands-the-future-s-all-electric-or-is-it-delta-ee-s-top-10-
facts-to-demystify-the-dutch-heating-market-1.html;B. Webster,
S. Swinford and A. Ellson, “Gas boiler ban for new homes in three
years under green deal”, The Times, 19 November 2020, https://
www.thetimes.co.uk/article/gas-boiler-ban-for-new-homes-in-
three-years-under-green-deal-sc85v00rn. See also REN21, op.
cit. note 43, p. 68, and J. Rosenow and R. Lowes, “Heating without
the hot air: Principles for smart heat electrification” (Brussels:
2020), p. 22, https://www.raponline.org/knowledge-center/
heating-without-hot-air-principles-smart-heat-electrification.
151 REN21, op. cit. note 43, p. 68; M. Gough, “San Francisco, San Jose,
and Oakland bring electrification this holiday season”, Sierra Club,
3 December 2020, https://www.sierraclub.org/articles/2020/12/
san-francisco-san-jose-and-oakland-bring-electrification-
holiday-season. The European Commission is considering
revising its energy labelling and downgrading fossil gas boilers
to the lowest efficiency standard to encourage consumers to opt
for cleaner options, from ECOS and CoolProducts, Five Years
Left: How Ecodesign and Energy Labelling Can Decarbonise
Heating (Brussels: 2020), https://ecostandard.org/wp-content/
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Heating without the hot air: Principles for smart heat electrification
Heating without the hot air: Principles for smart heat electrification
https://www.sierraclub.org/articles/2020/12/san-francisco-san-jose-and-oakland-bring-electrification-holiday-season
https://www.sierraclub.org/articles/2020/12/san-francisco-san-jose-and-oakland-bring-electrification-holiday-season
https://www.sierraclub.org/articles/2020/12/san-francisco-san-jose-and-oakland-bring-electrification-holiday-season
https://ecostandard.org/wp-content/uploads/2020/12/Five-Years-Left-How-ecodesign-and-energy-labelling-Coolproducts-report
ENDNOTES · GLOBAL OVERVIEW 01
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uploads/2020/12/Five-Years-Left-How-ecodesign-and-energy-
labelling-Coolproducts-report . Further examples of such bans
in Rosenow and Lowes, op. cit. note 150, p. 22.
152 Most European countries still provided subsidies for fossil fuel
boilers at end-2020, often at levels superior to financial policies
that incentivise the use of renewable energy for heating, from
F. Tognetti, Analysis of Existing Incentives in Europe for Heating
Powered by Fossil Fuels and Renewable Sources (Brussels: 2021),
https://www.coolproducts.eu/wp-content/uploads/2020/12/
Analysis-of-Fossil-Fuel-Incentives-in-Europe_FINAL_ . For
example, Italy provides a tax rebate for 110% of the cost of an
electric heat pump, yet a similar subsidy is also available for highly
efficient gas boilers under certain conditions, from idem. The US
state of New York also still has laws that subsidise the expansion
of its gas network, from E. Pontecorvo, “He wanted to get his home
off fossil fuels. There was just one problem.”, Grist, 18 March 2021,
https://grist.org/buildings/he-wanted-to-get-his-home-off-fossil-
fuels-there-was-just-one-problem.
153 R. Leber, “How the fossil fuel industry convinced Americans
to love gas stoves”, Mother Jones, 11 February 2021, https://
www.motherjones.com/environment/2021/02/how-the-
fossil-fuel-industry-convinced-americans-to-love-gas-stoves;
K. Joshi, “The gas war part 1: The American electrification
battlegrounds”, Medium, 13 November 2020, https://
medium.com/lobbywatch/the-gas-war-part-1-the-american-
electrification-battlegrounds-3494ac71d100; R. Lowes, B.
Woodman and J. Speirs, “Heating in Great Britain: An incumbent
discourse coalition resists an electrifying future”, Environmental
Innovation and Societal Transitions, vol. 37 (December 2020),
pp. 1-17, https://www.sciencedirect.com/science/article/pii/
S2210422420300964?via%3Dihub; Global Witness, Pipe Down:
How Gas Companies Influence EU Policy and Have Pocketed
€4 Billion of Taxpayers’ Money (London: 2020),https://www.
globalwitness.org/en/campaigns/oil-gas-and-mining/pipe-down.
154 D. Drugmand, “Unplugged: How the gas industry is fighting efforts
to electrify buildings”, DeSmog Blog, 22 July 2020, https://www.
desmogblog.com/2020/07/22/unplugged-how-gas-industry-
fighting-efforts-electrify-buildings; T. DiChristopher, “AGA
takes steps to counter gas bans, state opposition to pipelines”,
S&P Global, 27 January 2020, https://www.spglobal.com/
marketintelligence/en/news-insights/latest-news-headlines/
aga-takes-steps-to-counter-gas-bans-state-opposition-to-
pipelines-56763558; S. Cagle, “US gas utility funds ‘front’
consumer group to fight natural gas bans”, The Guardian (UK), 26
July 2019, https://www.theguardian.com/us-news/2019/jul/26/
us-natural-gas-ban-socalgas-berkeley.
155 S. Roth, “SoCalGas should be fined $255 million for fighting
climate action, watchdog says”, Los Angeles Times, 6 November
2020, https://www.latimes.com/environment/story/2020-11-06/
southern-california-gas-company-climate-fine-recommended;
T. Trimming, “Public Advocates Office opening brief on
SoCalGas”, 5 November 2020, https://www umentcloud.
org/documents/20402546-public-advocates-office-opening-
brief-on-socalgas. The state government of Massachusetts
blocked a local policy that banned fossil gas in new buildings
and renovations. As of early 2021 as many as nine US states had
introduced bills to stop cities from banning natural gas hook-ups
in buildings. Arizona was the first state in the country to pass
such legislation in 2020. See T. DiChristopher, “Mass. attorney
general blocks 1st East Coast gas ban”, S&P Global, 21 July 2020,
https://www.spglobal.com/marketintelligence/en/news-insights/
latest-news-headlines/mass-attorney-general-blocks-1st-east-
coast-gas-ban-59524958; T. DiChristopher, “Gas Ban Monitor:
States launch anti-ban blitz as electrification efforts grow”, S&P
Global Market Intelligence, 29 January 2021, https://www.spglobal.
com/marketintelligence/en/news-insights/latest-news-headlines/
gas-ban-monitor-states-launch-anti-ban-blitz-as-electrification-
efforts-grow-62336952; N. Groom and R. Valdmanis, “As climate
fight intensifies, U.S. states seek to block local natural-gas
bans”, Reuters, 5 March 2020, https://www.reuters.com/article/
us-usa-climatechange-naturalgas-idUSKBN20S1G8.
156 D. Ürge-Vorsatz et al., “Advances toward a net-zero global
building sector”, Annual Reviews, vol. 45 (October 2020), pp.
227-69, https://www.annualreviews.org/doi/abs/10.1146/
annurev-environ-012420-045843.
157 World Green Building Council (WGBC), “WorldGBC announces 18
new signatories to the Net Zero Carbon Buildings Commitment”,
11 December 2020, https://www.worldgbc.org/news-media/
worldgbc-announces-18-new-signatories-net-zero-carbon-
buildings-commitment; WGBC, “The Net Zero Carbon Buildings
Commitment”, https://worldgbc.org/thecommitment, viewed 22
March 2021.
158 EC, A Renovation Wave for Europe – Greening Our Buildings,
Creating Jobs, Improving Lives (Brussels: 2020), https://ec.europa.
eu/energy/sites/ener/files/eu_renovation_wave_strategy ; L.
Sunderland and M. Santini, “Filling the policy gap: Minimum energy
performance standards for European buildings” (Brussels: 2020),
https://www.raponline.org/knowledge-center/filling-the-policy-
gap-minimum-energy-performance-standards-for-european-
buildings.
159 S. Nadel and A. Hinge, Mandatory Building Performance Standards:
A Key Policy for Achieving Climate Goals (Washington, DC: 2020),
https://www.aceee.org/sites/default/files/pdfs/buildings_
standards_6.22.2020_0 ; Z. Hart, “Behind-the-scenes:
Montgomery County’s journey to building energy performance
standards”, Institute for Market Transformation (IMT), 21 April
2021, https://www.imt.org/behind-the-scenes-montgomery-
countys-journey-to-building-energy-performance-standards; IMT,
Comparison of U.S. Building Performance Standards (Washington,
DC: 2021), https://www.imt.org/wp-content/uploads/2021/01/IMT-
Comparison-of-Building-Performance-Policies-January-2021 .
160 See Policy Landscape chapter. The International Code Council
in the 2021 International Energy Code added two voluntary
appendices (residential and commercial) that require renewable
energy for 100% of the building’s energy use; see Zero Code,
“Renewable energy portions of the Zero Code added to the
2021 International Energy Conservation Code”, July 2020, http://
zero-code.org/new-model-building-code-empowers-local-
jurisdictions-to-require-zero-net-carbon-operations. In California,
new building standards came into force on 1 January that require
on-site renewable electricity generation with some allowance for
off-site equivalence; see California Energy Commission, “Energy
Commission adopts standards requiring solar systems for new
homes, first in nation”, 9 May 2018, https://www.energy.ca.gov/
news/2018-05/energy-commission-adopts-standards-requiring-
solar-systems-new-homes-first.
161 IEA, World Energy Balances 2020, op. cit. note 47.
162 Ibid.
163 Ibid.; J. Friedmann, Z. Fan and K. Tang, Low-carbon Heat Solutions
for Heavy Industry: Sources, Options, and Costs Today (New York:
October 2019), https://energypolicy.columbia.edu/sites/default/
files/file-uploads/LowCarbonHeat-CGEP_Report_100219-2_0 .
164 IEA, World Energy Balances 2020, op. cit. note 47; Friedmann, Fan
and Tang, op. cit. note 163.
165 Our World in Data, “Emissions by sector”, https://ourworldindata.
org/emissions-by-sector, viewed 17 May 2021.
166 The curtailment of economic activity due to the pandemic is
forecast to reduce heat consumption in industry by 4.2% in 2020.
IEA, The Covid-19 Crisis and Clean Energy Progress (Paris: June
2020), https://www.iea.org/reports/the-covid-19-crisis-and-clean-
energy-progress/industry#abstract; IEA, op. cit. note 5.
167 The United States is expected to record the largest drop in
industrial bioenergy consumption, followed by Brazil and the EU.
IEA, op. cit. note 5.
168 IEA, World Energy Balances 2020, op. cit. note 47.
169 IRENA Coalition for Action, Companies in Transition Towards
100% Renewables: Focus on Heating and Cooling (Abu Dhabi:
2021) https://coalition.irena.org/-/media/Files/IRENA/Agency/
Publication/2021/Feb/IRENA_Coalition_Companies_in_
Transition_towards_100_2021 .
170 IEA, Renewable Energy Market Update: Outlook for 2020 and 2021
(Paris: May 2020), https://www.iea.org/reports/renewable-
energy-market-update/technology-summaries#renewable-heat.
171 See Bioenergy section in Market and Industry chapter.
172 IEA. op. cit. note 5. China is also an important user of biomass for
heating in both buildings and industry, but this is not reflected in
current statistics due to data collection and reporting challenges.
See Bioenergy section in Market and Industry chapter.
173 IEA, Tracking Industry 2020 (Paris: June 2020), https://www.iea.
org/reports/tracking-industry-2020; IEA, op. cit. note 5.
174 IRENA Coalition for Action, op. cit. note 169.
175 Ibid.; IEA, Tracking Industry 2020, op. cit. note 173.
263
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ENDNOTES · GLOBAL OVERVIEW 01
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176 J. W. Lund and A. N. Toth, “Direct utilization of geothermal energy
2020 worldwide review”, Proceedings World Geothermal Congress
2020, Reykjavik, Iceland, April 26-May 2, 2020, https://www.
geothermal-energy.org/pdf/IGAstandard/WGC/2020/01018 .
177 Ibid.
178 IEA Solar Heating & Cooling Programme, Solar Heat Worldwide
2020 (Gleisdorf, Austria: 2020), https://www.iea-shc.org/Data/
Sites/1/publications/Solar-Heat-Worldwide-2020 .
179 Ibid.
180 BloombergNEF, BNEF Executive Factbook; Power, Transport,
Buildings and Industry, Commodities, Food and Agriculture, Capital
(London: 22 April 2020), https://data.bloomberglp.com/promo/
sites/12/678001-BNEF_2020-04-22-ExecutiveFactbook ; IEA,
Pulp and Paper Tracking Report 2020 (Paris: 2020), https://www.
iea.org/reports/pulp-and-paper#tracking-progress.
181 IEA, op. cit. note 5.
182 K. Ericsson and L. J. Nilsson, Climate Innovations in the Paper
Industry: Prospects for Decarbonisation, Reinvent Decarbonisation,
30 September 2018, https://static1.squarespace.com/
static/59f0cb986957da5faf64971e/t/5dc1acfb29bc520c15c858fc/1
572973823092/%28updated%29D2.4+Climate+innovations+in+t
he+paper+industry .
183 S. Matthis, “New biomass boiler inaugurated at Navigator’s Figueira
da Foz industrial complex”, Pulp and Paper News, 21 December
2020, https://www.pulpapernews.com/20201221/12096/new-
biomass-boiler-inaugurated-navigators-figueira-da-foz-industrial-
complex.
184 Ericsson and Nilsson, op. cit. note 182.
185 S. Matthis, “DS Smith Paper switches to green electrical
power in Croatia”, Pulp and Paper News, 13 November
2020, https://www.pulpapernews.com/20201113/11961/
ds-smith-paper-switches-green-electrical-power-croatia.
186 BloombergNEF, op. cit. note 180.
187 IRENA Coalition for Action, op. cit. note 169; BloombergNEF, op. cit.
note 180.
188 Protarget Solar Power Systems, “Orange juice from Cyprus,
produced with lots of sun and solar generated steam using
Protarget’s Concentrating Solar Thermal (CST) technology”,
https://protarget-ag.com/en/1138, viewed 17 May 2021; “Sunny
prospects for Cyprus”, CSP Focus, 26 May 2020, http://www.
cspfocus.cn/en/market/detail_3033.htm.
189 McCain Foods, “McCain Foods unveils Australia’s largest ‘behind-
the-meter’ renewable energy system”, 14 July 2020, https://www.
mccain.com/information-centre/news/mccain-foods-unveils-
australia-s-largest-behind-the-meter-renewable-energy-system.
190 U. Gupta, “SunAlpha installs 12 MW rooftop solar
for food processing”, pv magazine, 13 October 2020,
https://www.pv-magazine-india.com/2020/10/13/
sunalpha-installs-12-mw-rooftop-solar-for-food-processing.
191 Two Birds, Renewables for Mining in Africa (London: 2020),
https://www.twobirds.com/~/media/pdfs/expertise/energy-
and-utilities/2020/renewables-for-mining-in-africa ; A.
Fawthrop, “Why the mining industry must continue to embrace
renewable energy”, NS Energy, 20 March 2020, https://www.
nsenergybusiness.com/features/renewable-energy-mining-bnef.
192 Two Birds, op. cit. note 191.
193 N. Maennling and P. Toledano, The Renewable Power of the
Mine (New York: Columbia Center on Sustainable Investment:
December 2018), p. 17, https://rue.bmz.de/includes/downloads/
CCSI_2018_-_The_Renewable_Power_of_The_Mine__mr_ .
194 “Mining & Renewable energy – a greener way forward”,
Renewables Now, 24 November 2020, https://renewablesnow.com/
news/mining-renewable-energy-a-greener-way-forward-721937.
195 D. Benton, “Chile’s Zaldivar mine to operate with 100% renewable
energy”, Mining Global, 17 May 2020, https://miningglobal.com/
sustainability-1/chiles-zaldivar-mine-operate-100-renewable-
energy; Two Birds, op. cit. note 191; L. Cornish, “Renewable energy
uptake in mining gathers momentum”, Mining Review Africa, 22
May 2020, https://www.miningreview.com/energy/renewable-
energy-uptake-in-mining-gathers-momentum; Rio Tinto, “Rio
Tinto to build first solar plant in Western Australia to power iron
ore mine”, 16 February 2020, https://www.riotinto.com/news/
releases/2020/Rio-Tinto-to-build-first-solar-plant-in-Western-
Australia-to-power-iron-ore-mine; D. Mavrokefalidis, “Australian
gold mine to be decarbonised by 56MW hybrid renewable project”,
26 May 2020, https://www.energylivenews.com/2020/05/26/
australian-gold-mine-to-be-decarbonised-by-56mw-hybrid-
renewable-project; R. Warrier, “Finland’s Wärtsilä to equip 44MW
solar plant at Saudi gold mine”, Construction Week, 9 April
2020, https://www.constructionweekonline.com/projects-and-
tenders/264350-finlands-wartsila-to-equip-44mw-solar-plant-at-
saudi-gold-mine.
196 G. Parkinson, “Fortescue leads ‘stampede’ into green energy
with stunning plans for 235 gigawatts of wind and solar”,
RenewEconomy, 12 November 2020, https://reneweconomy.com.
au/fortescue-leads-stampede-into-green-energy-with-stunning-
plans-for-235-gigawatts-of-wind-and-solar-27936.
197 IEA, Energy Technology Perspectives 2020 (Paris: September 2020),
https://www.iea.org/reports/energy-technology-perspectives-2020.
198 IEA, World Energy Balances 2020, op. cit. note 47. Renewables
accounted for 0.68% of the total energy consumption in iron and
steel, chemicals and petrochemicals, and non-metallic minerals
(chemicals) together, as of 2018.
199 IEA, op. cit. note 197.
200 T. K. Blank and P. Molly, Hydrogen’s Decarbonization Impact
for Industry: Near-term Challenges and Long-term Potential
(Basalt, CO: RMI, January 2020), https://rmi.org/wp-content/
uploads/2020/01/hydrogen_insight_brief ; A. Griffin, “Hydrogen,
enabling decarbonisation in heavy industry”, HSBC, 22 April 2020,
https://www.sustainablefinance.hsbc.com/carbon-transition/
hydrogen-enabling-decarbonisation-in-heavy-industry; IRENA, op.
cit. note 62.
201 Climate Champions, “Green Hydrogen Catapult”, https://racetozero.
unfccc.int/green-hydrogen-catapult, viewed 17 May 2021
202 IRENA, op. cit. note 62.
203 Ibid.
204 Ibid.
205 Ibid.
206 Australian Renewable Energy Agency, ENGIE-YARA Renewable
Hydrogen and Ammonia Deployment in Pilbara (Canberra: October
2020), https://arena.gov.au/assets/2020/11/engie-yara-renewable-
hydrogen-and-ammonia-deployment-in-pilbara .
207 Green Car Congress, “Nouryon-led consortium wins €11M EU
backing for green hydrogen project”, 23 January 2020, https://
www.greencarcongress.com/2020/01/20200123-nouryon.html.
208 “BioBTX takes significant step towards a commercial
plant”, Bioplastics Magazine, 21 January 2020, https://www.
bioplasticsmagazine.com/en/news/meldungen/20200121-BioBTX-
takes-significant-step-towards-a-commercial-plant.php.
209 IRENA, op. cit. note 62.
210 Ibid.
211 Ibid.
212 World Steel Association, 2020 World Steel in Figures, 30 April 2020,
https://www.worldsteel.org/en/dam/jcr:f7982217-cfde-4fdc-8ba0-795
ed807f513/World%2520Steel%2520in%2520Figures%25202020i .
213 M. Pooler, “‘Green steel’: the race to clean up one of the world’s
dirtiest industries”, Financial Times, 15 February 2021, https://
www.ft.com/content/46d4727c-761d-43ee-8084-ee46edba491a;
Bocconi Students Investment Club, “Green steel – the next largest
industrial investment?” https://bsic.it/green-steel-the-next-largest-
industrial-investment, viewed 17 May 2021.
214 “Sweden’s HYBRIT starts operations at pilot plant for fossil-free
steel”, Reuters, 31 August 2020, https://www.reuters.com/article/
us-sweden-steel-hydrogen-idUSKBN25R1PI.
215 LKAB, “LKAB produces the world’s first iron ore pellets with
fossil-free fuels”, 2 November 2020, https://www.lkab.com/en/
news-room/news/lkab-produces-the-worlds-first-iron-ore-pellets-
with-fossil-free-fuels.
216 L. Paulsson, J. Starn and E. Spence, “Spotify billionaire Ek
among investors in green steel startup”, Bloomberg, 23 February
2021, https://www.bloomberg.com/news/articles/2021-02-23/
hydrogen-to-power-large-green-steel-plant-in-sweden-from-2024.
217 L. Varriale, “Germany’s Thyssenkrupp to build DRI plant run on
hydrogen for green steel production”, S&P Global Platts, 28 August
2020, https://www.spglobal.com/platts/en/market-insights/latest-
news/metals/082820-germanys-thyssenkrupp-to-build-dri-plant-
run-on-hydrogen-for-green-steel-production.
264
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01018
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01018
https://www.iea-shc.org/Data/Sites/1/publications/Solar-Heat-Worldwide-2020
https://www.iea-shc.org/Data/Sites/1/publications/Solar-Heat-Worldwide-2020
https://data.bloomberglp.com/promo/sites/12/678001-BNEF_2020-04-22-ExecutiveFactbook
https://data.bloomberglp.com/promo/sites/12/678001-BNEF_2020-04-22-ExecutiveFactbook
https://www.iea.org/reports/pulp-and-paper#tracking-progress
https://www.iea.org/reports/pulp-and-paper#tracking-progress
https://static1.squarespace.com/static/59f0cb986957da5faf64971e/t/5dc1acfb29bc520c15c858fc/1572973823092/%28updated%29D2.4+Climate+innovations+in+the+paper+industry
https://static1.squarespace.com/static/59f0cb986957da5faf64971e/t/5dc1acfb29bc520c15c858fc/1572973823092/%28updated%29D2.4+Climate+innovations+in+the+paper+industry
https://static1.squarespace.com/static/59f0cb986957da5faf64971e/t/5dc1acfb29bc520c15c858fc/1572973823092/%28updated%29D2.4+Climate+innovations+in+the+paper+industry
https://static1.squarespace.com/static/59f0cb986957da5faf64971e/t/5dc1acfb29bc520c15c858fc/1572973823092/%28updated%29D2.4+Climate+innovations+in+the+paper+industry
https://www.pulpapernews.com/20201221/12096/new-biomass-boiler-inaugurated-navigators-figueira-da-foz-industrial-complex
https://www.pulpapernews.com/20201221/12096/new-biomass-boiler-inaugurated-navigators-figueira-da-foz-industrial-complex
https://www.pulpapernews.com/20201221/12096/new-biomass-boiler-inaugurated-navigators-figueira-da-foz-industrial-complex
https://www.pulpapernews.com/20201113/11961/ds-smith-paper-switches-green-electrical-power-croatia
https://www.pulpapernews.com/20201113/11961/ds-smith-paper-switches-green-electrical-power-croatia
https://protarget-ag.com/en/1138
http://www.cspfocus.cn/en/market/detail_3033.htm
http://www.cspfocus.cn/en/market/detail_3033.htm
https://www.mccain.com/information-centre/news/mccain-foods-unveils-australia-s-largest-behind-the-meter-renewable-energy-system
https://www.mccain.com/information-centre/news/mccain-foods-unveils-australia-s-largest-behind-the-meter-renewable-energy-system
https://www.mccain.com/information-centre/news/mccain-foods-unveils-australia-s-largest-behind-the-meter-renewable-energy-system
https://www.twobirds.com/~/media/pdfs/expertise/energy-and-utilities/2020/renewables-for-mining-in-africa
https://www.twobirds.com/~/media/pdfs/expertise/energy-and-utilities/2020/renewables-for-mining-in-africa
https://www.nsenergybusiness.com/features/renewable-energy-mining-bnef
https://www.nsenergybusiness.com/features/renewable-energy-mining-bnef
https://rue.bmz.de/includes/downloads/CCSI_2018_-_The_Renewable_Power_of_The_Mine__mr_
https://rue.bmz.de/includes/downloads/CCSI_2018_-_The_Renewable_Power_of_The_Mine__mr_
https://renewablesnow.com/news/mining-renewable-energy-a-greener-way-forward-721937
https://renewablesnow.com/news/mining-renewable-energy-a-greener-way-forward-721937
https://miningglobal.com/sustainability-1/chiles-zaldivar-mine-operate-100-renewable-energy
https://miningglobal.com/sustainability-1/chiles-zaldivar-mine-operate-100-renewable-energy
https://miningglobal.com/sustainability-1/chiles-zaldivar-mine-operate-100-renewable-energy
https://www.miningreview.com/energy/renewable-energy-uptake-in-mining-gathers-momentum
https://www.miningreview.com/energy/renewable-energy-uptake-in-mining-gathers-momentum
https://www.riotinto.com/news/releases/2020/Rio-Tinto-to-build-first-solar-plant-in-Western-Australia-to-power-iron-ore-mine
https://www.riotinto.com/news/releases/2020/Rio-Tinto-to-build-first-solar-plant-in-Western-Australia-to-power-iron-ore-mine
https://www.riotinto.com/news/releases/2020/Rio-Tinto-to-build-first-solar-plant-in-Western-Australia-to-power-iron-ore-mine
Australian gold mine to be decarbonised by 56MW hybrid renewable project
Australian gold mine to be decarbonised by 56MW hybrid renewable project
Australian gold mine to be decarbonised by 56MW hybrid renewable project
https://www.constructionweekonline.com/projects-and-tenders/264350-finlands-wartsila-to-equip-44mw-solar-plant-at-saudi-gold-mine
https://www.constructionweekonline.com/projects-and-tenders/264350-finlands-wartsila-to-equip-44mw-solar-plant-at-saudi-gold-mine
https://www.constructionweekonline.com/projects-and-tenders/264350-finlands-wartsila-to-equip-44mw-solar-plant-at-saudi-gold-mine
Fortescue leads “stampede” into green energy with stunning plans for 235 gigawatts of wind and solar
Fortescue leads “stampede” into green energy with stunning plans for 235 gigawatts of wind and solar
Fortescue leads “stampede” into green energy with stunning plans for 235 gigawatts of wind and solar
https://www.iea.org/reports/energy-technology-perspectives-2020
https://rmi.org/wp-content/uploads/2020/01/hydrogen_insight_brief
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https://www.sustainablefinance.hsbc.com/carbon-transition/hydrogen-enabling-decarbonisation-in-heavy-industry
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https://racetozero.unfccc.int/green-hydrogen-catapult
https://racetozero.unfccc.int/green-hydrogen-catapult
https://arena.gov.au/assets/2020/11/engie-yara-renewable-hydrogen-and-ammonia-deployment-in-pilbara
https://arena.gov.au/assets/2020/11/engie-yara-renewable-hydrogen-and-ammonia-deployment-in-pilbara
https://www.greencarcongress.com/2020/01/20200123-nouryon.html
https://www.greencarcongress.com/2020/01/20200123-nouryon.html
https://www.bioplasticsmagazine.com/en/news/meldungen/20200121-BioBTX-takes-significant-step-towards-a-commercial-plant.php
https://www.bioplasticsmagazine.com/en/news/meldungen/20200121-BioBTX-takes-significant-step-towards-a-commercial-plant.php
https://www.bioplasticsmagazine.com/en/news/meldungen/20200121-BioBTX-takes-significant-step-towards-a-commercial-plant.php
https://www.worldsteel.org/en/dam/jcr:f7982217-cfde-4fdc-8ba0-795ed807f513/World%2520Steel%2520in%2520Figures%25202020i
https://www.ft.com/content/46d4727c-761d-43ee-8084-ee46edba491a
https://www.ft.com/content/46d4727c-761d-43ee-8084-ee46edba491a
https://www.reuters.com/article/us-sweden-steel-hydrogen-idUSKBN25R1PI
https://www.reuters.com/article/us-sweden-steel-hydrogen-idUSKBN25R1PI
https://www.lkab.com/en/news-room/news/lkab-produces-the-worlds-first-iron-ore-pellets-with-fossil-free-fuels
https://www.lkab.com/en/news-room/news/lkab-produces-the-worlds-first-iron-ore-pellets-with-fossil-free-fuels
https://www.lkab.com/en/news-room/news/lkab-produces-the-worlds-first-iron-ore-pellets-with-fossil-free-fuels
https://www.bloomberg.com/news/articles/2021-02-23/hydrogen-to-power-large-green-steel-plant-in-sweden-from-2024
https://www.bloomberg.com/news/articles/2021-02-23/hydrogen-to-power-large-green-steel-plant-in-sweden-from-2024
https://www.spglobal.com/platts/en/market-insights/latest-news/metals/082820-germanys-thyssenkrupp-to-build-dri-plant-run-on-hydrogen-for-green-steel-production
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ENDNOTES · GLOBAL OVERVIEW 01
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218 IRENA, op. cit. note 62.
219 Ibid.
220 Ibid.
221 Ibid.
222 M. Mace, “Manufacturers aim for carbon-neutral cement by
2050”, Edie, 1 September 2020, https://www.edie.net/news/6/
Manufacturers-aim-for-carbon-neutral-cement-by-2050;
“UK concrete and cement industry claims it can ‘go beyond
net-zero’ by 2050”, Edie, 6 October 2020, https://www.edie.
net/news/6/UK-concrete-and-cement-industry-claims-it-
can–go-beyond-net-zero–by-2050; “Dominican Republic
cement industry targets 33% carbon reduction by 2030”,
Cemnet, 2 December 2020, https://www.cemnet.com/News/
story/169963/dominican-republic-cement-industry-targets-33-
carbon-reduction-by-2030.html; CEMBUREAU, “2050 Carbon
Neutrality Roadmap”, 12 May 2020, https://cembureau.eu/library/
reports/2050-carbon-neutrality-roadmap.
223 R. Leese, “Putting our energies into carbon-cutting research”, MPA
UK Concrete, 2 April 2020, https://www.thisisukconcrete.co.uk/
Perspectives/Putting-our-energies-into-carbon-cutting-research.aspx.
224 S. George, “Major renewable hydrogen demo project comes online
at Welsh cement plant”, Industrial News, 11 February 2021, https://
industrialnews.co.uk/major-renewable-hydrogen-demo-project-
comes-online-at-welsh-cement-plant.
225 A. Gillod, Climate Chance, presentation at “Mobilités durables –
Accélérer et réussir” conference, 15 January 2021.
226 International Civil Aviation Organization (ICAO), “2020 passenger
totals drop 60 percent as COVID-19 assault on international
mobility continues”, 15 January 2021, https://www.icao.int/
Newsroom/Pages/2020-passenger-totals-drop-60-percent-as-
COVID19-assault-on-international-mobility-continues.aspx; rail
from IEA, “Long-distance transport”, in Energy Efficiency 2020
(Paris: 2020), https://www.iea.org/reports/energy-efficiency-2020/
long-distance-transport; United Nations Conference on Trade
and Development, “COVID-19 cuts global maritime trade,
transforms industry”, 12 November 2020, https://unctad.org/news/
covid-19-cuts-global-maritime-trade-transforms-industry.
227 Gillod, op. cit. note 225; IEA, “Urban transport”, in Energy
Efficiency 2020 (Paris: 2020), https://www.iea.org/reports/
energy-efficiency-2020/urban-transport#abstract. In many parts
of Asia, especially China, public transport was more or less back to
normal by the second half of 2020, from SLOCAT Partnership on
Sustainable, Low Carbon, “COVID-19 and mobility – an updated
analysis of regional impacts”, 28 October 2020, https://slocat.net/
covid-19-and-mobility-update.
228 IEA, Global EV Outlook 2021 (Paris: 2021), https://iea.blob.core.
windows.net/assets/ed5f4484-f556-4110-8c5c-4ede8bcba637/
GlobalEVOutlook2021 ; 14% from L. Cozzi and A. Petropoulos,
“Carbon emissions fell across all sectors in 2020 except for one –
SUVs”, IEA, 15 January 2021, https://www.iea.org/commentaries/
carbon-emissions-fell-across-all-sectors-in-2020-except-for-one-
suvs. Also, many car dealerships closed in major markets such as
China, Europe and the United States, from T. Furcher et al., “How
consumers’ behavior in car buying and mobility is changing amid
COVID-19”, McKinsey & Company, 22 September 2020, https://www.
mckinsey.com/business-functions/marketing-and-sales/our-insights/
how-consumers-behavior-in-car-buying-and-mobility-changes-amid-
covid-19. See also: ZSW, “Data Service Renewable Energies”, https://
www.zsw-bw.de/en/media-center/data-service.html, viewed 27 May
2021; R. Irle, “Global plug-in vehicle sales reached over 3,2 million
in 2020”, EV-Volumes, www.ev-volumes.com, viewed 27 May 2021.
229 As of 2020, around 25% of all two-wheelers on the road were
electric, over 95% of which were in China, and most of the rest
were in India and South-East Asian countries. Sales of electric
two-/three-wheelers increased 30% in Europe in 2020. IEA, op. cit.
note 228; IEA, Electric Vehicles (Paris: 2020), https://www.iea.org/
reports/electric-vehicles.
230 On average, SUVs consume over 20% more energy than a mid-
sized passenger car for the same distance travelled. Cozzi and
Petropoulos, op. cit. note 228.
231 Demand fell particularly during the second quarter of 2020, as
the sector was heavily impacted by mobility restrictions linked to
Covid-19. It had nearly rebounded to pre-pandemic levels by mid-
2021, and is expected to return to 2019 levels by the end of 2021.
IEA, “Oil”, in Global Energy Review 2021 (Paris: 2021), https://www.
iea.org/reports/global-energy-review-2021/oil.
232 Ibid.
233 Based on IEA, World Energy Balances 2020, op. cit. note 47
234 Ibid.
235 Numbers may not add up to 100% due to rounding. IEA, World Energy
Balances 2020, op. cit. note 47; IEA, “Transport”, in Renewables 2019
(Paris: 2019), https://www.iea.org/reports/renewables-2019/transport.
236 Based on IEA, World Energy Balances 2020, op. cit. note 47
237 Larger size of vehicles leads to higher energy consumption and
emissions, from International Transport Forum (ITF), Lightening
Up: How Less Heavy Vehicles Can Help Cut CO2 Emissions (Paris:
2017), p. 7, https://www.itf-oecd.org/sites/default/files/docs/
less-heavy-vehicles-cut-co2-emissions . See also: L. Cozzi
and A. Petropoulos, “Growing preference for SUVs challenges
emissions reductions in passenger car markets”, IEA, 15 October
2020, https://www.iea.org/commentaries/growing-preference-
for-suvs-challenges-emissions-reductions-in-passenger-car-
market; IEA, “Energy Efficiency Indicators database (2020 edition)
– extended version” (Paris: 2020), http://data.iea.org/payment/
products/120-energy-efficiency-indicators-2018-edition.aspx;
IEA, World Energy Balances 2020, op. cit. note 47; IEA, Energy
Efficiency 2019: Analysis and Outlook to 2040 (Paris: 2019),
https://www.iea.org/efficiency2019.
238 SLOCAT, “Transport and Climate Change Global Status Report
(TCC-GSR): Tracking transport emissions trends, raising transport
policy ambition”, December 2018, https://slocat.net/2011-2;
SLOCAT, Transport and Climate Change Global Status Report 2018
(Brussels: 2018), p. 2, http://www.slocat.net/wp-content/uploads/
legacy/slocat_transport-and-climate-change-2018-web .
239 Energy intensity has not decreased as much for freight due
to vehicle attributes, payloads and lack of supportive policy
frameworks to incentivise improvements. SLOCAT, Transport and
Climate Change Global Status Report 2018, op. cit. note 238, p. 2.
240 This global increase has occurred even as transport emissions in
some regions (such as the EU and the United States) have fallen.
Whereas total CO2 emissions in the EU decreased 20% between
1990 and 2017, emissions from the transport sector increased
27%, from ITF, “Is low-carbon road freight possible?” 6 December
2018, https://www.itf-oecd.org/low-carbon-road-freight.
Similarly, US transport sector emissions surpassed those of the
power sector in 2017, from J. Runyon, “6 key trends in sustainable
and renewable energy”, Renewable Energy World, 15 February
2019, https://www.renewableenergyworld.com/baseload/6-key-
trends-in-sustainable-and-renewable-energy/#gref. L. Cozzi
and A. Petropoulos, op. cit. note 228. 2018 emissions and 2020
emissions drop estimate from: ITF, ITF Transport Outlook 2021
(Paris: 2021), p. 24, https://read.oecd-ilibrary.org/transport/
itf-transport-outlook-2021_16826a30-en#page24.
241 Numbers may not add up to 100% due to rounding. Another 2% is
attributed to pipeline and non-specified transport. IEA, “Transport
sector CO2 emissions by mode in the Sustainable Development
Scenario, 2000-2030”, 22 November 2019, https://www.iea.org/
data-and-statistics/charts/transport-sector-co2-emissions-by-
mode-in-the-sustainable-development-scenario-2000-2030.
242 Plug-in hybrids differ from simple hybrid vehicles, as the latter use
electric energy produced only by braking or through the vehicle’s
internal combustion engine. Therefore, only plug-in hybrid EVs
allow for the use of electricity from renewable sources. Although
not an avenue for increased penetration of renewable electricity,
hybrid vehicles contribute to reduced fuel demand and remain far
more numerous than EVs. Electro-fuels, also known as e-fuels,
are synthetic fuels that do not chemically differ from conventional
fuels such as diesel or petrol, generated in procedures known as
power-to-liquids and power-to-gas. Renewable electro-fuels are
generated exclusively from electricity from renewable sources.
See Verband der Automobilindustrie, “Synthetic fuels – power
for the future”, https://www.vda.de/en/topics/environment-and-
climate/e-fuels/synthetic-fuels.html, viewed 1 May 2019, and N.
Aldag, “Role for e-fuels in EU transport?” Sunfire, 12 January 2018,
https://www.transportenvironment.org/sites/te/files/Industry%20
perspectives%20on%20the%20future%20development%20of%20
electrofuels%2C%20Nils%20Aldag . See also IRENA, IEA and
REN21, op. cit. note 83, Figure 3.4, p. 41.
243 See Bioenergy section in Market and Industry chapter. Based on
national biofuels data as referenced below; biofuels supplemented
by data from IEA, Oil 2021 (Paris: March 2021), https://www.iea.org/
reports/oil-2021.
265
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https://www.edie.net/news/6/Manufacturers-aim-for-carbon-neutral-cement-by-2050
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Major renewable hydrogen demo project comes online at Welsh cement plant
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https://www.iea.org/reports/renewables-2019/transport
https://www.itf-oecd.org/sites/default/files/docs/less-heavy-vehicles-cut-co2-emissions
https://www.itf-oecd.org/sites/default/files/docs/less-heavy-vehicles-cut-co2-emissions
https://www.iea.org/commentaries/growing-preference-for-suvs-challenges-emissions-reductions-in-passenger-car-market
https://www.iea.org/commentaries/growing-preference-for-suvs-challenges-emissions-reductions-in-passenger-car-market
https://www.iea.org/commentaries/growing-preference-for-suvs-challenges-emissions-reductions-in-passenger-car-market
http://data.iea.org/payment/products/120-energy-efficiency-indicators-2018-edition.aspx
http://data.iea.org/payment/products/120-energy-efficiency-indicators-2018-edition.aspx
https://www.iea.org/efficiency2019
https://slocat.net/2011-2
http://www.slocat.net/wp-content/uploads/legacy/slocat_transport-and-climate-change-2018-web
http://www.slocat.net/wp-content/uploads/legacy/slocat_transport-and-climate-change-2018-web
https://www.itf-oecd.org/low-carbon-road-freight
https://read.oecd-ilibrary.org/transport/itf-transport-outlook-2021_16826a30-en#page24
https://read.oecd-ilibrary.org/transport/itf-transport-outlook-2021_16826a30-en#page24
https://www.iea.org/data-and-statistics/charts/transport-sector-co2-emissions-by-mode-in-the-sustainable-development-scenario-2000-2030
https://www.iea.org/data-and-statistics/charts/transport-sector-co2-emissions-by-mode-in-the-sustainable-development-scenario-2000-2030
https://www.iea.org/data-and-statistics/charts/transport-sector-co2-emissions-by-mode-in-the-sustainable-development-scenario-2000-2030
https://www.vda.de/en/topics/environment-and-climate/e-fuels/synthetic-fuels.html
https://www.vda.de/en/topics/environment-and-climate/e-fuels/synthetic-fuels.html
https://www.transportenvironment.org/sites/te/files/Industry%20perspectives%20on%20the%20future%20development%20of%20electrofuels%2C%20Nils%20Aldag
https://www.transportenvironment.org/sites/te/files/Industry%20perspectives%20on%20the%20future%20development%20of%20electrofuels%2C%20Nils%20Aldag
https://www.transportenvironment.org/sites/te/files/Industry%20perspectives%20on%20the%20future%20development%20of%20electrofuels%2C%20Nils%20Aldag
https://www.iea.org/reports/oil-2021
https://www.iea.org/reports/oil-2021
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244 Ibid.
245 Renewable diesel is also called hydrogenated vegetable oil (HVO)
or hydrogenated esters of fatty acids (HEFA). This is produced
by taking vegetable oils and other bio-based oils and liquids,
including waste materials such as used cooking oil, and treating
them with hydrogen, which removes the oxygen and produces
a hydrocarbon which can be refined to a product which has fuel
qualities equivalent to fossil-based diesel. The refining process
also produced bio-based LPG and can be tuned to produce other
fuels including biojet. Renewable diesel can be used mixed in any
proportion with fossil diesel or on its own. Production estimate
is based on analysis of existing and new capacity as shown in
Biofuels Digest, “50 renewable diesel projects and the technologies
behind them”, 8 February 2021, https://www.biofuelsdigest.com/
bdigest/2021/02/08/50-renewable-diesel-projects-and-the-
technologies-behind-them, and research on specific plant outputs.
See Bioenergy industry section in Market and Industry chapter for
more detailed information.
246 IEA, World Energy Balances 2020, op. cit. note 47.
247 For example, in the EU where the renewable share of electricity
is higher than in other most regions, EV emissions over the entire
vehicle life cycle were estimated to be 17-30% lower than those of
petrol or diesel vehicles, from European Environment Agency, “EEA
report confirms: Electric cars are better for climate and air quality”,
22 November 2018, https://www.eea.europa.eu/highlights/
eea-report-confirms-electric-cars.
248 The estimation of EVs being more efficient than conventional
vehicles can be attributed in part to the fact that the energy
losses of converting primary energy to electricity (as well as
transport and distribution losses) are often underestimated, from
IEA, Global EV Outlook 2020 (Paris: 2020), https://www.iea.org/
reports/global-ev-outlook-2020.
249 See, for example: T. Casey, “100% renewable energy for 2,700
new EV fast charging stations in USA”, CleanTechnica, 31 July
2020, https://cleantechnica.com/2020/07/31/100-renewable-
energy-for-2700-new-ev-fast-charging-stations-in-usa; K.
Silverstein, “Solar-powered electric vehicle charging stations are
just around the corner”, Forbes, 10 February 2020, https://www.
forbes.com/sites/kensilverstein/2020/02/10/solar-powered-
electric-vehicle-charging-stations-are-just-around-the-corner;
J. Butler, “New electric boat charging stations and networks for
Norway, Venice”, Plugboats, 27 April 2021, https://plugboats.com/
new-electric-boat-charging-networks-norway-venice.
250 IEA, Hydrogen (Paris: 2021), https://www.iea.org/reports/
hydrogen; Argus, “China’s Sinopec outlines hydrogen
aspirations”, 24 February 2021, https://www.argusmedia.com/en/
news/2189848-chinas-sinopec-outlines-hydrogen-aspirations; J.
Jolly, “Hydrogen fuel bubbles up the agenda as investments rocket”,
The Guardian (UK), 28 June 2020, https://www.theguardian.com/
environment/2020/jun/28/hydrogen-fuel-bubbles-up-the-agenda-
as-investments-rocket; IEA, “Hydrogen”, https://www.iea.org/
fuels-and-technologies/hydrogen, viewed 24 May 2021.
251 Sustainable Mobility for All, Global Roadmap of Action: Toward
Sustainable Mobility (2019). http://pubdocs.worldbank.org/
en/350451571411004650/Global-Roadmap-of-Action-Toward-
Sustainable-Mobility ; IRENA, NDCs in 2020: Advancing
Renewables in the Power Sector and Beyond (Abu Dhabi:
2020), https://www.irena.org/-/media/Files/IRENA/Agency/
Publication/2020/Dec/IRENA_NDCs_in_2020 ; IEA,
Tracking Transport (Paris: 2020), https://www.iea.org/reports/
tracking-transport-2020; Transport and Environment, Draft
National Energy and Climate Plans Transport Ranking (Brussels:
2019), https://www.transportenvironment.org/sites/te/files/
publications/2020_06_Draft_NECP_transport_analysis_final .
252 Based on first-generation NDCs. ITF, “How transport CO2 reduction
pledges fall short”, 20 November 2018, https://www.itf-oecd.org/
co2-reduction-pledges.
253 Based on REN21 research on NDCs, from REN21 Policy Database.
See GSR 2021 Data Pack, available at www.ren21.net/gsr-2021.
254 REN21 op. cit. note 43.
255 Despite the necessary role that renewable energy would play
in decarbonising the transport sector, many adaptations of the
ASI framework have failed to include renewables or to mention
the source of energy under the improve section, focusing only
on energy efficiency. See improved ASI framework: Figure
60 in REN21, Renewables 2020 Global Status Report (Paris:
2020), https://www.ren21.net/gsr-2020/chapters/chapter_07/
chapter_07; Figure 2.1 in REN21 and FIA Foundation, Renewable
Energy Pathways in Road Transport (London: November 2020),
p. 17, https://www.ren21.net/wp-content/uploads/2019/05/
REN21_FIA-Fdn_Renewable-Energy-Pathways_FINAL ; H.E.
Murdock, “Decarbonising the transport sector with renewables
requires urgent action”, 18 November 2020, https://www.ren21.
net/decarbonise-transport-sector-2020; SLOCAT, Transport and
Climate Change Global Status Report 2018, op. cit. note 238.
256 LDVs represent about 88.7% of the transport energy demand
among passenger vehicles (excluding freight), the remainder
from buses (8%) and 2- and 3-wheelers (3.3%). US EIA,
“Transportation sector passenger transport and energy
consumption by region and mode”, in International Energy Outlook
2019 (Washington, DC: 2019), https://www.eia.gov/outlooks/
aeo/data/browser/#/?id=50-IEO2019®ion=0-0&cases=
Reference&start=2010&end=2020&f=A&linechart=Refere
nce-d080819.2-50-IEO2019&sourcekey=0.
257 Data from 2018 (latest available). IEA, World Energy Balances 2020,
op. cit. note 47.
258 See Policy Landscape chapter, and Reference Table R8 in GSR
2021 Data Pack, www.ren21.net/gsr-2021.
259 C. Huizenga, personal communication with REN21, 13 April 2020.
260 Irle, op. cit. note 228; M. Gorner and L. Paoli, “How
global electric car sales defied Covid-19 in 2020”, IEA,
28 January 2021, https://www.iea.org/commentaries/
how-global-electric-car-sales-defied-covid-19-in-2020.
261 Austria and Japan provide incentives to EV owners when they use
renewable electricity for charging, while Germany offers support for
charging infrastructure using renewable electricity. Klimaaktiv, op.
cit. note 68; BMVI, op. cit. note 68; “Japan to offer up to ¥800,000 in
subsidies for electric vehicles”, op. cit. note 68. Previously, a policy
linking renewables and EVs was in place in Luxembourg, but it was
no longer in place as of 2017.
262 See Policy Landscape chapter, and data for Figure 15 in GSR 2021
Data Pack, www.ren21.net/gsr-2021.
263 See Policy Landscape chapter, and Reference Table R8 in GSR
2021 Data Pack, www.ren21.net/gsr-2021. These targets primarily
incentivise increased EV uptake. However, while not a full ban
on internal combustion engine vehicles, restrictions on vehicles
using fossil fuels also have the potential to stimulate interest in
biogas vehicles that result in fewer emissions, as well as interest
in increased biofuel use in hybrid vehicles, as a major part of a
transition towards complete electrification where bans on internal
combustion engine vehicles are envisioned. For example, hybrid
vehicles are still allowed to enter the city centre of Madrid (Spain),
which has put in place bans on petrol and diesel cars registered
before 2000 and 2006, respectively, from J. Porter, “Madrid’s ban
on polluting vehicles cuts traffic by nearly 32 percent in some
areas”, The Verge, 3 December 2018, https://www.theverge.
com/2018/12/3/18123561/vehicle-emissions-pollution-ban-
madrid-spain-traffic-decrease. Increased interest in biogas, for
example in the UK, from K. Dickinson, “Waitrose to run HGV fleet
on biomethane”, Resource, 30 July 2018, https://resource.co/
article/waitrose-run-hgv-fleet-biomethane-12768; A. Sherrard,
“Biomethane reaches 91% share in expansive Swedish vehicle
gas market”, Bioenergy International, 22 February 2019, https://
bioenergyinternational.com/markets-finance/biomethane-reaches-
91-share-in-expansive-swedish-vehicle-gas-market; biofuels in
hybrid vehicles from R. Ocone, “Does the 2040 ban on new petrol
and diesel cars mean the death of biofuels?” The Conversation, 30
July 2017, https://theconversation.com/does-the-2040-ban-on-new-
petrol-and-diesel-cars-mean-the-death-of-biofuels-81765.
264 However, in many cases, low-emission zones mainly affect older
diesel vehicles rather than entirely banning fossil fuel vehicles.
REN21, op. cit. note 43.
265 General Motors has committed to phase out gas and diesel
vehicles worldwide by 2035 and plans to become carbon-neutral
by 2040, from E. Hannon, “General Motors says it will stop making
gas-powered vehicles by 2035”, Slate, 29 January 2021, https://
slate.com/news-and-politics/2021/01/general-motors-gm-
zero-emission-gas-powered-vehicles.html, and from “General
Motors announces plan for all-electric lineup by 2035”, The
Guardian (UK), 28 January 2021, https://www.theguardian.com/
environment/2021/jan/28/gm-electric-vehicles-cars-gas-diesel.
Nissan aims for all new vehicles to be electric in key markets by
early 2030s, from Nissan, “Nissan sets carbon neutral goal for
2050”, 27 January 2021, https://global.nissannews.com/en/releases/
266
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.eea.europa.eu/highlights/eea-report-confirms-electric-cars
https://www.eea.europa.eu/highlights/eea-report-confirms-electric-cars
https://www.iea.org/reports/global-ev-outlook-2020
https://www.iea.org/reports/global-ev-outlook-2020
100% Renewable Energy For 2,700 New EV Fast Charging Stations In USA
100% Renewable Energy For 2,700 New EV Fast Charging Stations In USA
https://www.forbes.com/sites/kensilverstein/2020/02/10/solar-powered-electric-vehicle-charging-stations-are-just-around-the-corner
https://www.forbes.com/sites/kensilverstein/2020/02/10/solar-powered-electric-vehicle-charging-stations-are-just-around-the-corner
https://www.forbes.com/sites/kensilverstein/2020/02/10/solar-powered-electric-vehicle-charging-stations-are-just-around-the-corner
New electric boat charging stations and networks for Norway, Venice
New electric boat charging stations and networks for Norway, Venice
https://www.iea.org/reports/hydrogen
https://www.iea.org/reports/hydrogen
https://www.argusmedia.com/en/news/2189848-chinas-sinopec-outlines-hydrogen-aspirations
https://www.argusmedia.com/en/news/2189848-chinas-sinopec-outlines-hydrogen-aspirations
https://www.theguardian.com/environment/2020/jun/28/hydrogen-fuel-bubbles-up-the-agenda-as-investments-rocket
https://www.theguardian.com/environment/2020/jun/28/hydrogen-fuel-bubbles-up-the-agenda-as-investments-rocket
https://www.theguardian.com/environment/2020/jun/28/hydrogen-fuel-bubbles-up-the-agenda-as-investments-rocket
https://www.iea.org/fuels-and-technologies/hydrogen
https://www.iea.org/fuels-and-technologies/hydrogen
http://pubdocs.worldbank.org/en/350451571411004650/Global-Roadmap-of-Action-Toward-Sustainable-Mobility
http://pubdocs.worldbank.org/en/350451571411004650/Global-Roadmap-of-Action-Toward-Sustainable-Mobility
http://pubdocs.worldbank.org/en/350451571411004650/Global-Roadmap-of-Action-Toward-Sustainable-Mobility
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Dec/IRENA_NDCs_in_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Dec/IRENA_NDCs_in_2020
https://www.iea.org/reports/tracking-transport-2020
https://www.iea.org/reports/tracking-transport-2020
https://www.transportenvironment.org/sites/te/files/publications/2020_06_Draft_NECP_transport_analysis_final
https://www.transportenvironment.org/sites/te/files/publications/2020_06_Draft_NECP_transport_analysis_final
https://www.itf-oecd.org/co2-reduction-pledges
https://www.itf-oecd.org/co2-reduction-pledges
http://www.ren21.net/gsr-2021
https://www.ren21.net/gsr-2020/chapters/chapter_07/chapter_07
https://www.ren21.net/gsr-2020/chapters/chapter_07/chapter_07
https://www.ren21.net/wp-content/uploads/2019/05/REN21_FIA-Fdn_Renewable-Energy-Pathways_FINAL
https://www.ren21.net/wp-content/uploads/2019/05/REN21_FIA-Fdn_Renewable-Energy-Pathways_FINAL
Decarbonising the Transport Sector with Renewables Requires Urgent Action
Decarbonising the Transport Sector with Renewables Requires Urgent Action
https://www.eia.gov/outlooks/aeo/data/browser/#/?id=50-IEO2019®ion=0-0&cases=Reference&start=2010&end=2020&f=A&linechart=Reference-d080819.2-50-IEO2019&sourcekey=0
https://www.eia.gov/outlooks/aeo/data/browser/#/?id=50-IEO2019®ion=0-0&cases=Reference&start=2010&end=2020&f=A&linechart=Reference-d080819.2-50-IEO2019&sourcekey=0
https://www.eia.gov/outlooks/aeo/data/browser/#/?id=50-IEO2019®ion=0-0&cases=Reference&start=2010&end=2020&f=A&linechart=Reference-d080819.2-50-IEO2019&sourcekey=0
https://www.eia.gov/outlooks/aeo/data/browser/#/?id=50-IEO2019®ion=0-0&cases=Reference&start=2010&end=2020&f=A&linechart=Reference-d080819.2-50-IEO2019&sourcekey=0
http://www.ren21.net/gsr-2021
https://www.iea.org/commentaries/how-global-electric-car-sales-defied-covid-19-in-2020
https://www.iea.org/commentaries/how-global-electric-car-sales-defied-covid-19-in-2020
http://www.ren21.net/gsr-2021
http://www.ren21.net/gsr-2021
https://www.theverge.com/2018/12/3/18123561/vehicle-emissions-pollution-ban-madrid-spain-traffic-decrease
https://www.theverge.com/2018/12/3/18123561/vehicle-emissions-pollution-ban-madrid-spain-traffic-decrease
https://www.theverge.com/2018/12/3/18123561/vehicle-emissions-pollution-ban-madrid-spain-traffic-decrease
https://resource.co/article/waitrose-run-hgv-fleet-biomethane-12768
https://resource.co/article/waitrose-run-hgv-fleet-biomethane-12768
https://bioenergyinternational.com/markets-finance/biomethane-reaches-91-share-in-expansive-swedish-vehicle-gas-market
https://bioenergyinternational.com/markets-finance/biomethane-reaches-91-share-in-expansive-swedish-vehicle-gas-market
https://bioenergyinternational.com/markets-finance/biomethane-reaches-91-share-in-expansive-swedish-vehicle-gas-market
https://theconversation.com/does-the-2040-ban-on-new-petrol-and-diesel-cars-mean-the-death-of-biofuels-81765
https://theconversation.com/does-the-2040-ban-on-new-petrol-and-diesel-cars-mean-the-death-of-biofuels-81765
https://slate.com/news-and-politics/2021/01/general-motors-gm-zero-emission-gas-powered-vehicles.html
https://slate.com/news-and-politics/2021/01/general-motors-gm-zero-emission-gas-powered-vehicles.html
https://slate.com/news-and-politics/2021/01/general-motors-gm-zero-emission-gas-powered-vehicles.html
https://www.theguardian.com/environment/2021/jan/28/gm-electric-vehicles-cars-gas-diesel
https://www.theguardian.com/environment/2021/jan/28/gm-electric-vehicles-cars-gas-diesel
https://global.nissannews.com/en/releases/release-18e8181d3a7c563be5e62225a70c61b2-nissan-sets-carbon-neutral-goal-for-2050
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release-18e8181d3a7c563be5e62225a70c61b2-nissan-sets-carbon-
neutral-goal-for-2050. Ford aims for all car sales in Europe to be
electric by 2030 and will double investments in electric development
until 2025, to USD 22 billion, from C. Isidore, “Ford is investing $1
billion in Germany as it goes electric in Europe”, CNN, 17 February
2021, https://edition.cnn.com/2021/02/17/business/ford-europe-
electric-vehicles/index.html. Volvo and Daimler announced a new
joint venture aimed at developing, producing and commercialising
hydrogen fuel cells for the heavy-duty vehicle industry, from J. S. Hill,
“Volvo and Daimler to develop fuel cell systems for heavy vehicles”,
The Driven, 22 April 2020, https://thedriven.io/2020/04/22/volvo-
and-daimler-to-develop-and-fuel-cell-systems-for-heavy-vehicles.
Isuzu, while not committing to EV targets, announced a target for
net zero greenhouse gases across the entire lifecycle of Isuzu Group
products and from Isuzu Group operations by 2050 as well as 100%
recycling of waste and end-of-use vehicles by 2050, from Isuzu,
“Isuzu announces formulation of Isuzu Environmental Vision 2050”, 2
March 2020, https://www.isuzu.co.jp/world/press/2020/3_2.html.
266 Challenges include a lack of charging infrastructure, a
lack of battery-swapping stations in many areas, a lack of
standardisation of charging infrastructure, and the potential
environmental and social impacts of sourcing raw materials for
battery production. See, for example, the following: Chargepoint,
“An employer’s guide to EV charging in the workplace”, https://
incisive.cvtr.io/lp/chargepoint-bg1?wp=2291&locale=1&
msgid=577553-f0bac4483b40ec99, viewed 15 April 2019;
Alternative Fuels Observatory, “Fuel map”, https://www.eafo.
eu/fuel-map, viewed 14 March 2019; Runyon, op. cit. note 240;
J. Ward and A. Upadhyay, “India’s rickshaw revolution leaves
China in the dust”, Bloomberg, 25 October 2018, https://www.
bloomberg.com/news/features/2019-10-25/india-s-rickshaws-
outnumber-china-s-electric-vehicles. Standardisation of
charging infrastructure from S. Bajaj, “New EV charging station
guidelines announced”, Mercom India, 18 December 2018,
https://mercomindia.com/ev-charging-station-guidelines-
announced; potential environmental and social impacts from
SLOCAT, Transport and Climate Change Global Status Report
2018, op. cit. note 238, p. 92; V2G from, for example, J. Spector,
“EMotorWerks is using its network of 10,000 EV chargers to
bid into wholesale markets”, Greentech Media, 25 September
2018, https://www.greentechmedia.com/articles/read/
emotorwerks-wholesale-markets-ev-charger-network.
267 L. Collins, “Engie and Fiat-Chrysler join forces to build world’s
largest vehicle-to-grid project”, Recharge, 26 May 2020, https://
www.rechargenews.com/transition/engie-and-fiat-chrysler-join-
forces-to-build-worlds-largest-vehicle-to-grid-project/2-1-814744;
PEI, “France to kickstart Europe rollout of ABB vehicle-to-grid
solution”, 15 October 2020, https://www.powerengineeringint.
com/smart-grid-td/ev-infrastructure/abbs-new-v2g-tech-
selected-for-rollout-by-edf-subsidiary; EDF, “Flexitanie,
l’énergie devient plus flexible grâce au V2G en Occitanie”, 22
October 2020, https://www.edf.fr/collectivites/le-mag/le-mag-
collectivites/territoires-realisations/flexitanie-l-energie-devient-
plus-flexible-grace-au-v2g-en-occitanie; T. Hill, “From parking
to power: Major vehicle to grid electricity trial ready for take off”,
Business Green, 7 August 2020, https://www.businessgreen.
com/news/4018725/parking-power-major-vehicle-grid-
electricity-trial-ready; M. Lempriere, “World’s largest V2G project
dubbed Bus2Grid launched in London”, Current News, 13 August
2020, https://www.current-news.co.uk/news/worlds-largest-
v2g-project-dubbed-bus2grid-launched-in-london; M. Lempriere,
“V2G project launched at London’s Islington Town Hall by Honda
and Moixa”, Energy Storage News, 17 January 2020, https://www.
energy-storage.news/news/v2g-project-launched-at-islington-
town-hall-by-moixa-and-honda; Automotive World, “Nissan
LEAF to light up Australia: Industry-first vehicle-to-grid charging
technology launched at Realising Electric Vehicles Services
(REVS) in ACT”, 7 July 2020, https://www.automotiveworld.com/
news-releases/nissan-leaf-to-light-up-australia-industry-first-
vehicle-to-grid-charging-technology-launched-at-realising-
electric-vehicles-services-revs-in-act.
268 Collins, op. cit. note 267.
269 ITF, “Towards road freight decarbonisation”, 5 December 2018,
https://www.itf-oecd.org/towards-road-freight-decarbonisation.
270 “Why automakers are driving for uniform fuel efficiency
standards”, University of Pennsylvania – Knowledge @ Wharton,
14 June 2019, https://knowledge.wharton.upenn.edu/article/
end-california-emissions-standards.
271 ITF, op. cit. note 240.
272 EC, “Reducing CO2 emissions from heavy-duty vehicles”, https://
ec.europa.eu/clima/policies/transport/vehicles/heavy_en, viewed
27 May 2021.
273 Although not all from renewable sources, many alternative fuels
are already commercially viable, and technological development
continues. Alternative fuels for heavy-duty vehicles refer to
alternative propulsion systems to the traditional diesel (or
petrol) internal combustion engine and are not exclusively from
renewable sources. Alternative fuels include biofuels, synfuels or
low-carbon liquid fuels produced from agriculture crops or waste,
liquefied natural gas (LNG) or compressed natural gas (CNG),
and biomethane. Other propulsion systems that are reaching
commercial viability include hydrogen fuel cells, battery electric
and hybrid vehicles, and electric roads (electric-powered vehicles
where the energy source is external, for example through overhead
wires). Other options under development are vehicle-integrated
solar PV and the use of solar PV for road surfaces to charge
vehicles while they are in motion. ITF, op. cit. note 269.
274 M. Bates, “CARB adopts rule requiring state transition from
diesel trucks”, NGT News, 26 June 2020, https://ngtnews.com/
carb-adopts-rule-requiring-state-transition-from-diesel-trucks.
275 W. Owen, “Gasum expands its LNG filling station
network”, LNG Industry, 15 June 2020, https://www.
lngindustry.com/liquid-natural-gas/15062020/
gasum-expands-its-lng-filling-station-network.
276 Bioenergy Insight, “Volvo Trucks reports increased interest in LNG
and bio-LNG”, 23 September 2020, https://www.bioenergy-news.
com/news/volvo-trucks-reports-increased-interest-in-lng-and-
bio-lng; Bioenergy Insight, “Finnish freight firm Posti invests in
biogas truck fleet”, 28 October 2020, https://www.bioenergy-news.
com/news/finnish-freight-firm-posti-invests-in-biogas-truck-fleet.
277 For more on biofuels and EV efforts in cities, see REN21, op. cit.
note 43. Sustainable Bus, “Electric bus, main fleets and projects
around the world”, 19 May 2020, https://www.sustainable-bus.
com/electric-bus/electric-bus-public-transport-main-fleets-
projects-around-world. An example of renewable energy charging
stations is the bus charging station in Jinjiang’s Binjiang Business
District (Fujian Province, China), which was charging its electric
buses using solar power as of end-2019. CNESA, “2019 sees
new solar-storage-charging stations launched across China”, 29
November 2019, http://en.cnesa.org/latest-news/2019/11/29/
et8hrtqdeblp7knrz3rjl6bg4ohjlt. Many other charging stations
that use solar EV and energy storage have been developed in
China since 2017. Also, to incentivise increased public transport
use, some cities have made public transport free. In 2018,
Luxembourg became the first country to pledge to make all of its
public transport free for users by 2020, although these initiatives
are often mainly to decrease congestion and local pollution, from
D. Boffey, “Luxembourg to become first country to make all public
transport free”, The Guardian (UK), 5 December 2018, http://www.
theguardian.com/world/2019/dec/05/luxembourg-to-become-
first-country-to-make-all-public-transport-free.
278 See, for example: “963 railway stations solarised, 550 more
to get rooftop solar panels soon: Indian Railways”, Economic
Times, 31 August 2020, https://economictimes.indiatimes.
com/industry/transportation/railways/963-railway-
stations-solarised-550-more-to-get-rooftop-solar-panels-
soon-indian-railways/articleshow/77853689.cms; Biofuels
International, “18 new biodiesel fuelled trains coming to
the Netherlands”, 13 July 2017, https://biofuels-news.com/
news/18-new-biodiesel-fuelled-trains-coming-to-the-netherlands.
279 India’s rail electrification target includes also advancing plans to
integrate rising amounts of renewable power capacity (among
other sustainability improvements). “Indian Railways gears up to
become ‘Green Railway’ by 2030”, Economic Times, 13 July 2020,
https://energy.economictimes.indiatimes.com/news/power/indian-
railways-gears-up-to-become-green-railway-by-2030/76938990.
France’s national railway company committed to meeting a portion
of its electricity needs using renewable electricity and signed a
renewable electricity PPA for 2% of the electricity consumption
of all national passenger trains. C. Rollet, “French railway
operator buys 40 MW of power through solar PPA”, pv magazine,
18 June 2020, https://www.pv-magazine.com/2020/06/18/
french-railway-operator-buys-40-mw-of-power-through-solar-ppa.
280 Around three-quarters of passenger rail transport, and nearly half
of freight rail transport globally, is electric, from IEA, The Future of
267
https://global.nissannews.com/en/releases/release-18e8181d3a7c563be5e62225a70c61b2-nissan-sets-carbon-neutral-goal-for-2050
https://global.nissannews.com/en/releases/release-18e8181d3a7c563be5e62225a70c61b2-nissan-sets-carbon-neutral-goal-for-2050
https://edition.cnn.com/2021/02/17/business/ford-europe-electric-vehicles/index.html
https://edition.cnn.com/2021/02/17/business/ford-europe-electric-vehicles/index.html
Volvo and Daimler to develop fuel cell systems for heavy vehicles
Volvo and Daimler to develop fuel cell systems for heavy vehicles
https://www.isuzu.co.jp/world/press/2020/3_2.html
https://incisive.cvtr.io/lp/chargepoint-bg1?wp=2291&locale=1&msgid=577553-f0bac4483b40ec99
https://incisive.cvtr.io/lp/chargepoint-bg1?wp=2291&locale=1&msgid=577553-f0bac4483b40ec99
https://incisive.cvtr.io/lp/chargepoint-bg1?wp=2291&locale=1&msgid=577553-f0bac4483b40ec99
https://www.eafo.eu/fuel-map
https://www.eafo.eu/fuel-map
https://www.bloomberg.com/news/features/2019-10-25/india-s-rickshaws-outnumber-china-s-electric-vehicles
https://www.bloomberg.com/news/features/2019-10-25/india-s-rickshaws-outnumber-china-s-electric-vehicles
https://www.bloomberg.com/news/features/2019-10-25/india-s-rickshaws-outnumber-china-s-electric-vehicles
https://mercomindia.com/ev-charging-station-guidelines-announced
https://mercomindia.com/ev-charging-station-guidelines-announced
https://www.greentechmedia.com/articles/read/emotorwerks-wholesale-markets-ev-charger-network
https://www.greentechmedia.com/articles/read/emotorwerks-wholesale-markets-ev-charger-network
https://www.rechargenews.com/transition/engie-and-fiat-chrysler-join-forces-to-build-worlds-largest-vehicle-to-grid-project/2-1-814744
https://www.rechargenews.com/transition/engie-and-fiat-chrysler-join-forces-to-build-worlds-largest-vehicle-to-grid-project/2-1-814744
https://www.rechargenews.com/transition/engie-and-fiat-chrysler-join-forces-to-build-worlds-largest-vehicle-to-grid-project/2-1-814744
France to kickstart Europe rollout of ABB vehicle-to-grid solution
France to kickstart Europe rollout of ABB vehicle-to-grid solution
France to kickstart Europe rollout of ABB vehicle-to-grid solution
https://www.edf.fr/collectivites/le-mag/le-mag-collectivites/territoires-realisations/flexitanie-l-energie-devient-plus-flexible-grace-au-v2g-en-occitanie
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https://www.businessgreen.com/news/4018725/parking-power-major-vehicle-grid-electricity-trial-ready
https://www.businessgreen.com/news/4018725/parking-power-major-vehicle-grid-electricity-trial-ready
https://www.businessgreen.com/news/4018725/parking-power-major-vehicle-grid-electricity-trial-ready
https://www.current-news.co.uk/news/worlds-largest-v2g-project-dubbed-bus2grid-launched-in-london
https://www.current-news.co.uk/news/worlds-largest-v2g-project-dubbed-bus2grid-launched-in-london
https://www.energy-storage.news/news/v2g-project-launched-at-islington-town-hall-by-moixa-and-honda
https://www.energy-storage.news/news/v2g-project-launched-at-islington-town-hall-by-moixa-and-honda
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https://www.itf-oecd.org/towards-road-freight-decarbonisation
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https://knowledge.wharton.upenn.edu/article/end-california-emissions-standards
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https://ec.europa.eu/clima/policies/transport/vehicles/heavy_en
CARB Adopts Rule Requiring State Transition from Diesel Trucks
CARB Adopts Rule Requiring State Transition from Diesel Trucks
https://www.lngindustry.com/liquid-natural-gas/15062020/gasum-expands-its-lng-filling-station-network
https://www.lngindustry.com/liquid-natural-gas/15062020/gasum-expands-its-lng-filling-station-network
https://www.lngindustry.com/liquid-natural-gas/15062020/gasum-expands-its-lng-filling-station-network
https://www.sustainable-bus.com/electric-bus/electric-bus-public-transport-main-fleets-projects-around-world
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http://en.cnesa.org/latest-news/2019/11/29/et8hrtqdeblp7knrz3rjl6bg4ohjlt
http://www.theguardian.com/world/2019/dec/05/luxembourg-to-become-first-country-to-make-all-public-transport-free
http://www.theguardian.com/world/2019/dec/05/luxembourg-to-become-first-country-to-make-all-public-transport-free
http://www.theguardian.com/world/2019/dec/05/luxembourg-to-become-first-country-to-make-all-public-transport-free
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https://economictimes.indiatimes.com/industry/transportation/railways/963-railway-stations-solarised-550-more-to-get-rooftop-solar-panels-soon-indian-railways/articleshow/77853689.cms
https://economictimes.indiatimes.com/industry/transportation/railways/963-railway-stations-solarised-550-more-to-get-rooftop-solar-panels-soon-indian-railways/articleshow/77853689.cms
https://economictimes.indiatimes.com/industry/transportation/railways/963-railway-stations-solarised-550-more-to-get-rooftop-solar-panels-soon-indian-railways/articleshow/77853689.cms
https://energy.economictimes.indiatimes.com/news/power/indian-railways-gears-up-to-become-green-railway-by-2030/76938990
https://energy.economictimes.indiatimes.com/news/power/indian-railways-gears-up-to-become-green-railway-by-2030/76938990
French railway operator buys 40 MW of power through solar PPA
French railway operator buys 40 MW of power through solar PPA
ENDNOTES · GLOBAL OVERVIEW 01
EN
DN
OT
ES
I
GL
OB
AL
O
VE
RV
IE
W
Rail (Paris, 2019), https://www.iea.org/reports/the-future-of-rail.
Based on IEA, World Energy Balances 2020, op. cit. note 47.
281 Based on IEA, World Energy Balances 2020, op. cit. note 47.
282 See, for example: “Dutch electric trains become 100% powered
by wind energy”, Agence France-Presse, 10 January 2017, https://
www.theguardian.com/world/2018/jan/10/dutch-trains-100-
percent-wind-powered-ns; the Swiss railway company SBB CFF
FFS sources 75% of its power from hydropower, from International
Union of Railways (UIC), Railway Statistics: Synopsis (Paris: 2017),
https://uic.org/IMG/pdf/uic-statistics-synopsis-2017 .
283 O. Cuenca, “Indian Railways targets net zero emissions by
2030”, International Railway Journal, 16 July 2020, https://www.
railjournal.com/technology/indian-railways-to-achieve-net-zero-
emissions-by-2030; Carbon Intelligence, “Network Rail”, https://
carbon.ci/case-studies/network-rail-becomes-the-first-railway-
organisation-to-set-science-based-targets-aligned-to-1-5-degrees,
viewed 10 May 2021.
284 IEA, World Energy Balances 2020, op. cit. note 47. Emissions as of
2018 (latest data) from International Maritime Organization (IMO),
Fourth IMO Greenhouse Gas Study (Geneva: 2020), p. 1, https://
wwwcdn.imo.org/localresources/en/MediaCentre/Documents/
Fourth%20IMO%20GHG%20Study%202020%20Executive%20
Summary .
285 Biofuels International,“Netherlands examines biofuels’ law changes
to meet RED II targets”, 11 December 2020, https://biofuels-news.
com/news/netherlands-examines-biofuels-law-changes-to-meet-
red-ii-targets.
286 Energie zukunft, “Schifffahrtsbranche will sich grünen Anstrich geben“,
https://www.energiezukunft.eu/mobilitaet/schifffahrtsbranche-
will-sich-gruenen-anstrich-geben, viewed 26 January 2021.
287 N. Chestney, “IMO agrees on stricter efficiency targets for some
ships”, Reuters, 17 May 2020, https://www.reuters.com/article/
us-imo-shipping-efficiency/imo-agrees-on-stricter-efficiency-
targets-for-some-ships-idUSKCN1SN2BV; International
Shipping News, “New fuel, emission standards for shipping
from January”, Hellenic Shipping, 30 December 2020, https://
www.hellenicshippingnews.com/new-fuel-emission-standards-
for-shipping-from-january; Euronews, “Shipping industry plans
speed limit reductions to cut emissions”, 13 May 2020, https://
www.euronews.com/2020/05/13/shipping-industry-plans-
speed-limit-reductions-to-cut-emissions; M. Wingrove, “IMO sets
new emissions-cutting goals for ship-port interfaces”, Riviera,
22 May 2020, https://www.rivieramm.com/news-content-hub/
news-content-hub/imo-sets-new-maritime-emissions-cutting-
goals—though-technology-59494. Previously, in 2019, the IMO
had adopted energy efficiency standards for international shipping,
targeting a 40% reduction in total carbon intensity by 2030 and a
50% reduction in overall greenhouse gas emissions for the sector
by 2050, relative to 2008 levels, from IMO, “UN body adopts climate
change strategy for shipping”, 13 April 2019, http://www.imo.org/
en/MediaCentre/PressBriefings/Pages/06GHGinitialstrategy.aspx.
288 For an example using wind, see M. Schaus, “Greening our
shipping: Wind-powered cargo ships can change future of
freight cutting emissions by 90%”, Good News Network,
24 October 2020, https://www.goodnewsnetwork.org/
oceanbird-prototype-cuts-cargo-ship-emissions-by-90pt.
289 For example: 100% renewably fuelled ferry fleet, from Biofuel
Express, “Take the ferry to the Copenhagen Opera with Neste
MY Renewable Diesel HVO”, https://www.biofuel-express.com/
en/take-the-ferry-to-the-copenhagen-opera-with-neste-my-
renewable-diesel-hvo, viewed 27 May 2021; hybrid ferry fleet with
storage but fossil fuel-based from Wärtsilä, “Three new Finnlines
ships to go green with Wärtsilä Hybrid Systems”, 5 February
2020, https://www.wartsila.com/media/news/05-02-2020-
three-new-finnlines-ships-to-go-green-with-wartsila-hybrid-
systems-2632097.
290 Bioenergy Insight, “Finnish firms testing liquefied biogas as
shipping fuel”, 12 June 2020, https://www.bioenergy-news.
com/news/finnish-firms-testing-liquefied-biogas-as-shipping-
fuel. In 2019, some shipping companies in Scandinavia
entered into agreements to use LBG, from Scandinavia:
“Preem signs agreement for renewable maritime fuel”,
Renewable Energy Magazine, 25 March 2020, https://www.
renewableenergymagazine.com/biogas/preem-signs-agreement-
for-renewable-maritime-fuel-20210325; “Hurtigruten buys
fish-based fuel for its future fleet”, The Maritime Executive,
24 May 2019, https://www.maritime-executive.com/article/
hurtigruten-buys-fish-based-fuel-for-its-future-fleet.
291 Green Car Congress, “Wärtsilä launches first combustion trials
with ammonia”, 26 March 2021, https://www.greencarcongress.
com/2021/03/20210326-wartsila.html.
292 See, for example: Fuel Cells Works, “Irish islands look to ferry
services with hydrogen fuel cells”, 23 November 2020, https://
fuelcellsworks.com/news/irish-islands-look-to-ferry-services-
with-hydrogen-fuel-cells; M. Lewis, “Denmark, Norway to build
world’s largest green hydrogen ferry”, Electrek, 8 December 2020,
https://electrek.co/2020/12/08/denmark-norway-worlds-largest-
green-hydrogen-ferry; J. Saul and N. Chestney, “The path to zero:
First wave of ships explore green hydrogen”, Maritime Logistics
Professional, 30 October 2020, https://www.maritimeprofessional.
com/news/path-zero-first-wave-ships-362805.
293 IEA, “Ordinance (2017: 1317) on grants to private individuals for
the purchase of electric bikes, mopeds, motorcycles and outboard
motors”, 4 November 2019, https://www.iea.org/policies/7159-
ordinance-2017-1317-on-grants-to-private-individuals-for-the-
purchase-of-electric-bikes-mopeds-motorcycles-and-outboard-
motors; Mobility Foresights, “Global Marine Outboard Engine
Market 2019-2025”, https://mobilityforesights.com/product/
marine-outboard-engine-market; Torqueedo, “Torqeedo
Solar pannel 45 W”, http://www.torqeedo-belux.com/Solaire/
Torqeedo%20solar%20pannel%2045%20W.htm, viewed 27
May 2021; Global Market Insights, “Electric outboard engines
market size by power (below 25kW, 25 to 50 kW, 50 to 150 kW),
by control (tiller, remote), by application (commercial, recreational,
military), industry analysis report, regional outlook, application
growth potential, price trends, competitive landscape & forecast,
2021-2027”, 2020, https://www.gminsights.com/industry-analysis/
electric-outboard-engine-market.
294 AJOT, “Valenciaport joins the club of the 12 largest ports in
the world that lead the decarbonization and reduction of
emissions”, 4 January 2021, https://www.ajot.com/news/
valenciaport-joins-the-club-of-the-12-largest-ports-in-the-world-
that-lead-the-decarbonization-and-reduction-of-emissions. The
programme was established in 2017 led by the Port of Rotterdam
(Netherlands) along with Antwerp (Belgium), Barcelona (Spain),
Hamburg (Germany), Long Beach and Los Angeles (US) and
Vancouver (Canada). New additions from 2019 include Amsterdam
(Netherlands), Le Havre (France), Gothenburg (Sweden), and New
York and New Jersey (US). Greenport, “Climate action congress
plans underway”, 6 September 2019, https://www.greenport.
com/news101/Projects-and-Initiatives/climate-action-congress-
plans-underway; E. Lopez, “From Los Angeles to Hamburg, 7
ports team up to fight climate change”, Supply Chain Dive, 15
September 2018, https://www.supplychaindive.com/news/
World-Ports-Climate-Action-Program-launch/532431.
295 S. Djunisic, “Port of Valencia plans to add 8.5 MW of PV for
own operations”, Renewables Now, 22 April 2020, https://
renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-
of-pv-for-own-operations-695937.
296 E. Bellini, “Portuguese green hydrogen for the Port of Rotterdam”,
pv magazine, 24 September 2020,,https://www.pv-magazine.
com/2020/09/24/portuguese-green-hydrogen-for-the-port-of-
rotterdam. In 2016, industrial activities in the Port of Rotterdam
accounted for 19% of total CO2 emissions in the Netherlands,
from C. Schneider, S. Lechtenböhmer and S. Samadi, “Risks and
opportunities associated with decarbonizing Rotterdam’s industrial
cluster”, Environmental Innovation and Societal Transitions, vol.
35 (2020), pp. 414-28, https://epub.wupperinst.org/frontdoor/
index/index/start/4/rows/10/sortfield/year_sort/sortorder/desc/
searchtype/simple/query/Rotterdam/yearfq/2020/docId/7334.
297 IEA, World Energy Balances 2020, op. cit. note 47; H. Ritchie,
“Climate change and flying: What share of global CO2 emissions
come from aviation?”, Our World in Data, 22 October 2020, https://
ourworldindata.org/co2-emissions-from-aviation.
298 Ritchie, op. cit. note 297; D. Habtemariam, “Global air traffic growth
outpaced capacity growth in 2018”, Business Travel News, 7
February 2019, https://www.businesstravelnews.com/Global/
Global-Air-Traffic-Growth-Outpaced-Capacity-Growth-in-2018;
International Airport Review, “IATA announces 50 per cent
decrease in carbon emissions per passenger”, 16 December
2019, https://www.internationalairportreview.com/news/109066/
iata-50-per-cent-decrease-carbon-emissions-per-passenger; H.
Tabuchi, “‘Worse than anyone expected’: Air travel emissions vastly
outpace predictions”, New York Times, 20 September 2019, https://
www.nytimes.com/2019/09/19/climate/air-travel-emissions.html.
268
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https://www.theguardian.com/world/2018/jan/10/dutch-trains-100-percent-wind-powered-ns
https://www.theguardian.com/world/2018/jan/10/dutch-trains-100-percent-wind-powered-ns
https://www.theguardian.com/world/2018/jan/10/dutch-trains-100-percent-wind-powered-ns
https://uic.org/IMG/pdf/uic-statistics-synopsis-2017
https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
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Netherlands examines biofuels’ law changes to meet RED II targets
Netherlands examines biofuels’ law changes to meet RED II targets
Netherlands examines biofuels’ law changes to meet RED II targets
https://www.energiezukunft.eu/mobilitaet/schifffahrtsbranche-will-sich-gruenen-anstrich-geben
https://www.energiezukunft.eu/mobilitaet/schifffahrtsbranche-will-sich-gruenen-anstrich-geben
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https://www.hellenicshippingnews.com/new-fuel-emission-standards-for-shipping-from-january
https://www.euronews.com/2020/05/13/shipping-industry-plans-speed-limit-reductions-to-cut-emissions
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https://www.rivieramm.com/news-content-hub/news-content-hub/imo-sets-new-maritime-emissions-cutting-goals—though-technology-59494
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https://www.wartsila.com/media/news/05-02-2020-three-new-finnlines-ships-to-go-green-with-wartsila-hybrid-systems-2632097
https://www.wartsila.com/media/news/05-02-2020-three-new-finnlines-ships-to-go-green-with-wartsila-hybrid-systems-2632097
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https://www.renewableenergymagazine.com/biogas/preem-signs-agreement-for-renewable-maritime-fuel-20210325
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https://www.maritime-executive.com/article/hurtigruten-buys-fish-based-fuel-for-its-future-fleet
https://www.greencarcongress.com/2021/03/20210326-wartsila.html
https://www.greencarcongress.com/2021/03/20210326-wartsila.html
Irish Islands Look to Ferry Services with Hydrogen Fuel Cells
Irish Islands Look to Ferry Services with Hydrogen Fuel Cells
Irish Islands Look to Ferry Services with Hydrogen Fuel Cells
Denmark, Norway to build world’s largest green hydrogen ferry
Denmark, Norway to build world’s largest green hydrogen ferry
https://www.maritimeprofessional.com/news/path-zero-first-wave-ships-362805
https://www.maritimeprofessional.com/news/path-zero-first-wave-ships-362805
https://www.iea.org/policies/7159-ordinance-2017-1317-on-grants-to-private-individuals-for-the-purchase-of-electric-bikes-mopeds-motorcycles-and-outboard-motors
https://www.iea.org/policies/7159-ordinance-2017-1317-on-grants-to-private-individuals-for-the-purchase-of-electric-bikes-mopeds-motorcycles-and-outboard-motors
https://www.iea.org/policies/7159-ordinance-2017-1317-on-grants-to-private-individuals-for-the-purchase-of-electric-bikes-mopeds-motorcycles-and-outboard-motors
https://www.iea.org/policies/7159-ordinance-2017-1317-on-grants-to-private-individuals-for-the-purchase-of-electric-bikes-mopeds-motorcycles-and-outboard-motors
https://mobilityforesights.com/product/marine-outboard-engine-market
https://mobilityforesights.com/product/marine-outboard-engine-market
http://www.torqeedo-belux.com/Solaire/Torqeedo%20solar%20pannel%2045%20W.htm
http://www.torqeedo-belux.com/Solaire/Torqeedo%20solar%20pannel%2045%20W.htm
https://www.gminsights.com/industry-analysis/electric-outboard-engine-market
https://www.gminsights.com/industry-analysis/electric-outboard-engine-market
https://www.ajot.com/news/valenciaport-joins-the-club-of-the-12-largest-ports-in-the-world-that-lead-the-decarbonization-and-reduction-of-emissions
https://www.ajot.com/news/valenciaport-joins-the-club-of-the-12-largest-ports-in-the-world-that-lead-the-decarbonization-and-reduction-of-emissions
https://www.ajot.com/news/valenciaport-joins-the-club-of-the-12-largest-ports-in-the-world-that-lead-the-decarbonization-and-reduction-of-emissions
https://www.greenport.com/news101/Projects-and-Initiatives/climate-action-congress-plans-underway
https://www.greenport.com/news101/Projects-and-Initiatives/climate-action-congress-plans-underway
https://www.greenport.com/news101/Projects-and-Initiatives/climate-action-congress-plans-underway
https://www.supplychaindive.com/news/World-Ports-Climate-Action-Program-launch/532431
https://www.supplychaindive.com/news/World-Ports-Climate-Action-Program-launch/532431
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
https://epub.wupperinst.org/frontdoor/index/index/start/4/rows/10/sortfield/year_sort/sortorder/desc/searchtype/simple/query/Rotterdam/yearfq/2020/docId/7334
https://epub.wupperinst.org/frontdoor/index/index/start/4/rows/10/sortfield/year_sort/sortorder/desc/searchtype/simple/query/Rotterdam/yearfq/2020/docId/7334
https://epub.wupperinst.org/frontdoor/index/index/start/4/rows/10/sortfield/year_sort/sortorder/desc/searchtype/simple/query/Rotterdam/yearfq/2020/docId/7334
https://ourworldindata.org/co2-emissions-from-aviation
https://ourworldindata.org/co2-emissions-from-aviation
https://www.businesstravelnews.com/Global/Global-Air-Traffic-Growth-Outpaced-Capacity-Growth-in-2018
https://www.businesstravelnews.com/Global/Global-Air-Traffic-Growth-Outpaced-Capacity-Growth-in-2018
IATA announces 50 per cent decrease in carbon emissions per passenger
IATA announces 50 per cent decrease in carbon emissions per passenger
ENDNOTES · GLOBAL OVERVIEW 01
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299 Seating capacity fell by around 50%, while flights decreased from
38.9 million in 2019 to 16.4 million in 2020. “Air travel down 60 per
cent, as airline industry losses top $370 billion: ICAO”, UN News,
15 January 2021, https://news.un.org/en/story/2021/01/1082302;
E. Mazareanu, “Global air traffic – number of flights 2004-2021”,
Statista, 11 May 2020, https://www.statista.com/statistics/564769/
airline-industry-number-of-flights.
300 ICAO, “Climate change: State action plans and assistance”, https://
www.icao.int/environmental-protection/Pages/ClimateChange_
ActionPlan.aspx, viewed 12 March 2021; ICAO, “Environment”,
https://www.icao.int/environmental-protection/GFAAF/Pages/
default.aspx, viewed 12 March 2021.
301 ICAO, “Environment”, op. cit. note 300.
302 Mazareanu, op. cit. note 299.
303 Airports with regular distribution saw the addition of San Francisco
Airport (US), while those with batch deliveries decreased from 14
the year before as San Francisco Airport began regular distribution.
ICAO, “Environment”, op. cit. note 300.
304 However, some limitations (related to costs and availability of sufficient
sustainable feedstocks) continue to hinder significant biofuel use in
aviation. See Bioenergy section in Market and Industry chapter.
305 See, for example: B. Cogley, “World’s first commercial electric plane
takes off near Vancouver”, Dezeen, 17 December 2019, https://
www.dezeen.com/2019/12/17/worlds-first-commercial-electric-
plane-canada-seaplane; Green Car Congress, “Wright Electric
begins motor development program for 186-seat electric aircraft;
1.5MW motor, 3 kV inverter”, 31 January 2020, https://www.
greencarcongress.com/2020/01/20200131-wright.html. In 2018,
Norway became the first country (and as of early 2021, still the only
country) to see its airports announce a target for electric air travel,
with a goal of having all short-haul domestic flights run on electricity
by 2040, from “Norway aims for all short-haul flights 100% electric
by 2040”, Tech Xplore, 17 January 2018, https://techxplore.com/
news/2018-01-norway-aims-short-haul-flights-electric.html.
306 GCCA+, “Reducing aviation emissions from the ground up on the
island of Trinidad”, 12 August 2019, https://www.gcca.eu/stories/
reducing-aviation-emissions-ground-island-trinidad; Jamaica
from ICAO, “Solar-at-gate. Pilot project”, https://www.icao.int/
environmental-protection/Documents/UNDP%20Leaflets/
ICAO%20ENV%20Solar-F%20WEB , viewed 27 May 2021, and
from ICAO, “New Jamaica ‘solar-at-gate’ pilot project a big step
toward more sustainable aircraft gate power solutions for small
island states”, 25 April 2018, https://www.icao.int/Newsroom/
Pages/New-Jamaica-solar-at-gate-pilot-project-big-step-toward-
sustainable-aircraft-gate-power-solutions-for-small-island-states.
aspx; Green Ari, “ICAO launches two African airport solar-at-gate
projects to reduce aircraft ground emissions”, 25 January 2019,
https://www.greenaironline.com/news.php?viewStory=2557.
307 J. M. Takouleu, “Ghana: Government to power airports with solar
energy”, Afrik21, 6 April 2020, https://www.afrik21.africa/en/ghana-
government-to-power-airports-with-solar-energy; International
Airport Review, “EIA introduces the world’s-largest airport solar
farm”, 8 July 2020, https://www.internationalairportreview.com/
news/120379/solar-farm-edmonton-international-airport; L.
Butcher, “Solar power for Australian airport”, Passenger Terminal
Today, 6 August 2020, https://www.passengerterminaltoday.com/
news/airport/solar-power-for-australian-airport.html; Aviation
Pros, “New York State’s largest solar power canopy storage
system at JFK Airport authorized to begin development, furthering
Port Authority’s commitment to the Paris Climate Agreement”,
17 December 2020, https://www.aviationpros.com/airports/
press-release/21203148/the-port-authority-of-new-york-new-
jersey-new-york-states-largest-solar-power-canopy-storage-
system-at-jfk-airport-authorized-to-begin-development-furthering-
port-authoritys-commitment-to-the-paris-climate-agreement;
E. Bellini, “21-year solar PPA for three French airports”, pv
magazine, 6 February 2020, https://www.pv-magazine.
com/2020/02/06/21-year-solar-ppa-for-three-french-airports.
308 See Market and Industry chapter. See also L. Stoker, “New solar
investment falls 12% as COVID-19 dents H1 2020 figures: BNEF”,
pv magazine, 13 July 2020, https://www.pv-tech.org/new-solar-
investment-falls-12-as-covid-19-dents-h1-2020-figures-bnef, and
IEA, Renewable Energy Market Update 2021 (Paris: 2021), https://
www.iea.org/reports/renewable-energy-market-update-2021.
Auctions were cancelled for solar PV and wind, as well as
hydropower in Brazil, from L. Morais, “Brazil officially cancels 2020
auctions, posts schedule for 2021-2023”, Renewables Now, 8
December 2020, https://renewablesnow.com/news/brazil-officially-
cancels-2020-auctions-posts-schedule-for-2021-2023-723763.
309 GWEC, Global Wind Report 2020 (Brussels: 2020), p. 46, https://
gwec.net/global-offshore-wind-report-2020; IEA, op. cit. note 5,
p. 11. See Market and Industry chapter for more information.
310 Additions of 256.6 GW consisted of 139.4 GW solar PV, 93.0
GW wind power, 19.4 GW hydropower, 4.6 GW biopower, 0.1
GW geothermal power, 0.1 GW CSP and ~0 GW ocean power.
Hydropower from International Hydropower Association (IHA),
Hydropower Status Report 2021 (London: May 2021), https://
www.hydropower.org/publications/2021-hydropower-status-
report, and from IHA, personal communication with REN21, 25
May 2020; wind power from GWEC, op. cit. note 6; solar PV
collected in direct current and from IEA PVPS, Snapshot of Global
Photovoltaic Markets 2021 (Paris: 2021), https://iea-pvps.org/
snapshot-reports/snapshot-2021; bio-power from IEA, op. cit.
note 5, and from US Federal Energy Regulatory Commission,
“Office of Energy Projects Energy Infrastructure Update for
December 2020” (Washington, DC: 2020), https://www.ferc.gov/
legal/staff-reports/2019/dec-energy-infrastructure ; German
Federal Ministry for Economic Affairs and Energy (BMWi)
and AGEE Stat, “Zeitreihen zur Entwicklung der erneuerbaren
Energien in Deutschland, 1990-2020”, Table 4, https://www.
erneuerbare-energien.de/EE/Navigation/DE/Service/
Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html,
updated March 2021; UK Department for Business, Energy and
Industrial Strategy (BEIS), “Energy Trends: Renewables”, Table
6.1, https://www.gov.uk/government/statistics/energy-trends-
section-6-renewables, updated 13 May 2021; Government of
India, Ministry of New and Renewable Energy (MNRE), “Physical
progress (achievements) for 2019 and 2020”, https://mnre.gov.in/
physical-progress-achievements, viewed 14 February 2021; data
for other countries based on forecast 2020 capacity figures from
IEA, op. cit. this note, datafiles. Geothermal from the following
sources: IEA, op. cit. this note; US EIA, op. cit. note 70, Table 6.2.B;
BMWi, op. cit. this note; Turkey from endnote 1 in Geothermal
section of Market and Industry chapter. CSP capacity was
limited to 14 countries; for data and references, see CSP section
of Market and Industry chapter. Ocean power capacity was
negligible worldwide and had no effect on capacity rankings or
whether or not a certain country exceeded 10 GW of capacity.
Where national data were unavailable from previously referenced
sources, gaps were filled from IRENA, “Renewable electricity
capacity and generation statistics”, http://resourceirena.irena.org/
gateway/dashboard/?topic=4&subTopic=54, viewed on multiple
occasions in April and May 2021. For “rebound”, see Market and
Industry chapter and IEA, op. cit. note 308.
311 Total capacity and growth based on sources in endnote 310, on
data provided throughout this report and on data from past GSRs.
See Market and Industry chapter, Reference Table R1 in GSR 2021
Data Pack, and related endnotes for sources and details. Figure 7
based on idem. For more on renewable power capacity in 2020,
see Reference Table R1 in GSR 2021 Data Pack, technology
sections in Market and Industry chapter, and related endnotes.
312 Fossil fuel and nuclear power sector progress from IEA,
Global Energy Review 2021 (Paris: 2021), https://www.iea.org/
reports/global-energy-review-2021; share of 83% from IRENA,
“Renewable capacity highlights”, 31 March 2021, https://www.
irena.org/-/media/Files/IRENA/Agency/Publication/2021/Apr/
IRENA_-RE_Capacity_Highlights_2021 ; renewable power
capacity from idem; non-renewable power capacity provided
by A. Whiteman, IRENA, personal communication with REN21,
April 2021. Figure 8 based on sources in this note.
313 Based on capacity additions reported in endnote 310 and
throughout this report.
314 Ibid.
315 46% share from China’s additions of 119.3 GW over a global total of
256.8 GW, from Ibid.
316 Ibid.
317 Based on capacity additions reported in endnote 310 and in Market
and Industry section.
318 Based on capacity additions reported in endnote 310.
319 Ibid.; 20 countries in 2010 from IRENA, op. cit. note 312.
320 Estimate of 19 countries in 2020 from sources in endnote 310;
5 countries in 2010 from IRENA, op. cit. note 312.
269
https://news.un.org/en/story/2021/01/1082302
https://www.statista.com/statistics/564769/airline-industry-number-of-flights
https://www.statista.com/statistics/564769/airline-industry-number-of-flights
https://www.icao.int/environmental-protection/Pages/ClimateChange_ActionPlan.aspx
https://www.icao.int/environmental-protection/Pages/ClimateChange_ActionPlan.aspx
https://www.icao.int/environmental-protection/Pages/ClimateChange_ActionPlan.aspx
https://www.icao.int/environmental-protection/GFAAF/Pages/default.aspx
https://www.icao.int/environmental-protection/GFAAF/Pages/default.aspx
World’s first commercial electric plane takes off near Vancouver
World’s first commercial electric plane takes off near Vancouver
World’s first commercial electric plane takes off near Vancouver
https://www.greencarcongress.com/2020/01/20200131-wright.html
https://www.greencarcongress.com/2020/01/20200131-wright.html
https://techxplore.com/news/2018-01-norway-aims-short-haul-flights-electric.html
https://techxplore.com/news/2018-01-norway-aims-short-haul-flights-electric.html
https://www.gcca.eu/stories/reducing-aviation-emissions-ground-island-trinidad
https://www.gcca.eu/stories/reducing-aviation-emissions-ground-island-trinidad
https://www.icao.int/environmental-protection/Documents/UNDP%20Leaflets/ICAO%20ENV%20Solar-F%20WEB
https://www.icao.int/environmental-protection/Documents/UNDP%20Leaflets/ICAO%20ENV%20Solar-F%20WEB
https://www.icao.int/environmental-protection/Documents/UNDP%20Leaflets/ICAO%20ENV%20Solar-F%20WEB
https://www.icao.int/Newsroom/Pages/New-Jamaica-solar-at-gate-pilot-project-big-step-toward-sustainable-aircraft-gate-power-solutions-for-small-island-states.aspx
https://www.icao.int/Newsroom/Pages/New-Jamaica-solar-at-gate-pilot-project-big-step-toward-sustainable-aircraft-gate-power-solutions-for-small-island-states.aspx
https://www.icao.int/Newsroom/Pages/New-Jamaica-solar-at-gate-pilot-project-big-step-toward-sustainable-aircraft-gate-power-solutions-for-small-island-states.aspx
https://www.icao.int/Newsroom/Pages/New-Jamaica-solar-at-gate-pilot-project-big-step-toward-sustainable-aircraft-gate-power-solutions-for-small-island-states.aspx
https://www.greenaironline.com/news.php?viewStory=2557
https://www.aviationpros.com/airports/press-release/21203148/the-port-authority-of-new-york-new-jersey-new-york-states-largest-solar-power-canopy-storage-system-at-jfk-airport-authorized-to-begin-development-furthering-port-authoritys-commitment-to-the-paris-climate-agreement
https://www.aviationpros.com/airports/press-release/21203148/the-port-authority-of-new-york-new-jersey-new-york-states-largest-solar-power-canopy-storage-system-at-jfk-airport-authorized-to-begin-development-furthering-port-authoritys-commitment-to-the-paris-climate-agreement
https://www.aviationpros.com/airports/press-release/21203148/the-port-authority-of-new-york-new-jersey-new-york-states-largest-solar-power-canopy-storage-system-at-jfk-airport-authorized-to-begin-development-furthering-port-authoritys-commitment-to-the-paris-climate-agreement
https://www.aviationpros.com/airports/press-release/21203148/the-port-authority-of-new-york-new-jersey-new-york-states-largest-solar-power-canopy-storage-system-at-jfk-airport-authorized-to-begin-development-furthering-port-authoritys-commitment-to-the-paris-climate-agreement
https://www.aviationpros.com/airports/press-release/21203148/the-port-authority-of-new-york-new-jersey-new-york-states-largest-solar-power-canopy-storage-system-at-jfk-airport-authorized-to-begin-development-furthering-port-authoritys-commitment-to-the-paris-climate-agreement
New solar investment falls 12% as COVID-19 dents H1 2020 figures: BNEF
New solar investment falls 12% as COVID-19 dents H1 2020 figures: BNEF
https://www.iea.org/reports/renewable-energy-market-update-2021
https://www.iea.org/reports/renewable-energy-market-update-2021
https://renewablesnow.com/news/brazil-officially-cancels-2020-auctions-posts-schedule-for-2021-2023-723763
https://renewablesnow.com/news/brazil-officially-cancels-2020-auctions-posts-schedule-for-2021-2023-723763
https://www.hydropower.org/publications/2021-hydropower-status-report
https://www.hydropower.org/publications/2021-hydropower-status-report
https://www.hydropower.org/publications/2021-hydropower-status-report
https://iea-pvps.org/snapshot-reports/snapshot-2021
https://iea-pvps.org/snapshot-reports/snapshot-2021
https://www.ferc.gov/legal/staff-reports/2019/dec-energy-infrastructure
https://www.ferc.gov/legal/staff-reports/2019/dec-energy-infrastructure
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.gov.uk/government/statistics/energy-trends-section-6-renewables
https://www.gov.uk/government/statistics/energy-trends-section-6-renewables
https://mnre.gov.in/physical-progress-achievements
https://mnre.gov.in/physical-progress-achievements
http://resourceirena.irena.org/gateway/dashboard/?topic=4&subTopic=54
http://resourceirena.irena.org/gateway/dashboard/?topic=4&subTopic=54
https://www.iea.org/reports/global-energy-review-2021
https://www.iea.org/reports/global-energy-review-2021
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2021/Apr/IRENA_-RE_Capacity_Highlights_2021
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2021/Apr/IRENA_-RE_Capacity_Highlights_2021
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2021/Apr/IRENA_-RE_Capacity_Highlights_2021
ENDNOTES · GLOBAL OVERVIEW 01
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321 Ranking for top countries per capita for based on sources
throughout this chapter and population data from World Bank,
“Population, total”, https://data.worldbank.org/indicator/SP.POP.
TOTL, viewed March 2021.
322 See Policy Landscape chapter, Wind Power section and Solar
PV section in Market and Industry chapter and IEA, “January to
June renewable electricity capacity additions”, https://www.iea.
org/reports/renewables-2020/covid-19-and-the-resilience-of-
renewables, viewed 13 May 2021. See also IEA, op. cit. note 308.
323 IEA PVPS, op. cit. note 310, p. 12. See sources throughout Market
and Industry chapter and endnote 308.
324 Ibid, all references.
325 IHA, Hydropower Status Report 2021, op. cit. note 310. See Hydropower
section in Market and Industry chapter for more information.
326 Each technology only installed 100 MW of new capacity, with
nearly all geothermal additions in Turkey and only CSP project
coming only in China during the year. See Market and Industry
chapter for more information.
327 See Ocean Power section in Market and Industry chapter. Capacity
targets from EC, Offshore Renewable Energy Strategy (Brussels:
2020), https://ec.europa.eu/energy/sites/ener/files/offshore_
renewable_energy_strategy .
328 See Figure 16 in Policy Landscape chapter and related endnotes.
329 IEA, op. cit. note 5, p. 19.
330 Countries holding tenders for the first time in 2020 included
Bhutan, Croatia, Mozambique, Myanmar and the Slovak Republic.
Europe is included in this total. From REN21 Policy Database. See
Policy Landscape chapter for more discussion.
331 IRENA Coalition for Action, Stimulating Investment in Community
Energy (Abu Dhabi: 2020), p. 13, https://coalition.irena.org/-/media/
Files/IRENA/Coalition-for-Action/IRENA_Coalition_Stimulating_
Investment_in_Community_Energy_2020 .
332 Solar PV from E. Bellini, “Portugal’s second PV auction draws
world record low bid of $0.0132/kWh”, pv magazine, 24 August
2020, https://www.pv-magazine.com/2020/08/24/portugals-
second-pv-auction-draws-world-record-low-bid-of-0-0132-kwh,
and from “Bundesnetzagentur awards 100.55 MW under first
solar PV auction of 2020 in Germany with average Wwnning
bid coming in at €0.0501/kWh”, TaiyangNews, 21 February
2020, http://taiyangnews.info/markets/record-low-e0-0355-
winning-bid-in-german-auction. Wind from the following
sources: C. Richard, “Greece momentum continues with record
onshore prices”, Wind Power, 9 April 2020, https://www.
windpowermonthly.com/article/1679862/greece-momentum-
continues-record-onshore-prices; N. Weekes, “Onshore wind
dominates latest Italian energy tender”, Wind Power, 2 June
2020, https://www.windpowermonthly.com/article/1684954/
onshore-wind-dominates-latest-italian-energy-tender; C. Richard,
“Prices hit new low in French onshore”, Wind Power, 2 April
2020, https://www.windpowermonthly.com/article/1679192/
prices-hit-new-low-french-onshore; C. Richard, “Shell advances
hydrogen plan with Eneco deal”, Wind Power, 7 May 2020,
https://www.windpowermonthly.com/article/1682629/shell-
advances-hydrogen-plan-eneco-deal; C. Richard, “Subsidy-free
wind farm wins first Lithuanian tender”, Wind Power, 16 January
2020, https://www.windpowermonthly.com/article/1671089/
subsidy-free-wind-farm-wins-first-lithuanian-tender; I. Todorović,
“Greece awards nearly all wind, solar capacity at auction as
prices drop”, Balkan Green Energy News, 28 July 2020, https://
balkangreenenergynews.com/greece-awards-nearly-all-wind-
solar-capacity-at-auction-as-prices-drop; A. Franke, “France
awards 1.7 GW renewables projects, adjusts 2020 auction
schedule”, S&P Global, 3 April 2020, https://www.spglobal.com/
platts/en/market-insights/latest-news/electric-power/040320-
france-awards-17-gw-renewables-projects-adjusts-2020-
auction-schedule. See Market and Industry chapter for further
examples and discussion.
333 IRENA, Renewable Energy Auctions: Status and Trends Beyond
Price (Abu Dhabi: 2019), pp. 13-16, https://www.irena.org/
publications/2019/Dec/Renewable-energy-auctions-Status-and-
trends-beyond-price; E. Vartiainen et al., “Impact of weighted
average cost of capital, capital expenditure, and other parameters
on future utility‐scale PV levelised cost of electricity”, EU PVSEC,
29 August 2019, https://doi.org/10.1002/pip.3189.
334 BloombergNEF, op. cit. note 31. See Feature chapter for further
discussion.
335 Ibid.
336 A. Niklaus, Pexpark, cited in M. Nicholls, “Dynamism and
innovation in a post-subsidy renewables market“, EnergyMonitor, 8
March 2021, https://energymonitor.ai/finance/sustainable-finance/
dynamism-and-innovation-in-a-post-subsidy-renewables-market.
337 IEA, “2020 Global overview: The Covid-19 pandemic”, in Electricity
Market Report (Paris: 2020), https://www.iea.org/reports/
electricity-market-report-december-2020/2020-global-overview-
the-covid-19-pandemic#abstract.
338 Ibid.
339 See, for example, GWEC, op. cit. note 6; IEA, op. cit. note 5.
340 Ember, op. cit. note 2.
341 Decline of electricity production from fossil fuels of 16,233 TWh in
2018 to 16,114 TWh in 2019 and 15,757 TWh in 2020, from Ember, op.
cit. note 2.
342 Share of generation in 2020 based on estimated total global
electricity generation of 25,850 TWh and total renewable
generation of 7,493 TWh, from Ember, op. cit. note 2. Global totals
for 2020 were estimated by summing total electricity generation
and electricity generation per energy source in 36 countries
where 2020 national sources (including official government
data and utility data) were available, comprising 90% of global
generation. See Ember, “Methodology”, https://ember-climate.
org/global-electricity-review-2021/methodology, viewed 7 April
2021. Figure 7 based on previous year’s generation from idem.
343 Ember, EU Power Sector in 2020 (London and Berlin: 2021),
https://ember-climate.org/project/eu-power-sector-2020.
344 Ibid.
345 UK BEIS, op. cit. note 310.
346 US EIA, “Table 7.2b – Electricity Net Generation”, in Monthly Energy
Review April 2021 (Washington, DC: 2021), https://www.eia.gov/
totalenergy/data/monthly/pdf/sec7_6 .
347 Clean Energy Council, Clean Energy Australia 2021 (Sydney:
2021), p. 7, https://assets.cleanenergycouncil.org.au/documents/
resources/reports/clean-energy-australia/clean-energy-
australia-report-2021 .
348 Based on total electricity production in 2020 of 7,623,600
GWh, solar energy production of 261,100 GWh, hydropower
production of 1,355,200 GWh and wind energy production of
466,500 GWh (based on grid-connected capacity), and total
electricity production in 2019 of 7,326,900 GWh, solar energy
production of 224,000, hydropower production of 1,302,100
GWh and wind energy production of 405,300 GWh, from
China Energy Portal, “2020 electricity & other energy statistics
(preliminary)”, 22 January 2021, https://chinaenergyportal.org/
en/2020-electricity-other-energy-statistics-preliminary.
349 Total global share from Ember, op. cit. note 2. Remaining countries
from the following: Denmark share of net generation based on
net generation data of 16,353 GWh from wind power, 1,181 GWh
from solar PV, and total net production of 27,907 GWh, from
Danish Energy Agency, “Månedlig elstatistik. Oversigtstabeller”, in
Electricity Supply, https://ens.dk/en/our-services/statistics-data-
key-figures-and-energy-maps/annual-and-monthly-statistics,
viewed 15 April 2021; Uruguay share of wind generation of 5,437.7
GWh, solar generation 525.5 GWh and total 13,470.5 GWh, from
Ministerio de Industria, Energía y Minería, “Balance Preliminar
2020”, https://ben.miem.gub.uy/preliminar.php; Ireland share
of wind as percentage of demand, based on provisional 2020
data (to be confirmed in May 2021) from EIRGRID, “System &
renewable summary report”, https://www.eirgridgroup.com/
how-the-grid-works/renewables, viewed 16 April 2021; Germany
share of gross electricity production of wind onshore 103,66
TWh, wind offshore 27,303 TWh (total wind: 130,963 TWh),
solar gross electricity production 50,6 TWh, and total gross
electricity production 558 TWh, from BMWi and AGEE Stat, op.
cit. note 310; Greece share of wind production of 9,323 GWh,
Solar PV production 3,898 GWh, solar rooftop PV 494 GWh,
and total 42,229.90 GWh, from Dapeep, “Μηνιαίο Δελτίο Ειδικού
Λογαριασμού ΑΠΕ & ΣΗΘΥΑ”, 2020, https://www.dapeep.gr/
wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_
ELAPE_v1.0_21.03.2021 , viewed April 2021, all in Greek and
provided by I. Tsipouridis, REDPro Consultants, Athens, personal
communication with REN21, 12 April 2021; Spain share of demand
coverage of wind 22.2%, and solar 6.1%, from Red Eléctrica
de España (REE), The Spanish Electricity System – Preliminary
Report 2020 (Madrid: February 2021), with estimated data as of
270
https://data.worldbank.org/indicator/SP.POP.TOTL
https://data.worldbank.org/indicator/SP.POP.TOTL
https://www.iea.org/reports/renewables-2020/covid-19-and-the-resilience-of-renewables
https://www.iea.org/reports/renewables-2020/covid-19-and-the-resilience-of-renewables
https://www.iea.org/reports/renewables-2020/covid-19-and-the-resilience-of-renewables
https://ec.europa.eu/energy/sites/ener/files/offshore_renewable_energy_strategy
https://ec.europa.eu/energy/sites/ener/files/offshore_renewable_energy_strategy
https://coalition.irena.org/-/media/Files/IRENA/Coalition-for-Action/IRENA_Coalition_Stimulating_Investment_in_Community_Energy_2020
https://coalition.irena.org/-/media/Files/IRENA/Coalition-for-Action/IRENA_Coalition_Stimulating_Investment_in_Community_Energy_2020
https://coalition.irena.org/-/media/Files/IRENA/Coalition-for-Action/IRENA_Coalition_Stimulating_Investment_in_Community_Energy_2020
Portugal’s second PV auction draws world record low bid of $0.0132/kWh
Portugal’s second PV auction draws world record low bid of $0.0132/kWh
http://taiyangnews.info/markets/record-low-e0-0355-winning-bid-in-german-auction
http://taiyangnews.info/markets/record-low-e0-0355-winning-bid-in-german-auction
https://www.windpowermonthly.com/article/1679862/greece-momentum-continues-record-onshore-prices
https://www.windpowermonthly.com/article/1679862/greece-momentum-continues-record-onshore-prices
https://www.windpowermonthly.com/article/1679862/greece-momentum-continues-record-onshore-prices
https://www.windpowermonthly.com/article/1684954/onshore-wind-dominates-latest-italian-energy-tender
https://www.windpowermonthly.com/article/1684954/onshore-wind-dominates-latest-italian-energy-tender
https://www.windpowermonthly.com/article/1679192/prices-hit-new-low-french-onshore
https://www.windpowermonthly.com/article/1679192/prices-hit-new-low-french-onshore
https://www.windpowermonthly.com/article/1682629/shell-advances-hydrogen-plan-eneco-deal
https://www.windpowermonthly.com/article/1682629/shell-advances-hydrogen-plan-eneco-deal
https://www.windpowermonthly.com/article/1671089/subsidy-free-wind-farm-wins-first-lithuanian-tender
https://www.windpowermonthly.com/article/1671089/subsidy-free-wind-farm-wins-first-lithuanian-tender
Greece awards nearly all wind, solar capacity at auction as prices drop
Greece awards nearly all wind, solar capacity at auction as prices drop
Greece awards nearly all wind, solar capacity at auction as prices drop
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/040320-france-awards-17-gw-renewables-projects-adjusts-2020-auction-schedule
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/040320-france-awards-17-gw-renewables-projects-adjusts-2020-auction-schedule
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/040320-france-awards-17-gw-renewables-projects-adjusts-2020-auction-schedule
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/040320-france-awards-17-gw-renewables-projects-adjusts-2020-auction-schedule
https://www.irena.org/publications/2019/Dec/Renewable-energy-auctions-Status-and-trends-beyond-price
https://www.irena.org/publications/2019/Dec/Renewable-energy-auctions-Status-and-trends-beyond-price
https://www.irena.org/publications/2019/Dec/Renewable-energy-auctions-Status-and-trends-beyond-price
https://doi.org/10.1002/pip.3189
https://energymonitor.ai/finance/sustainable-finance/dynamism-and-innovation-in-a-post-subsidy-renewables-market
https://energymonitor.ai/finance/sustainable-finance/dynamism-and-innovation-in-a-post-subsidy-renewables-market
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-the-covid-19-pandemic#abstract
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-the-covid-19-pandemic#abstract
https://www.iea.org/reports/electricity-market-report-december-2020/2020-global-overview-the-covid-19-pandemic#abstract
https://ember-climate.org/global-electricity-review-2021/methodology
https://ember-climate.org/global-electricity-review-2021/methodology
https://ember-climate.org/project/eu-power-sector-2020
https://www.eia.gov/totalenergy/data/monthly/pdf/sec7_6
https://www.eia.gov/totalenergy/data/monthly/pdf/sec7_6
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ben.miem.gub.uy/preliminar.php
https://www.eirgridgroup.com/how-the-grid-works/renewables
https://www.eirgridgroup.com/how-the-grid-works/renewables
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
ENDNOTES · GLOBAL OVERVIEW 01
EN
DN
OT
ES
I
GL
OB
AL
O
VE
RV
IE
W
13 January 2021, p. 15, https://www.ree.es/sites/default/files/
publication/2021/03/downloadable/avance_ISE_2020_EN ;
United Kingdom share of electricity generation of wind onshore
34.95 TWh, wind offshore 40.66 TWh, solar PV 12.8 TWh, and
total electricity generation 312.76 TWh, from UK BEIS, “Fuel used
in electricity generation and electricity supplied”, March 2021,
https://assets.publishing.service.gov.uk/government/uploads/
system/uploads/attachment_data/file/972781/ET_5.1_MAR_21.
xls; Portugal share of 12,067 GWh of wind production and
1,269 GWh of solar PV, and total production of 49,342 GWh,
from REN, “Dados Tecnicos / Technical Data 20”, p. 9, https://
www.centrodeinformacao.ren.pt/PT/InformacaoTecnica/
DadosTecnicos/AFnet_RENPRO%20Brochura%20Dados%20
T%C3%A9cnicos%202020 ; Australia share of wind of
22,196 GWh and solar PV of 22,288 GWh, and total generation
of 221,957 GWh from OpenNEM, “Western Australia (SWIS)”,
https://opennem.org.au/energy/wem/?range=all&interval=1y,
viewed 23 April 2021; The Netherlands provisional data for
net production of wind onshore 9,785 TWh and offshore 5,484
TWh, solar 8,056 TWh and total net production of 118,920
TWh, from CBS StatLine, “Electricity balance sheet; supply
and consumption”, https://opendata.cbs.nl/statline/#/CBS/en/
dataset/84575ENG/table?ts=1619216097037, viewed 3 May 2021;
Honduras power generation data on the National Interconnected
Electrical System – Energía Eléctrica Generada en el Sistema
Inteconectado Nacional, based on net generation of wind of
707,202.8 MWh, solar of 1,044,775.9 MWh, and total 9,292,817.3
MWh, from Empresa Nacional de Energía Eléctrica (ENEE),
Boletines Estadísticos Año 2020 – Diciembre, http://www.enee.
hn/index.php/planificacionicono/182-boletines-estadisticos;
Sweden share of wind of 27,589 GWh, solar 805 GWh, and total
159,635 GWh, from Statistics Sweden, “Elproduktion i Sverige
efter produktionsslag. Månad 2017M01 – 2021M02”, https://www.
statistikdatabasen.scb.se/pxweb/sv/ssd/START__EN__EN0108/
Elprod; Belgium share of wind onshore generation of 4.1 TWh
and offshore 6.7 TWh, and solar generation of 4.3 TWh, from Elia
Group, “Belgium’s electricity mix in 2020: Renewable generation
up 31% in a year marked by the COVID-19 crisis”, 7 January 2021,
https://www.elia.be/-/media/project/elia/shared/documents/
press-releases/2021/20210107-mix-electrique-2020_en ;
Chile wind generation of 5,537 GWh, and solar of 7,638 GWh,
from Generadoras de Chile, Generación Eléctrica en Chile, http://
generadoras.cl/generacion-electrica-en-chile; Nicaragua share
of wind net generation of 538,826 MWh and solar of 22,688
MWh, and total generation of 3,379,530 MWh, from Instituto
Nicaragüense de Energía, Ente Regulador, Generación Neta
Sistema Eléctrico Nacional Año 2020, https://www.ine.gob.ni/
DGE/estadisticas/2020/generacion_neta_dic20_actfeb21 ;
Italy share of wind generation of 18,547 GWh, solar generation
of 25,549 GWh, and total 273,108 GWh, from Terna, Rapporto
mensile sul Sistema Elettrico, https://download.terna.it/terna/
Rapporto_Mensile_Dicembre%202020_8d8b615dca4dafe .
350 For examples, see Systems Integration chapter and Teske, op. cit.
note 63.
351 See Wind Power section and Solar PV section in Market and
Industry chapter.
352 See Policy Landscape chapter.
353 W. Gorman et al., “Motivations and options for deploying hybrid
generator-plus-battery projects within the bulk power system”,
The Electricity Journal, June 2020, https://www.sciencedirect.com/
science/article/pii/S1040619020300312?via%3Dihub; N. Lee et al.,
“Hybrid floating solar photovoltaics-hydropower systems: Benefits
and global assessment of technical potential”, Renewable Energy,
vol. 162 (December 2020), pp. 1415-27, https://www.sciencedirect.
com/science/article/pii/S0960148120313252. Pairing technologies
not only side-by-side but at the same interconnection reduces
costs of equipment, siting, grid connection, financing as well as
operations and maintenance compared to separate projects while
also increasing capacity factor.
354 In addition, 13 provinces in China introduced policies
requiring a specific amount of energy storage be included in
the development of solar PV and wind power projects, from
Polaris Solar Photovoltaic Network, “Zhongguang Nuclear
5.7GW, China Resources 5GW… 3 months more than 45GW,
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20 October 2020, https://www.pv-magazine.com/2020/10/20/
wa-govt-approves-15-gw-asian-renewable-energy-hub-whole-
project-now-expanded-to-26-gw; J. M. Takouleu, “Gabon:
Ausar Energy and CDC launch the Ndjolé hybrid power plant
construction”, Afrik21, 5 February 2020, https://www.afrik21.africa/
en/gabon-ausar-energy-and-cdc-launch-the-ndjole-hybrid-
power-plant-construction; GE, “GE Renewable Energy to integrate
UK’s first DC-coupled battery energy storage system at Wykes’s
Chelveston Renewable Energy Wind-Solar Park”, 27 August 2020,
https://www.ge.com/news/press-releases/ge-renewable-energy-
integrate-uks-first-dc-coupled-battery-energy-storage-system;
E. Hancock, “Construction starts on Australia’s ‘largest’ hybrid
solar and battery energy storage system”, PV-Tech, 22 March 2021,
https://www.pv-tech.org/construction-starts-on-australias-largest-
hybrid-solar-and-battery-energy-storage-system; C. Keating,
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hybrid”, PV-Tech, 15 January 2020, https://www.pv-tech.org/
iberdrola-partners-with-dp-energy-for-maiden-australian-project;
Z. Shahan, “Largest renewable energy project in world will be 30
gigawatt solar–wind project in India”, CleanTechnica, 17 December
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energy-project-in-world-will-be-30-gigawatt-solar-wind-project-
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in Kutch”, 15 December 2020, https://thewire.in/politics/worlds-
largest-renewable-energy-park-opens-in-kutch; PR Newswire, “JA
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news-releases/ja-solar-supplies-modules-for-the-largest-solar-
wind-hybrid-project-in-south-korea-829837442.html; P. Hannen,
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27 August 2020, https://www.pv-magazine.com/2020/08/27/
new-solar-ppa-hybrid-pv-wind-project-in-germany; A. Dimitrova,
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Uni”, Renewables Now, 11 December 2020, https://renewablesnow.
com/news/engie-to-develop-gbp-8m-hybrid-renewables-project-
for-keele-uni-724226; G. Parkinson, “BP looks to add 1.5GW
wind and solar for huge renewable hydrogen project in W.A.”,
RenewEconomy, 13 May 2020, https://reneweconomy.com.au/
bp-looks-to-add-1-5gw-wind-and-solar-for-huge-renewable-
hydrogen-project-in-w-a-45931; “Goldwind to deliver turbines
to Oz hybrid scheme”, reNEWS, 5 August 2020, https://renews.
biz/62225/goldwind-to-deliver-turbines-to-oz-hybrid-scheme; U.
Gupta, “Renew Power wins 400 MW ‘round-the-clock’ renewables
auction at Rs2.90/kWh”, pv magazine, 09 May 2020, https://
www.pv-magazine-india.com/2020/05/09/renew-power-wins-
400-mw-round-the-clock-renewable-auction-at-rs-2-90-kwh;
M. Maisch, “56 MW hybrid microgrid powers up at Western
Australian gold mine”, pv magazine, 19 May 2020, https://www.
pv-magazine-australia.com/2020/05/19/56-mw-hybrid-microgrid-
powers-up-at-western-australian-gold-mine; J. S. Hill, “Aurora
project may still include solar thermal as 1414 signs with Vast Solar”,
RenewEconomy, 10 September 2020, https://reneweconomy.com.
au/aurora-project-may-still-include-solar-thermal-as-1414-signs-
with-vast-solar-65004; J. Scully, “Adani to develop 600MW solar-
wind hybrid project following SECI auction success”, PV-Tech, 4
January 2021, https://www.pv-tech.org/adani-to-develop-600mw-
solar-wind-hybrid-project-following-seci-auction-success; L.
Stoker, “Enel targets US multi-gigawatt solar, storage build-out
as maiden hybrid breaks ground”, PV-Tech, 22 July 2020, https://
www.pv-tech.org/enel-sets-sights-on-1gw-of-us-energy-storage-
as-it-co-locates-first-with-so; L. Collins, “World first for solid-state
green hydrogen at hybrid solar project”, Recharge, 11 March
2020, https://www.rechargenews.com/transition/world-first-for-
solid-state-green-hydrogen-at-hybrid-solar-project/2-1-771319;
E. Bellini, “Malian gold mine to be powered by 3.9 MW/2.6 MWh
solar-plus-storage plant”, pv magazine, 28 October 2020, https://
www.pv-magazine.com/2020/10/28/malian-gold-mine-to-
be-powered-by-3-9-mw-2-6-mwh-solar-plus-storage-plant;
D. Mavrokefalidis, “Statkraft to manage ‘UK’s largest solar and
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www.energylivenews.com/2020/06/01/statkraft-to-manage-uks-
largest-solar-and-battery-storage-project; A. Colthorpe, “California
community energy group signs PPA for 400MW / 540MWh solar-
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https://www.energy-storage.news/news/california-community-
energy-group-signs-ppa-for-400mw-540mwh-solar-plus-sto; J.
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www.pv-tech.org/elecnor-secures-epc-contract-for-australias-
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WA Govt approves 15 GW Asian Renewable Energy Hub, whole project now expanded to 26 GW
WA Govt approves 15 GW Asian Renewable Energy Hub, whole project now expanded to 26 GW
WA Govt approves 15 GW Asian Renewable Energy Hub, whole project now expanded to 26 GW
GABON: Ausar Energy and CDC launch the Ndjolé hybrid power plant construction
GABON: Ausar Energy and CDC launch the Ndjolé hybrid power plant construction
GABON: Ausar Energy and CDC launch the Ndjolé hybrid power plant construction
https://www.ge.com/news/press-releases/ge-renewable-energy-integrate-uks-first-dc-coupled-battery-energy-storage-system
https://www.ge.com/news/press-releases/ge-renewable-energy-integrate-uks-first-dc-coupled-battery-energy-storage-system
Construction starts on Australia’s ‘largest’ hybrid solar and battery energy storage system
Construction starts on Australia’s ‘largest’ hybrid solar and battery energy storage system
Iberdrola teams up with DP Energy for 320MW Aussie wind-solar hybrid
Iberdrola teams up with DP Energy for 320MW Aussie wind-solar hybrid
Largest Renewable Energy Project In World Will Be 30 Gigawatt Solar–Wind Project In India
Largest Renewable Energy Project In World Will Be 30 Gigawatt Solar–Wind Project In India
Largest Renewable Energy Project In World Will Be 30 Gigawatt Solar–Wind Project In India
https://thewire.in/politics/worlds-largest-renewable-energy-park-opens-in-kutch
https://thewire.in/politics/worlds-largest-renewable-energy-park-opens-in-kutch
https://www.prnewswire.com/ae/news-releases/ja-solar-supplies-modules-for-the-largest-solar-wind-hybrid-project-in-south-korea-829837442.html
https://www.prnewswire.com/ae/news-releases/ja-solar-supplies-modules-for-the-largest-solar-wind-hybrid-project-in-south-korea-829837442.html
https://www.prnewswire.com/ae/news-releases/ja-solar-supplies-modules-for-the-largest-solar-wind-hybrid-project-in-south-korea-829837442.html
https://renewablesnow.com/news/engie-to-develop-gbp-8m-hybrid-renewables-project-for-keele-uni-724226
https://renewablesnow.com/news/engie-to-develop-gbp-8m-hybrid-renewables-project-for-keele-uni-724226
https://renewablesnow.com/news/engie-to-develop-gbp-8m-hybrid-renewables-project-for-keele-uni-724226
BP looks to add 1.5GW wind and solar for huge renewable hydrogen project in W.A.
BP looks to add 1.5GW wind and solar for huge renewable hydrogen project in W.A.
BP looks to add 1.5GW wind and solar for huge renewable hydrogen project in W.A.
https://renews.biz/62225/goldwind-to-deliver-turbines-to-oz-hybrid-scheme
https://renews.biz/62225/goldwind-to-deliver-turbines-to-oz-hybrid-scheme
Renew Power wins 400 MW ‘round-the-clock’ renewables auction at Rs2.90/kWh
Renew Power wins 400 MW ‘round-the-clock’ renewables auction at Rs2.90/kWh
Renew Power wins 400 MW ‘round-the-clock’ renewables auction at Rs2.90/kWh
56 MW hybrid microgrid powers up at Western Australian gold mine
56 MW hybrid microgrid powers up at Western Australian gold mine
56 MW hybrid microgrid powers up at Western Australian gold mine
Aurora project may still include solar thermal as 1414 signs with Vast Solar
Aurora project may still include solar thermal as 1414 signs with Vast Solar
Aurora project may still include solar thermal as 1414 signs with Vast Solar
Adani to develop 600MW solar-wind hybrid project following SECI auction success
Adani to develop 600MW solar-wind hybrid project following SECI auction success
Enel targets US multi-gigawatt solar, storage build-out as maiden hybrid breaks ground
Enel targets US multi-gigawatt solar, storage build-out as maiden hybrid breaks ground
Enel targets US multi-gigawatt solar, storage build-out as maiden hybrid breaks ground
https://www.rechargenews.com/transition/world-first-for-solid-state-green-hydrogen-at-hybrid-solar-project/2-1-771319
https://www.rechargenews.com/transition/world-first-for-solid-state-green-hydrogen-at-hybrid-solar-project/2-1-771319
Malian gold mine to be powered by 3.9 MW/2.6 MWh solar-plus-storage plant
Malian gold mine to be powered by 3.9 MW/2.6 MWh solar-plus-storage plant
Malian gold mine to be powered by 3.9 MW/2.6 MWh solar-plus-storage plant
Statkraft to manage ‘UK’s largest solar and battery storage project’
Statkraft to manage ‘UK’s largest solar and battery storage project’
Statkraft to manage ‘UK’s largest solar and battery storage project’
https://www.energy-storage.news/news/california-community-energy-group-signs-ppa-for-400mw-540mwh-solar-plus-sto
https://www.energy-storage.news/news/california-community-energy-group-signs-ppa-for-400mw-540mwh-solar-plus-sto
https://www.pv-tech.org/elecnor-secures-epc-contract-for-australias-largest-solar-plus-pstorage-project
https://www.pv-tech.org/elecnor-secures-epc-contract-for-australias-largest-solar-plus-pstorage-project
https://www.pv-tech.org/elecnor-secures-epc-contract-for-australias-largest-solar-plus-pstorage-project
ENDNOTES · GLOBAL OVERVIEW 01
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SolarPACES, 25 April 2020, https://www.solarpaces.org/morocco-
pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project; V.
Godinho, “Dubai’s Mohammed bin Rashid Al Maktoum Solar Park
to have world’s largest energy storage capacity”, Gulf Business, 29
November 2020, https://gulfbusiness.com/dubais-mohammed-
bin-rashid-al-maktoum-solar-park-to-have-worlds-largest-energy-
storage-capacity; K. Pickerel, “Dept. of Interior approves plans
for 690-MW Gemini solar project with 1,400-MWh battery”, Solar
Power World, 11 May 2020, https://www.solarpowerworldonline.
com/2020/05/dept-of-interior-approves-plans-for-690-mw-
gemini-solar-project-with-1400-mwh-battery; GE, “GE Renewable
Energy to supply DC-coupled system to Convergent for 123 MWh
hybrid solar plus storage project in upstate New York”, 16 March
2021, https://www.ge.com/news/press-releases/ge-renewable-
energy-to-supply-dc-coupled-system-to-convergent-for-123-mwh-
hybrid-solar-storage-project-upstate-new-york.
355 T. Ramschak, AEE INTEC, Austria, personal communication with
REN21, April 2021. See Solar Thermal Heating section in Market
and Industry chapter.
272
https://www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project
https://www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project
Dubai’s Mohammed bin Rashid Al Maktoum Solar Park to have world’s largest energy storage capacity
Dubai’s Mohammed bin Rashid Al Maktoum Solar Park to have world’s largest energy storage capacity
Dubai’s Mohammed bin Rashid Al Maktoum Solar Park to have world’s largest energy storage capacity
Dept. of Interior approves plans for 690-MW Gemini solar project with 1,400-MWh battery
Dept. of Interior approves plans for 690-MW Gemini solar project with 1,400-MWh battery
Dept. of Interior approves plans for 690-MW Gemini solar project with 1,400-MWh battery
https://www.ge.com/news/press-releases/ge-renewable-energy-to-supply-dc-coupled-system-to-convergent-for-123-mwh-hybrid-solar-storage-project-upstate-new-york
https://www.ge.com/news/press-releases/ge-renewable-energy-to-supply-dc-coupled-system-to-convergent-for-123-mwh-hybrid-solar-storage-project-upstate-new-york
https://www.ge.com/news/press-releases/ge-renewable-energy-to-supply-dc-coupled-system-to-convergent-for-123-mwh-hybrid-solar-storage-project-upstate-new-york
ENDNOTES · POLICY L ANDSCAPE 02
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1 International Energy Agency (IEA), Renewables 2020: Analysis
and Forecast to 2025 (Paris: 2020), p. 146, https://www.iea.org/
reports/renewables-2020/key-trends-to-watch.
2 This chapter is intended to be only indicative of the overall
landscape of policy activity and is not a definitive reference.
Generally, listed policies are those that have been enacted by
legislative bodies. Some of the listed policies may not yet be
implemented, or are awaiting detailed implementing regulations. It
is difficult to capture every policy change, so some policies may be
unintentionally omitted or incorrectly listed. This report does not
cover policies and activities related to technology transfer, capacity
building, carbon finance and Clean Development Mechanism
projects, nor does it attempt to provide a comprehensive list of
broader framework and strategic policies – all of which are still
important to renewable energy progress. For the most part, this
report also does not cover policies that are still under discussion
or formulation, except to highlight overall trends. Information
on policies comes from a wide variety of sources, including
the IEA and International Renewable Energy Agency (IRENA)
Global Renewable Energy Policies and Measures Database, the
US Database of State Incentives for Renewables & Efficiency
(DSIRE), press reports, submissions from REN21 regional- and
country-specific contributors and a wide range of United Nations
unpublished data. Table 6 and Figures 10–16 are based on
numerous sources cited throughout this chapter.
3 “Global corporate clean energy purchasing up 18% in 2020”,
Renewable Energy World, 27 January 2021, https://www.
renewableenergyworld.com/solar/global-corporate-clean-
energy-purchasing-up-18-in-2020; IEA, op. cit. note 1, p. 146;
IRENA, Renewable Power Generation Costs in 2019 (Abu
Dhabi: 2020), https://www.irena.org/publications/2020/Jun/
Renewable-Power-Costs-in-2019; Institute for Energy Economics
and Financial Analysis, “Study shows renewables cheaper than
fossil fuels across Middle East, North Africa region”, 28 April
2020, https://ieefa.org/study-shows-renewables-cheaper-
than-fossil-fuels-across-middle-east-north-africa-region;
Carbon Brief, “Solar is now ‘cheapest electricity in history’,
confirms IEA”, 13 October 2020, https://www.carbonbrief.org/
solar-is-now-cheapest-electricity-in-history-confirms-iea.
4 Data in this paragraph are from the REN21 Policy Database and
can be accessed in Reference Tables R3-R8 in the GSR 2021
Data Pack, www.ren21.net/gsr-2021.
5 Energy Policy Tracker, https://www.energypolicytracker.org,
updated 20 January 2021; T. Lei Win, “Reuters, G20 countries
still backing fossil fuels through COVID-19 response”, Reuters,
9 November 2020,,https://www.reuters.com/article/us-g20-
climatechange-energy-trfn-idUSKBN27Q00Q. Sidebar 3 based
on the following sources: IEA, op. cit. note 1; Y. Dagnet and J.
Jaeger, “Not enough climate action in stimulus plans”, World
Resources Institute (WRI) Blog, 15 September 2020, https://
www.wri.org/blog/2020/09/coronavirus-green-economic-
recovery; S. Kaplan and D. Grandoni, “Stimulus deal includes
raft of provisions to fight climate change”, Washington Post, 21
December 2020, https://www.washingtonpost.com/climate-
solutions/2020/12/21/congress-climate-spending; Energy Policy
Tracker, “G20 countries”, https://www.energypolicytracker.
org/region/g20, viewed 26 January 2021. The EU’s recovery
package includes EUR 91 billion (USD 112 billion) a year for green
incentives like low-interest loans to drive sustainable building
initiatives across the continent, including renewable heating
systems, rooftop solar, batteries and energy efficiency measures.
For renewable energy, the EU committed to tender 15 GW of new
capacity over the coming two years, with expected investments
of EUR 25 billion (USD 31 billion), focused particularly on
large-scale solar and wind. The EU package also focuses on
the production of hydrogen from renewable electricity, boosting
funding for this to EUR 1.3 billion (USD 1.6 billion). For transport,
the package provides EUR 20 billion (USD 25 billion) to drive
the shift to electric and other zero-emission vehicles, including
the installation of 1 million EV charging stations by 2025. The
package also includes EUR 40-60 billion (USD 49-74 billion)
of investments in zero-emission trains. S. Vorrath, “EU unveils
‘green’ Covid recovery plan, leaves Australia wallowing in coal
dust”, RenewEconomy, 28 May 2020, https://reneweconomy.
com.au/eu-unveils-green-covid-recovery-plan-leaves-australia-
wallowing-in-coal-dust-39319; IEA, op. cit. note 1, pp. 142-44;
Clean Energy Canada, “Media brief: A summary of international
clean stimulus efforts”, 29 May 2020, https://cleanenergycanada.
org/media-brief-a-summary-of-international-clean-stimulus-
efforts; “Doosan Heavy I&C gets another $1bn, raising total state
bailout to near $3 bn”, Pulse, 2 June 2020, https://pulsenews.
co.kr/view.php?year=2020&no=564186; “Green Stimulus Index:
An assessment of the orientation of COVID-19 stimulus in relation
to climate change, biodiversity and other environmental impacts”,
Vivid Economics, 3 June 2020, https://www.vivideconomics.
com/wp-content/uploads/2020/06/200605-Green-Stimulus-
Index-1 ; C. Farand, “India eyes private investment to open
41 new coal mines”, Climate Home News, 19 June 2020, https://
www.climatechangenews.com/2020/06/19/india-eyes-private-
investment-open-41-new-coal-mines; fossil fuel support in India
and the Republic of Korea from Energy Policy Tracker, https://
www.energypolicytracker.org, viewed February 2021; fossil
fuel support in Canada and the United Kingdom from Alberta,
“Investing in Keystone XL pipeline”, https://www.alberta.ca/
investing-in-keystone-xl-pipeline.aspx, viewed February 2021,
and from D. Barmes et al., The Covid Corporate Financing Facility.
Where Are the Conditions for the Billion £ Bailouts? (London:
PositiveMoney, July 2020), http://positivemoney.org/wp-content/
uploads/2020/07/CCFF-Final-version ; International Institute
for Sustainable Development (IISD), “Sustainable recovery in
Colombia: President underlines ambitions”, 31 August 2020,
https://www.iisd.org/sustainable-recovery/news/sustainable-
recovery-in-colombia-president-underlines-ambitions; E.
Bellini, “Israel’s plan to recover from Covid-19 crisis includes
2 GW of New Solar”, pv magazine, 29 April 2020, https://www.
pv-magazine.com/2020/04/29/israels-plan-to-recover-from-
covid-19-crisis-includes-2-gw-of-new-solar; Federal Republic
of Nigeria, Bouncing Back: Nigeria Economic Sustainability
Plan (Lagos: 2020), p. 22, https://nipc.gov.ng/wp-content/
uploads/2020/09/NG-Economic-Sustainability-Plan-2020.
pdf; C. Morehouse, “Federal stimulus includes wind, solar tax
credit extensions, adds first US offshore wind tax credit”, Utility
Dive, 22 December 2020, https://www.utilitydive.com/news/
federal-stimulus-includes-wind-solar-tax-credit-extensions-adds-
first-us/592572; H. Cooper and P. Tingle, “COVID-19 stimulus
bill includes key renewable energy tax credits”, National Law
Review, 28 December 2020, https://www.natlawreview.com/
article/covid-19-stimulus-bill-includes-key-renewable-energy-
tax-credits; Fredrikson & Byron PA, “New stimulus brings
another extension for renewable energy tax credits”, Lexology,
29 December 2020, https://www.lexology.com/library/detail.
aspx?g=070f5f1a-4922-4b10-b10f-ea10f7331d2a; J. Cossardeaux,
“Plan de relance: la transition ecologique se taille la part du lion”,
3 September 2020, https://www.lesechos.fr/politique-societe/
societe/plan-de-relance-la-transition-ecologique-se-taille-la-
part-du-lion-1238889; A. Garric et al., “Le chantier sans fin de
la rénovation thermique”, Le Monde, 5 October 2020, https://
www.lemonde.fr/economie/article/2020/10/05/le-chantier-
sans-fin-de-la-renovation-thermique_6054748_3234.html; H.
Shin and S. Cha, “The Republic of Korea to spend $95 billion on
green projects to boost economy”, Reuters, 14 July 2020, https://
www.reuters.com/article/us-southkorea-president-newdeal/
south-korea-to-spend-95-billion-on-green-projects-to-boost-
economy-idUSKCN24F0GA; J. Spaes, “France devotes €30 billion
to energy transition”, pv magazine, 4 September 2020, https://
www.pv-magazine.com/2020/09/04/france-devotes-e30-billion-
to-energy-transition. However, actual spending will depend on
the annual budget of the corresponding ministry. Government of
Germany, “Policies, measures and actions on climate change and
environmental protection in the context of COVID-19 recovery:
Germany”, https://platform2020redesign.org/countries/germany,
updated 17 September 2020; D. Loy, Loy Energy Consulting,
personal communication with REN21, 19 January 2021; S. Morgan,
“Spain underpins car sector bailout with green goals”, EURACTIV,
15 June 2020, https://www.euractiv.com/section/transport/
news/spain-underpins-car-sector-bailout-with-green-goals;
EUobserver, “Spain unveils €3.75bn rescue package for car
industry”, 16 June 2020, https://euobserver.com/tickers/148653;
M. Planelles, “Spain to provide up to €4,000 in subsidies for
purchase of a new car”, El Pais, 16 June 2020, https://english.
elpais.com/economy_and_business/2020-06-16/spain-to-
provide-up-to-4000-in-subsidies-for-purchasing-a-new-car.html.
6 Based on information and sources used throughout this chapter.
7 Box 4 based on the following sources: J. Spaes, “Mali exempts
solar from VAT, import duties”, pv magazine, 7 April 2020,
https://www.pv-magazine.com/2020/04/07/mali-exempts-
solar-from-vat-import-duties; N. Karume, “New energy policy
273
https://www.iea.org/reports/renewables-2020/key-trends-to-watch
https://www.iea.org/reports/renewables-2020/key-trends-to-watch
https://www.irena.org/publications/2020/Jun/Renewable-Power-Costs-in-2019
https://www.irena.org/publications/2020/Jun/Renewable-Power-Costs-in-2019
https://ieefa.org/study-shows-renewables-cheaper-than-fossil-fuels-across-middle-east-north-africa-region
https://ieefa.org/study-shows-renewables-cheaper-than-fossil-fuels-across-middle-east-north-africa-region
Solar is now ‘cheapest electricity in history’, confirms IEA
Solar is now ‘cheapest electricity in history’, confirms IEA
http://www.ren21.net/gsr-2021
https://www.reuters.com/article/us-g20-climatechange-energy-trfn-idUSKBN27Q00Q
https://www.reuters.com/article/us-g20-climatechange-energy-trfn-idUSKBN27Q00Q
https://www.wri.org/blog/2020/09/coronavirus-green-economic-recovery
https://www.wri.org/blog/2020/09/coronavirus-green-economic-recovery
https://www.wri.org/blog/2020/09/coronavirus-green-economic-recovery
https://www.washingtonpost.com/climate-solutions/2020/12/21/congress-climate-spending
https://www.washingtonpost.com/climate-solutions/2020/12/21/congress-climate-spending
EU unveils “green” Covid recovery plan, leaves Australia wallowing in coal dust
EU unveils “green” Covid recovery plan, leaves Australia wallowing in coal dust
EU unveils “green” Covid recovery plan, leaves Australia wallowing in coal dust
Media brief: A summary of international clean stimulus efforts
Media brief: A summary of international clean stimulus efforts
Media brief: A summary of international clean stimulus efforts
https://pulsenews.co.kr/view.php?year=2020&no=564186
https://pulsenews.co.kr/view.php?year=2020&no=564186
https://www.vivideconomics.com/wp-content/uploads/2020/06/200605-Green-Stimulus-Index-1
https://www.vivideconomics.com/wp-content/uploads/2020/06/200605-Green-Stimulus-Index-1
https://www.vivideconomics.com/wp-content/uploads/2020/06/200605-Green-Stimulus-Index-1
https://www.alberta.ca/investing-in-keystone-xl-pipeline.aspx
https://www.alberta.ca/investing-in-keystone-xl-pipeline.aspx
http://positivemoney.org/wp-content/uploads/2020/07/CCFF-Final-version
http://positivemoney.org/wp-content/uploads/2020/07/CCFF-Final-version
https://www.iisd.org/sustainable-recovery/news/sustainable-recovery-in-colombia-president-underlines-ambitions
https://www.iisd.org/sustainable-recovery/news/sustainable-recovery-in-colombia-president-underlines-ambitions
Israel’s plan to recover from Covid-19 crisis includes 2 GW of new solar
Israel’s plan to recover from Covid-19 crisis includes 2 GW of new solar
Israel’s plan to recover from Covid-19 crisis includes 2 GW of new solar
https://nipc.gov.ng/wp-content/uploads/2020/09/NG-Economic-Sustainability-Plan-2020
https://nipc.gov.ng/wp-content/uploads/2020/09/NG-Economic-Sustainability-Plan-2020
https://nipc.gov.ng/wp-content/uploads/2020/09/NG-Economic-Sustainability-Plan-2020
https://www.utilitydive.com/news/federal-stimulus-includes-wind-solar-tax-credit-extensions-adds-first-us/592572
https://www.utilitydive.com/news/federal-stimulus-includes-wind-solar-tax-credit-extensions-adds-first-us/592572
https://www.utilitydive.com/news/federal-stimulus-includes-wind-solar-tax-credit-extensions-adds-first-us/592572
https://www.natlawreview.com/article/covid-19-stimulus-bill-includes-key-renewable-energy-tax-credits
https://www.natlawreview.com/article/covid-19-stimulus-bill-includes-key-renewable-energy-tax-credits
https://www.natlawreview.com/article/covid-19-stimulus-bill-includes-key-renewable-energy-tax-credits
https://www.lexology.com/library/detail.aspx?g=070f5f1a-4922-4b10-b10f-ea10f7331d2a
https://www.lexology.com/library/detail.aspx?g=070f5f1a-4922-4b10-b10f-ea10f7331d2a
https://www.lesechos.fr/politique-societe/societe/plan-de-relance-la-transition-ecologique-se-taille-la-part-du-lion-1238889
https://www.lesechos.fr/politique-societe/societe/plan-de-relance-la-transition-ecologique-se-taille-la-part-du-lion-1238889
https://www.lesechos.fr/politique-societe/societe/plan-de-relance-la-transition-ecologique-se-taille-la-part-du-lion-1238889
https://www.lemonde.fr/economie/article/2020/10/05/le-chantier-sans-fin-de-la-renovation-thermique_6054748_3234.html
https://www.lemonde.fr/economie/article/2020/10/05/le-chantier-sans-fin-de-la-renovation-thermique_6054748_3234.html
https://www.lemonde.fr/economie/article/2020/10/05/le-chantier-sans-fin-de-la-renovation-thermique_6054748_3234.html
https://www.reuters.com/article/us-southkorea-president-newdeal/south-korea-to-spend-95-billion-on-green-projects-to-boost-economy-idUSKCN24F0GA
https://www.reuters.com/article/us-southkorea-president-newdeal/south-korea-to-spend-95-billion-on-green-projects-to-boost-economy-idUSKCN24F0GA
https://www.reuters.com/article/us-southkorea-president-newdeal/south-korea-to-spend-95-billion-on-green-projects-to-boost-economy-idUSKCN24F0GA
https://www.reuters.com/article/us-southkorea-president-newdeal/south-korea-to-spend-95-billion-on-green-projects-to-boost-economy-idUSKCN24F0GA
https://platform2020redesign.org/countries/germany
https://euobserver.com/tickers/148653
https://english.elpais.com/economy_and_business/2020-06-16/spain-to-provide-up-to-4000-in-subsidies-for-purchasing-a-new-car.html
https://english.elpais.com/economy_and_business/2020-06-16/spain-to-provide-up-to-4000-in-subsidies-for-purchasing-a-new-car.html
https://english.elpais.com/economy_and_business/2020-06-16/spain-to-provide-up-to-4000-in-subsidies-for-purchasing-a-new-car.html
ENDNOTES · POLICY L ANDSCAPE 02
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PEto promote solar and geothermal sectors in Uganda”, PUMPS
Africa, 17 January 2020, http://www.pumps-africa.com/
new-energy-policy-to-promote-solar-and-geothermal-sectors-
in-uganda-2; J. E. Rodriguez, Colibri Energy SAS, personal
communication with REN21, 19 January 2021; J. M. Takouleu,
“Senegal: Government exempts renewable energy equipment
from VAT” Afrik21, 5 August 2020, https://www.afrik21.africa/en/
senegal-government-exempts-renewable-energy-equipment-
from-vat; C. Mwirigi, “Senegal introduces VAT exemption for
off-grid solar products”, pv magazine, 2 September 2020, https://
www.pv-magazine.com/2020/09/02/senegal-introduces-vat-
exemption-for-off-grid-solar-products; “Plan unveiled to increase
local content in Saudi renewable energy industry chains”, Asharq
Al-Awsat, 12 January 2020, https://aawsat.com/english/home/
article/2078831/plan-unveiled-increase-local-content-saudi-
renewable-energy-industry-chains; U. Gupta, “PV imports to
face 20-25% customs duty in India”, pv magazine, 26 June 2020,
https://www.pv-magazine.com/2020/06/26/pv-panel-imports-
to-face-20-25-customs-duty-in-india-from-august; “Govt
working on mega plan to triple solar manufacturing capacity”,
Economic Times, 4 July 2020, https://energy.economictimes.
indiatimes.com/news/renewable/govt-working-on-mega-
plan-to-triple-solar-manufacturing-capacity/76786536; S.
Patel, “Trump ban on foreign bulk power equipment triggers
new uncertainty”, Power Magazine, 7 May 2020, https://www.
powermag.com/trump-ban-on-foreign-bulk-power-equipment-
triggers-new-uncertainty; B. Publicover, “Burkina Faso kicks
off ‘Solar Cluster’ plan”, pv magazine, 8 July 2020, https://www.
pv-magazine.com/2020/07/08/burkina-faso-kicks-off-solar-
cluster-plan; E. Bellini, “Turkey sets new rules for solar module
imports”, pv magazine, 15 April 2020, https://www.pv-magazine.
com/2020/04/15/turkey-sets-new-rules-for-solar-module-
imports; P. Sánchez Molina, “Brazil eliminates import duties for
cells, modules, inverters and trackers”, pv magazine, 2 July 2020,
https://www.pv-magazine.com/2020/07/22/brazil-eliminates-
import-duties-for-cells-modules-inverters-and-trackers; S.
Islam, “Bangladesh opens €200m loan fund for eco-friendly
imports”, pv magazine, 27 April 2020, https://www.pv-magazine.
com/2020/04/27/bangladesh-opens-e200m-loan-fund-for-eco-
friendly-imports; “BB introduces €200m green transformation
fund”, Dhaka Tribune, 15 April 2020, https://www.dhakatribune.
com/business/banks/2020/04/15/bb-introduces-200m-green-
transformation-fund; U. Bhaskar, “New tariffs on import of solar
cells and modules on the cards”, Hindustan Times, 14 December
2020, https://www.hindustantimes.com/business-news/new-
tariffs-on-import-of-solar-cells-and-modules-on-the-cards/
story-MlTA8w0MZ0XykyM23Y5bcK.html; R. Ranjan, “2020
a look back: Developments that shaped the solar sector”,
Mercom India, 29 December 2020, https://mercomindia.
com/2020-look-back-developments-solar.
8 New/updated NDCs were submitted by Andorra, Argentina,
Australia, Bangladesh, Brazil, Brunei, Cambodia, Chile, Colombia,
Costa Rica, Cuba, the Dominican Republic, Fiji, Ethiopia,
Grenada, Japan, Jamaica, Kenya, Maldives, Marshall Islands,
Mexico, Monaco, Norway, Moldova, Mongolia, Nepal, New
Zealand, Nicaragua, Norway, Panama, Papua New Guinea,
Peru, the Republic of Korea, the Russian Federation, Rwanda,
Senegal, Singapore, Suriname, Switzerland, Thailand, Tonga,
the United Arab Emirates, the United Kingdom, Vietnam and
Zambia. The EU’s 27 Member States are considered one bloc.
J. Gabbatiss, “Which countries met the UN’s 2020 deadline
to raise ‘climate ambition’?” Carbon Brief, 9 January 2021,
https://www.carbonbrief.org/analysis-which-countries-met-
the-uns-2020-deadline-to-raise-climate-ambition; United
Nations Framework Convention on Climate Change (UNFCCC),
“Nationally Determined Contributions (NDCs)”, https://unfccc.
int/process-and-meetings/the-paris-agreement/nationally-
determined-contributions-ndcs/nationally-determined-
contributions-ndcs, viewed 2 February 2021; UNFCCC, “NDC
Synthesis Report”, https://unfccc.int/process-and-meetings/
the-paris-agreement/nationally-determined-contributions-ndcs/
nationally-determined-contributions-ndcs/ndc-synthesis-report,
viewed 2 February 2021. Figure 12 based on the following: carbon
pricing policies from World Bank, “Carbon Pricing Dashboard”,
https://carbonpricingdashboard.worldbank.org/map_data,
viewed 11 January 2021; net zero emission targets from Energy
and Climate Intelligence Unit, “Net Zero Tracker”, https://eciu.
net/netzerotracker, viewed 11 January 2021 (unless specified; see
GSR 2021 Data Pack); fossil fuel ban data from various sources
compiled in the REN21 Policy Database. See Reference Tables
R4, R6, and R9 in GSR 2021 Data Pack for details.
9 Table 4 based on 2019 data from European Commission,
Emissions Database for Global Atmospheric Research (EDGAR),
Joint Research Centre Data Catalogue, https://data.jrc.ec.europa.
eu/dataset/jrc-edgar-emissiontimeseriesv41.
10 “China, top global emitter, aims to go carbon-neutral by
2060”, CBC, 23 September 2020, https://www.cbc.ca/news/
technology/china-carbon-neutral-1.5735172; F. Harvey, “China
pledges to become carbon neutral before 2060”, The Guardian
(UK), 22 September 2020, https://www.theguardian.com/
environment/2020/sep/22/china-pledges-to-reach-carbon-
neutrality-before-2060; E. Lies, “PM Suga says Japan will attain
zero-emissions, carbon neutral society by 2050”, Reuters, 26
October 2020, https://www.reuters.com/article/japan-politics-
suga/pm-suga-says-japan-will-attain-zero-emissions-carbon-
neutral-society-by-2050-idUKL4N2HE2HS; S. Denyer and
A. Kashiwagi, “Japan, world’s third largest economy, vows to
become carbon neutral by 2050”, Washington Post, 26 October
2020, https://www.washingtonpost.com/world/japan-climate-
emissions/2020/10/26/b6ea2b5a-1752-11eb-8bda-814ca56e138b_
story.html; J. McCurry, “South Korea vows to go carbon neutral by
2050 to fight climate emergency”, 28 October 2020, https://www.
theguardian.com/world/2020/oct/28/south-korea-vows-to-go-
carbon-neutral-by-2050-to-fight-climate-emergency.
11 Data for 2019 from World Bank, “Carbon Pricing Dashboard”,
https://carbonpricingdashboard.worldbank.org, viewed 22
December 2020; data for 2020 from World Bank, “Carbon Pricing
Dashboard”, https://carbonpricingdashboard.worldbank.org,
viewed 22 October 2019.
12 “Montenegro introduces cap and trade scheme for major CO2
emitters”, Reuters, 24 February 2020, https://www.reuters.com/
article/us-montenegro-climate/montenegro-introduces-cap-
and-trade-scheme-for-major-co2-emitters-idUSKCN20I18O;
Government of Mexico, “Programa de prueba del sistema de
comercio de emisiones”, 5 March 2021, https://www.gob.mx/
semarnat/acciones-y-programas/programa-de-prueba-del-
sistema-de-comercio-de-emisiones-179414.
13 M. Mazengarb, “NZ puts hard cap on emissions for first time to
strengthen its trading scheme”, RenewEconomy, 2 June 2020,
https://reneweconomy.com.au/nz-puts-hard-cap-on-emissions-
for-first-time-to-strengthen-its-trading-scheme-27417.
14 France, Ireland, Italy, Portugal, the Slovak Republic, Sweden
and the United Kingdom also plan to exit coal by 2025. J. Tirone,
“Austria ends coal era and commits to more renewable energy”,
The Financial Post, 17 April 2020, https://business.financialpost.
com/pmn/business-pmn/austria-ends-coal-era-and-commits-to-
more-renewable-energy; M. Willuhn, “Sweden exits coal two years
early”, pv magazine, 22 April 2020, https://www.pv-magazine.
com/2020/04/22/sweden-exits-coal-two-years-early.
15 The Coal Phase-Out Act indicates that no new coal-fired plants
may start operating after 14 August 2020 (with the exception of
those that received a licence to operate before 29 January 2020).
The Act also provides financial compensation for operators
of coal-fired plants and sets out amendments to the German
Renewable Energy Sources Act which enshrine into law the
German goal of 65% renewable power by 2030. J. Gesley,
“Germany: Law on phasing-out coal-powered energy by 2038
enters into force”, Global Legal Monitor, 31 August 2020, https://
www.loc.gov/law/foreign-news/article/germany-law-on-phasing-
out-coal-powered-energy-by-2038-enters-into-force; F. Schulz,
“German cabinet approves final ‘Coal Phase-out Act’”, EURACTIV,
25 June 2020, https://www.euractiv.com/section/energy/news/
german-cabinet-finally-approves-the-coal-phase-out; “Germany
adds brown coal to energy exit under landmark deal”, Reuters,
16 January 2020, https://www.reuters.com/article/us-climate-
change-germany-coal/germany-adds-brown-coal-to-energy-
exit-under-landmark-deal-idUSKBN1ZF0OS.
16 Around 100 older, low-efficiency coal plants are expected to
close as a result. “Japan to accelerate closure of old coal power
plants”, Reuters, 2 July 2020, https://www.reuters.com/article/
us-japan-powerstation-coal/japan-to-accelerate-closure-of-old-
coal-power-plants-idUSKBN2440AA; T. Sawa, “Plan to phase out
inefficient coal plants breaks no new ground”, Japan Times,
7 August 2020, https://www.japantimes.co.jp/opinion/2020/08/
07/commentary/japan-commentary/meti-coal-plants-energy.
17 H. Alcoseba Fernandez, “Philippines announces moratorium on
new coal power”, Eco-Business, 28 October 2020, https://www.
274
New energy policy to promote solar and geothermal sectors in Uganda
New energy policy to promote solar and geothermal sectors in Uganda
New energy policy to promote solar and geothermal sectors in Uganda
SENEGAL: Government exempts renewable energy equipment from VAT
SENEGAL: Government exempts renewable energy equipment from VAT
SENEGAL: Government exempts renewable energy equipment from VAT
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https://www.pv-magazine.com/2020/09/02/senegal-introduces-vat-exemption-for-off-grid-solar-products
https://www.pv-magazine.com/2020/09/02/senegal-introduces-vat-exemption-for-off-grid-solar-products
https://aawsat.com/english/home/article/2078831/plan-unveiled-increase-local-content-saudi-renewable-energy-industry-chains
https://aawsat.com/english/home/article/2078831/plan-unveiled-increase-local-content-saudi-renewable-energy-industry-chains
https://aawsat.com/english/home/article/2078831/plan-unveiled-increase-local-content-saudi-renewable-energy-industry-chains
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https://energy.economictimes.indiatimes.com/news/renewable/govt-working-on-mega-plan-to-triple-solar-manufacturing-capacity/76786536
https://energy.economictimes.indiatimes.com/news/renewable/govt-working-on-mega-plan-to-triple-solar-manufacturing-capacity/76786536
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https://www.powermag.com/trump-ban-on-foreign-bulk-power-equipment-triggers-new-uncertainty
https://www.powermag.com/trump-ban-on-foreign-bulk-power-equipment-triggers-new-uncertainty
Brazil eliminates import duties for cells, modules, inverters and trackers
Brazil eliminates import duties for cells, modules, inverters and trackers
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Analysis: Which countries met the UN’s 2020 deadline to raise ‘climate ambition’?
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https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs
https://unfccc.int/process-and-meetings/the-paris-agreement/nationally-determined-contributions-ndcs/nationally-determined-contributions-ndcs
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https://www.reuters.com/article/us-montenegro-climate/montenegro-introduces-cap-and-trade-scheme-for-major-co2-emitters-idUSKCN20I18O
https://www.gob.mx/semarnat/acciones-y-programas/programa-de-prueba-del-sistema-de-comercio-de-emisiones-179414
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https://www.gob.mx/semarnat/acciones-y-programas/programa-de-prueba-del-sistema-de-comercio-de-emisiones-179414
NZ puts hard cap on emissions for first time to strengthen its trading scheme
NZ puts hard cap on emissions for first time to strengthen its trading scheme
https://business.financialpost.com/pmn/business-pmn/austria-ends-coal-era-and-commits-to-more-renewable-energy
https://business.financialpost.com/pmn/business-pmn/austria-ends-coal-era-and-commits-to-more-renewable-energy
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https://www.reuters.com/article/us-japan-powerstation-coal/japan-to-accelerate-closure-of-old-coal-power-plants-idUSKBN2440AA
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https://www.eco-business.com/news/philippines-announces-moratorium-on-new-coal-power
ENDNOTES · POLICY L ANDSCAPE 02
PO
LI
CY
L
AN
DS
CA
PEeco-business.com/news/philippines-announces-moratorium-
on-new-coal-power; J. Lo, “Pakistan signals coal power exit,
in potential model for China’s belt and road”, Climate Home
News, 16 December 2020, https://www.climatechangenews.
com/2020/12/16/pakistan-signals-coal-power-exit-potential-
model-chinas-belt-road; T. Fransen et al., “Outcomes and
next steps from the Climate Ambition Summit”, WRI Blog, 17
December 2020, https://www.wri.org/blog/2020/12/outcomes-
and-next-steps-climate-ambition-summit; “75 leaders announce
new commitments during Climate Ambition Summit”, IISD, 17
December 2020, https://sdg.iisd.org/news/75-leaders-announce-
new-commitments-during-climate-ambition-summit.
18 German Federal Ministry of the Interior, Building and
Community, The New Buildings Energy Act, https://www.
bmi.bund.de/EN/topics/building-housing/building/energy-
efficient-construction-renovation/buildings-energy-act/
buildings-energy-act-node.html, viewed 14 November 2020;
L. Frank, “Germany’s new Building Energy Act is a missed
opportunity”, Institute for Advanced Sustainability Studies, 15
July 2020, https://www.iass-potsdam.de/en/blog/2020/07/
germanys-new-building-energy-act-missed-opportunity.
19 Government of Finland, “Government reaches agreement on
fourth supplementary budget proposal for 2020”, 2 June 2020,
https://valtioneuvosto.fi/en/-/10616/hallitus-paatti-vuoden-2020-
neljannesta-lisatalousarvioesityksesta.
20 R. Harrabin, “Climate pledge on gas boilers for 2023 ‘vanishes’”,
BBC, 20 November 2020, https://www.bbc.com/news/
science-environment-55020558.
21 V. Spasić, “Slovenia’s NECP: Local communities, protected areas
limit renewables growth”, Balkan Green Energy News, 22 October
2020, https://balkangreenenergynews.com/slovenias-necp-
local-communities-protected-areas-limit-renewables-growth;
Republic of Slovenia, Integrated National Energy and Climate
Plan of the Republic of Slovenia (Ljubljana: 27 February 2020),
https://ec.europa.eu/energy/sites/ener/files/documents/
si_final_necp_main_en .
22 “Japan aims to eliminate gasoline vehicles by mid-2030s, boost
green growth”, Reuters, 25 December 2020, https://uk.reuters.
com/article/us-japan-economy-green-idUKKBN28Z09P.
23 Scottish Construction Now, “Plan for one million zero emission
homes by 2030 is ‘ambitious’ but detail needed on delivery”, 17
December 2020, https://www.scottishconstructionnow.com/
article/plan-for-one-million-zero-emission-homes-by-2030-is-
ambitious-but-detail-needed-on-delivery; Scotland’s Cabinet
Secretary for Environment, Climate Change and Land Reform,
Securing a Green Recovery on a Path to Net Zero: Climate Change
Plan 2018–2032 – Update, Section 3.3.16 (Edinburgh: 16 December
2020), https://www.gov.scot/publications/securing-green-
recovery-path-net-zero-update-climate-change-plan-20182032/
pages/9.
24 D. Shepardson and N. Groom, “California passes landmark
mandate for zero emission trucks”, Reuters, 25 June 2020, https://
news.trust.org/item/20200625230325-cvhq2; R. Mitchell,
“California mandates big increase in zero-emission trucks”,
Los Angeles Times, 25 June 2020, https://www.latimes.com/
business/story/2020-06-25/new-california-truck-mandate-100-
000-zero-emission-commercial-haulers-sold-annually-by-2030.
25 R. Baldwin, “Massachusetts to ban sale of new gas-powered
cars by 2035”, Car and Driver, 31 December 2020, https://www.
caranddriver.com/news/a35104768/massachusetts-ban-new-gas-
cars-2035; Government of Massachusetts, Massachusetts 2050
Decarbonization Roadmap (Boston: December 2020), https://www.
mass.gov/doc/ma-2050-decarbonization-roadmap/download.
26 By 2019, there were nearly 300 LEZs in Europe alone, spread
across a dozen countries, from Groupe Renault, “Low emission
zones (LEZs) in Europe”, 25 March 2020, https://easyelectriclife.
groupe.renault.com/en/outlook/cities-planning/low-emission-
zones-lezs-in-europe. Others were implemented in 2020, for
example in the UK: A. Campion, “New low emission zones
to charge polluting cars”, Confused.com, 6 January 2021,
https://www.confused.com/on-the-road/cost-of-motoring/
low-emission-zones.
27 K. Vandy, “Coronavirus: How pandemic sparked European cycling
revolution”, BBC News, 2 October 2020, https://www.bbc.com/
news/world-europe-54353914.
28 “Denmark set to end all new oil and gas exploration”, BBC
News, 4 December 2020,https://www.bbc.com/news/
business-55184580; I. Slav, “Denmark to end oil production in
2050”, OilPrice.com, 4 December 2020, https://oilprice.com/
Latest-Energy-News/World-News/Denmark-To-End-Oil-
Production-In-2050.html.
29 C. Nugent, “U.K. says it will end support for overseas oil, gas and
coal projects with ‘very limited exceptions’”, TIME, 11 December
2020, https://time.com/5920475/u-k-fossil-fuels-overseas;
Government of the United Kingdom, “PM announces the UK
will end support for fossil fuel sector overseas”, press release
(London: 12 December 2020), https://www.gov.uk/government/
news/pm-announces-the-uk-will-end-support-for-fossil-fuel-
sector-overseas.
30 T. Helm and R. McKie, “UK urged to follow Denmark in ending
North Sea oil and gas exploration”, The Guardian (UK), 6 December
2020, https://www.theguardian.com/environment/2020/dec/06/
uk-urged-to-follow-denmark-in-ending-north-sea-oil-and-gas-
exploration; World Oil, “UK projects up to 20 billion barrels of oil
remain to be found offshore”, 14 September 2020, https://www.
worldoil.com/news/2020/9/14/uk-projects-up-to-20-billion-
barrels-of-oil-remain-to-be-found-offshore.
31 Sidebar 4 contributed by IISD and based on the following
sources: subsidies in 2019 from Organisation for Economic
Co-operation and Development (OECD), “Governments should
use Covid-19 recovery efforts as an opportunity to phase out
support for fossil fuels, say OECD and IEA”, 5 June 2020, https://
www.oecd.org/environment/governments-should-use-covid-19-
recovery-efforts-as-an-opportunity-to-phase-out-support-for-
fossil-fuels-say-oecd-and-iea.htm; Friends of Fossil Fuel Subsidy
Reform, “’We must act now’: Ten governments call on world
leaders to phase out fossil fuel subsidies”, 10 December 2020,
http://fffsr.org/2020/12/we-must-act-now-ten-governments-call-
on-world-leaders-to-phase-out-fossil-fuel-subsidies; R. Bridle
et al.,Fossil Fuel to Clean Energy Subsidy Swaps: How to Pay for
an Energy Revolution (Winnipeg: IISD, June 2019), p. 10, https://
www.iisd.org/system/files/publications/fossil-fuel-clean-energy-
subsidy-swap ; renewables capacity from REN21, Renewables
2020 Global Status Report (Paris: 2020), p. 47, https://www.ren21.
net/wp-content/uploads/2019/05/gsr_2020_full_report_en ;
captured by rich from P. Gass et al., Raising Ambition Through
Fossil Fuel Subsidy Reform: Greenhouse Gas Emissions Modelling
Results from 26 Countries (Winnipeg: IISD, June 2019), https://
www.iisd.org/publications/raising-ambition-through-fossil-fuel-
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ENDNOTES · POLICY L ANDSCAPE 02
PO
LI
CY
L
AN
DS
CA
PEgreentechmedia.com/articles/read/uk-unveils-ten-point-
plan-to-be-net-zero-by-2050; Covington & Burling LLP, “The
UK’s 10-point Green Industrial Revolution Plan”, Lexology, 19
November 2020, https://www.lexology.com/library/detail.
aspx?g=5a3688a4-a6d0-492b-8404-be67c4c36a46.
36 Ibid., all references.
37 R. Harrabin, “Ban on new petrol and diesel cars in UK from 2030
under PM’s green plan”, BBC, 18 November 2020, https://www.
bbc.com/news/science-environment-54981425.
38 H. Shin and S. Cha, “S. Korea to spend $95 bln on green projects
to boost economy”, Reuters, 14 July 2020, https://news.trust.org/
item/20200714053209-5b4wg; S-Y. Kim et al., “The Republic
of Korea’s Green New Deal shows the world what a smart
economic recovery looks like”, The Conversation, 9 September
2020, https://theconversation.com/south-koreas-green-new-
deal-shows-the-world-what-a-smart-economic-recovery-
looks-like-145032; C. Huang, “The Republic of Korea is using
coronavirus stimulus to green the economy”, Nikkei Asia, 15 May
2020, https://asia.nikkei.com/Opinion/South-Korea-is-using-
coronavirus-stimulus-to-green-the-economy.
39 Ibid., all references.
40 Africa Energy Portal, “Zimbabwe launches renewable energy,
biofuels policies”, 23 March 2020, https://africa-energy-portal.
org/news/zimbabwe-launches-renewable-energy-biofuels-
policies; “Zimbabwe government launches renewable energy
policy”, Xinhua, 19 March 2020, http://www.china.org.cn/world/
Off_the_Wire/2020-03/19/content_75836009.htm.
41 “Zimbabwe government launches renewable energy policy”, op.
cit. note 40.
42 Ibid.
43 For buildings, the plan includes CAD 2.6 billion (USD 2.03 billion)
for residential energy efficiency retrofit grants, CAD 2 billion
(USD 1.6 billion) in financing for commercial and large-scale
building retrofits. For transport, the plan includes CAD 287 million
(USD 225 million) in funding to continue Canada’s zero-emission
vehicle programme until March 2022 (which provides rebates
of up to CAD 5,000 (USD 3,911) for zero-emission passenger
vehicles) as well as CAD 150 million (USD 117 million)to fund EV
charging and hydrogen refuelling stations across Canada and a
100% tax write off for commercial light-duty, medium- and heavy-
duty zero-emission vehicles. For industry, Canada’s climate plan
includes CAD 1.5 billion (USD 1.2 billion) in a Low-carbon and
Zero-emissions Fuels Fund to increase the production and use of
low-carbon fuels such as hydrogen (as well as renewable natural
gas, renewable diesel and ethanol) and support for agriculture.
D. Baic, “From building retrofits and a national hydrogen strategy
to higher carbon taxes and planting trees: A primer on Canada’s
climate plan”, Globe and Mail, 11 December 2020, https://www.
theglobeandmail.com/canada/article-from-building-retrofits-
and-a-national-hydrogen-strategy-to-higher; Environment
and Climate Change Canada, “A healthy environment and a
healthy economy”, 11 December 2020, https://www.canada.
ca/en/environment-climate-change/news/2020/12/a-healthy-
environment-and-a-healthy-economy.html; M. Walsh, “Liberals
pitch $15-billion in new spending, hike carbon tax to pass 2030
emissions goals”, Globe and Mail, 11 December 2020, https://
www.theglobeandmail.com/politics/article-liberals-pitch-15-
billion-in-new-spending-170-carbon-tax-by-2030-to.
44 Transport commitments include a target of 1.5 million EVs by
2030, a target of 55% of city buses and 65% of school buses
to be electrified by 2030, a mandate of 15% ethanol in gasoline
by 2025 and 10% in biodiesel by 2030, a commitment to 50%
reduction of emissions related to heating for buildings by 2030 by
way of funding for electrification of building heating and cooling
and a requirement for 10% renewable natural gas to be added
to the natural gas network by 2030. Government of Quebec,
“2030 Plan for a Green Economy”, https://www.quebec.ca/en/
government/policies-orientations/plan-green-economy, updated
16 November 2020; Government of Quebec, “The Implementation
Plan: Unparalleled resources”, https://cdn-contenu.quebec.
ca/cdn-contenu/adm/min/environnement/publications-adm/
plan-economie-verte/fiche-synthese-pev2030-en , viewed
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le Quebec. Gagnant pour la planete (Montreal : 2020), p. 30,
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/
environnement/publications-adm/plan-economie-verte/
plan-economie-verte-2030 ; CBC, “Quebec to ban sale of
new gas-powered vehicles as of 2035”, 14 November 2020,
https://www.cbc.ca/news/canada/montreal/gas-vehicles-ban-
electric-quebec-1.5802374; M. Lowrie, “Quebec to ban sale of
gas-powered cars by 2035 as part of climate plan”, The Canadian
Press, 16 November 2020, https://globalnews.ca/news/7465476/
quebec-climate-plan-unveiled-2020.
45 In 2019, CO2 emissions from the operation of buildings increased
to their highest level yet at around 10 gigatonnes, or 28% of total
global energy-related CO2 emissions. IEA, World Energy Balances
(Paris: July 2020), https://www.iea.org/reports/world-energy-
balances-overview; Global Alliance for Buildings and Construction,
2020 Global Status Report for Buildings and Construction (Nairobi:
2020), http://globalabc.org/sites/default/files/inline-files/2020%20
Buildings%20GSR_FULL%20REPORT .
46 IRENA, IEA and REN21, Renewable Energy Policies in a Time of
Transition: Heating and Cooling (Paris and Abu Dhabi: 2020),
p. 11, https://www.irena.org/publications/2020/Nov/Renewable-
Energy-Policies-in-a-Time-of-Transition-Heating-and-Cooling.
47 IEA, Renewables 2020 (Paris: 2020), https://www.iea.org/reports/
renewables-2020/renewable-heat; IRENA, IEA and REN21, op. cit.
note 46, p. 31.
48 Figure 13 from REN21 Policy Database. See GSR 2021 Data Pack
at www.ren21.net/gsr.
49 IRENA, IEA and REN21, op. cit. note 46.
50 M. Hall, “Covid-19 weekly round-up: Residential systems in Italy
will get a 110% tax rebate and UK consumers are being paid to
turn appliances on as coronavirus turns the energy world upside
down”, pv magazine, 27 May 2020, https://www.pv-magazine.
com/2020/05/27/covid-19-weekly-round-up-residential-systems-
in-italy-will-get-a-110-tax-rebate-and-uk-consumers-are-being-
paid-to-turn-appliances-on-as-coronavirus-turns-the-energy-
world-upside-down; “Italy enables homeowners to install PV
systems for free”, Balkan Green Energy News, 2 June 2020,
https://balkangreenenergynews.com/italy-enables-homeowners-
to-install-pv-systems-for-free; E. Bellini, “Italy extends 110% fiscal
break for rooftop PV linked to building renovations to 2022”,
pv magazine, 21 December 2020, https://www.pv-magazine.
com/2020/12/21/italy-extends-110-fiscal-break-for-rooftop-pv-
linked-to-building-renovations-to-2022.
51 Agency of the Ministry of Environment of the Republic of
Lithuania, “An invitation to replace old and inefficient heating
boilers has been published”, 2 January 2020, https://www.apva.lt/
paskelbtas-kvietimas-senu-ir-neefektyviu-sildymo-katilu-keitimui-2.
52 Dentons, “Dutch subsidies for renewable energy: The end of
the SDE+ scheme and the launch of the broadened SDE++”,
16 April 2020, https://www.dentons.com/en/insights/alerts/2020/
april/16/ams-dutch-subsidies-for-renewable-energy-the-end-of-
the-sde-scheme.
53 Government of Scotland, “Green Recovery: Low Carbon Energy
Project Development Funding (closed)”,https://www.gov.scot/
policies/renewable-and-low-carbon-energy/low-carbon-
infrastructure-transition-programme, viewed 10 March 2021;
Government of the United Kingdom, “Changes to RHI support
and COVID-19 response: Notice of proposals: Extension of
the Domestic Renewable Heat Incentive Scheme (DRHI) for
an additional year until 31 March 2022”, https://www.gov.uk/
government/publications/changes-to-the-renewable-heat-
incentive-rhi-schemes/changes-to-rhi-support-and-covid-19-
response, updated 30 June 2020.
54 The programme includes support for the installation of thermal
insulation, efficient air conditioning and heating systems including
heat pumps, and for the installation of solar thermal or solar
PV. IISD, “Eur4.5 million for energy efficiency in Portugal”, 11
September 2020, https://www.iisd.org/sustainable-recovery/
news/eur4-5-milllion-for-energy-efficiency-in-portugal; P. Dias,
Solar Heat Europe, personal communication with REN21, 19
January 2021.
55 IEA, 2019 Global Status Report for Buildings and Construction
(Paris: 2019), p. 20, https://webstore.iea.org/download/
direct/2930?fileName=2019_Global_Status_Report_for_
Buildings_and_Construction .
56 IRENA, IEA, REN21, op. cit. note 46.
57 M. Jordan, IEA, personal communication with REN21, 7 May 2021.
58 Ibid.
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https://www.theglobeandmail.com/politics/article-liberals-pitch-15-billion-in-new-spending-170-carbon-tax-by-2030-to
https://www.theglobeandmail.com/politics/article-liberals-pitch-15-billion-in-new-spending-170-carbon-tax-by-2030-to
https://www.theglobeandmail.com/politics/article-liberals-pitch-15-billion-in-new-spending-170-carbon-tax-by-2030-to
https://www.quebec.ca/en/government/policies-orientations/plan-green-economy
https://www.quebec.ca/en/government/policies-orientations/plan-green-economy
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/fiche-synthese-pev2030-en
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/fiche-synthese-pev2030-en
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/fiche-synthese-pev2030-en
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/plan-economie-verte-2030
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/plan-economie-verte-2030
https://cdn-contenu.quebec.ca/cdn-contenu/adm/min/environnement/publications-adm/plan-economie-verte/plan-economie-verte-2030
https://www.cbc.ca/news/canada/montreal/gas-vehicles-ban-electric-quebec-1.5802374
https://www.cbc.ca/news/canada/montreal/gas-vehicles-ban-electric-quebec-1.5802374
Quebec to ban sale of gas-powered cars by 2035 as part of climate plan
Quebec to ban sale of gas-powered cars by 2035 as part of climate plan
https://www.iea.org/reports/world-energy-balances-overview
https://www.iea.org/reports/world-energy-balances-overview
http://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT
http://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT
https://www.irena.org/publications/2020/Nov/Renewable-Energy-Policies-in-a-Time-of-Transition-Heating-and-Cooling
https://www.irena.org/publications/2020/Nov/Renewable-Energy-Policies-in-a-Time-of-Transition-Heating-and-Cooling
https://www.iea.org/reports/renewables-2020/renewable-heat
https://www.iea.org/reports/renewables-2020/renewable-heat
Italy extends 110% fiscal break for rooftop PV linked to building renovations to 2022
Italy extends 110% fiscal break for rooftop PV linked to building renovations to 2022
Italy extends 110% fiscal break for rooftop PV linked to building renovations to 2022
https://www.apva.lt/paskelbtas-kvietimas-senu-ir-neefektyviu-sildymo-katilu-keitimui-2
https://www.apva.lt/paskelbtas-kvietimas-senu-ir-neefektyviu-sildymo-katilu-keitimui-2
https://www.dentons.com/en/insights/alerts/2020/april/16/ams-dutch-subsidies-for-renewable-energy-the-end-of-the-sde-scheme
https://www.dentons.com/en/insights/alerts/2020/april/16/ams-dutch-subsidies-for-renewable-energy-the-end-of-the-sde-scheme
https://www.dentons.com/en/insights/alerts/2020/april/16/ams-dutch-subsidies-for-renewable-energy-the-end-of-the-sde-scheme
https://www.gov.scot/policies/renewable-and-low-carbon-energy/low-carbon-infrastructure-transition-programme
https://www.gov.scot/policies/renewable-and-low-carbon-energy/low-carbon-infrastructure-transition-programme
https://www.gov.scot/policies/renewable-and-low-carbon-energy/low-carbon-infrastructure-transition-programme
https://www.gov.uk/government/publications/changes-to-the-renewable-heat-incentive-rhi-schemes/changes-to-rhi-support-and-covid-19-response
https://www.gov.uk/government/publications/changes-to-the-renewable-heat-incentive-rhi-schemes/changes-to-rhi-support-and-covid-19-response
https://www.gov.uk/government/publications/changes-to-the-renewable-heat-incentive-rhi-schemes/changes-to-rhi-support-and-covid-19-response
https://www.gov.uk/government/publications/changes-to-the-renewable-heat-incentive-rhi-schemes/changes-to-rhi-support-and-covid-19-response
https://www.iisd.org/sustainable-recovery/news/eur4-5-milllion-for-energy-efficiency-in-portugal
https://www.iisd.org/sustainable-recovery/news/eur4-5-milllion-for-energy-efficiency-in-portugal
https://webstore.iea.org/download/direct/2930?fileName=2019_Global_Status_Report_for_Buildings_and_Construction
https://webstore.iea.org/download/direct/2930?fileName=2019_Global_Status_Report_for_Buildings_and_Construction
https://webstore.iea.org/download/direct/2930?fileName=2019_Global_Status_Report_for_Buildings_and_Construction
ENDNOTES · POLICY L ANDSCAPE 02
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PE59 A. Moore, “California home solar panels to become a necessary
part of new building codes”, Hydrogen Fuel News, 2 January
2020, https://www.hydrogenfuelnews.com/california-home-
solar-panels-to-become-a-necessary-part-of-new-building-
codes/8539135; N. Nellis, “Building code updates to encourage
solar power”, Journal of Business, 18 June 2020, https://www.
spokanejournal.com/up-close/building-code-updates-to-
encourage-solar-power. At the local level, Honolulu (Hawaii),
included “solar-ready” roofs and solar water heating requirements
in its building code, from E. Stampe and M. Stamas, “Honolulu
votes to build back better for climate”, Natural Resources
Defense Council, 20 May 2020, https://www.nrdc.org/experts/
elizabeth-stampe/honolulu-votes-build-back-better-climate.
60 F. Jossi, “This new building code in Minnesota is going to hurt
its residential solar market”, Solar Builder, 2 April 2020, https://
solarbuildermag.com/news/this-new-building-code-in-
minnesota-is-going-to-hurt-its-residential-solar-market.
61 IEA, op. cit. note 47.
62 “Danish Climate Agreement for Energy and Industry 2020
– Overview”, 22 June 2020,https://kefm.dk/Media/C/B/faktaark-
klimaaftale%20(English%20august%2014) .
63 Provincial Government of British Columbia, “CleanBC Better
Homes Low-Interest Financing Program”, https://betterhomesbc.
ca/rebates/financing, viewed 27 November 2020; Canada Energy
Regulator, Canada’s Renewable Power Landscape 2016: Energy
Market Analysis (Calgary: 2016), https://www.cer-rec.gc.ca/
en/data-analysis/energy-commodities/electricity/report/2016-
canadian-renewable-power/2016cndrnwblpwr-eng .
64 J. Gerdes, “California moves to tackle another big emissions
source: Fossil fuel use in buildings”, Greentech Media, 4
February 2020, https://www.greentechmedia.com/articles/read/
california-moves-to-tackle-another-big-emissions-source-fossil-
fuel-use-in-buildings; “New Mexico governor signs solar energy,
grid update bills”, US News, 3 March 2020, https://www.usnews.
com/news/best-states/new-mexico/articles/2020-03-03/
new-mexico-governor-signs-solar-energy-grid-update-bills.
65 M. Mazengarb, “ACT government to build first all-electric hospital,
powered by renewables”, RenewEconomy, 2 September 2020,
https://reneweconomy.com.au/act-government-to-build-first-all-
electric-hospital-powered-by-renewables-76968.
66 A. Richter, “EUR 150m scheme to support renewable energy
district heating systems in Romania”, Think GeoEnergy, 7
November 2020, https://www.thinkgeoenergy.com/eur-150m-
scheme-to-support-renewable-energy-district-heating-systems-
in-romania.
67 B. Epp, “Poland shifts away from coal-fired district
heating”, Solarthermalworld.org, 6 December
2020, https://www.solarthermalworld.org/news/
poland-shifts-away-coal-fired-district-heating.
68 IRENA, IEA and REN21, op. cit. note 46, p. 33.
69 European Commission, “Renovation Wave: Doubling the
renovation rate to cut emissions, boost recovery and reduce
energy poverty”, https://ec.europa.eu/commission/presscorner/
detail/en/IP_20_1835, updated 16 October 2020; F. Simon, “EU
launches ‘renovation wave’ for greener, more stylish buildings”,
EURACTIV, 15 October 2020, https://www.euractiv.com/section/
energy/news/eu-launches-renovation-wave-for-greener-more-
stylish-buildings; SolarPower Europe, EU Market Outlook for Solar
Power 2020-2024 (Brussels: December 2020), p. 25, https://www.
solarpowereurope.org/wp-content/uploads/2020/12/3520-SPE-
EMO-2020-report-11-mr .
70 Simon, op. cit. note 69.
71 Ibid.
72 M. Brignall, “Green Homes Grant: Homeowners can apply for up
to £5,000 in England”, The Guardian (UK), 30 September 2020,
https://www.theguardian.com/environment/2020/sep/30/green-
homes-grant-apply-egland-vouchers-insulation-double-glazing.
73 S. Surkes, “Ministry unveils program to make Israeli economy more
energy efficient”, Times of Israel, 17 November 2020, https://www.
timesofisrael.com/ministry-unveils-program-to-make-israeli-
economy-more-energy-efficient; “Israel launches 10-year national
energy efficiency plan”, Xinhua, 16 November 2020, http://www.
xinhuanet.com/english/2020-11/16/c_139520363.htm.
74 Beveridge & Diamond PC, “Washington adopts ‘PACER’
legislation that will create a proven source of financing for energy
and resiliency retrofits in commercial buildings”, Lexology,
25 March 2020, https://www.lexology.com/library/detail.
aspx?g=df6a1e2d-b68f-4cda-8aeb-f0e34292ece.
75 IRENA, IEA and REN21, op. cit. note 46, p. 11.
76 Sidebar 5 based on the following sources: IRENA, “Hydrogen from
renewable power”, https://www.irena.org/energytransition/Power-
Sector-Transformation/Hydrogen-from-Renewable-Power, viewed
10 March 2021; K. Appunn, “EU aims for 40 GW of green hydrogen
electrolysers, and one million jobs, by 2030”, RenewEconomy, 9
July 2020, https://reneweconomy.com.au/eu-aims-for-40gw-of-
green-hydrogen-electrolysers-and-one-million-jobs-by-2030;
J. Parnell, “European Union sets gigawatt-scale targets for
green hydrogen”, Greentech Media, 9 July 2020, https://www.
greentechmedia.com/articles/read/eu-sets-green-hydrogen-
targets-now-blue-hydrogen-has-to-keep-up; SolarPower Europe,
op. cit. note 69, p. 27; “German government to agree national
hydrogen strategy”, Economic Times, 10 June 2020, https://
energy.economictimes.indiatimes.com/news/renewable/german-
government-to-agree-national-hydrogen-strategy/76299802;
“Germany plans to promote ‘green’ hydrogen with €7 billion”,
EURACTIV, 11 June 2020, https://www.eceee.org/all-news/news/
news-2020/germany-plans-to-promote-green-hydrogen-with-7-
billion; CNBC, “UK government announces millions in funding for
‘low carbon’ hydrogen production”, 18 February 2020, https://www.
cnbc.com/2020/02/18/uk-government-announces-funding-for-
low-carbon-hydrogen-production.html; “Norway sees hydrogen
as a ‘story of hope’”, 8 June 2020, https://www.kallanishenergy.
com/2020/06/08/norway-sees-hydrogen-as-a-story-of-hope;
“Spain approves hydrogen strategy to spur low-carbon economy”,
EURACTIV, 7 October 2020, https://www.euractiv.com/section/
energy/news/spain-approves-hydrogen-strategy-to-spur-low-
carbon-economy; E. Bellini, “Scotland stimulates hydrogen
economy with £100m investment”, pv magazine, 22 December
2020, https://www.pv-magazine.com/2020/12/22/scotland-
stimulates-hydrogen-economy-with-100m-investment. The AUD
300 million (USD 230 million) fund will provide finance, through
direct investment and loans, to projects looking to grow Australia’s
renewable hydrogen sector, including the development of new
domestic supply chains, export infrastructure and investing in
projects that help grow local demand for hydrogen. M. Mazengarb,
“CEFC to kick-start Australia’s hydrogen industry with new
$300m investment fund”, RenewEconomy, 4 May 2020, https://
reneweconomy.com.au/cefc-to-kick-start-australias-hydrogen-
industry-with-new-300m-investment-fund-38339; V. Petrova,
“Australia opens USD-44m funding round for green hydrogen”,
Renewables Now, 15 April 2020, https://renewablesnow.com/
news/australia-opens-usd-44m-funding-round-for-green-
hydrogen-695144; HyResource, A Short Report on Hydrogen
Industry Policy Initiatives and the Status of Hydrogen Projects in
Australia (December 2020), https://research.csiro.au/hyresource/
wp-content/uploads/sites/378/2020/12/HyResource-Short-
Report ; S. Vorrath, “NT unveils strategy to lead global
renewable hydrogen market”, RenewEconomy, 10 July 2020,
https://reneweconomy.com.au/nt-unveils-strategy-to-lead-global-
renewable-hydrogen-market-75048; M. Mazengarb, “Tasmania
boosts renewable hydrogen aspirations with $50m ‘action plan’”,
RenewEconomy, 2 March 2020, https://reneweconomy.com.au/
tasmania-boosts-renewable-hydrogen-aspirations-with-50m-
action-plan-87011; BNAmericas, “Chile unveils green hydrogen
strategy to become world-class exporter”, 3 November 2020,
https://www.bnamericas.com/en/news/chile-unveils-sweeping-
green-hydrogen-strategy-to-become-world-class-exporter;
Acera, “Ministerio de Energía adelanta los cuatro ejes de la
estrategia nacional de hidrógeno verde a 2050”, 19 May 2020,
https://acera.cl/ministerio-de-energia-adelanta-los-cuatro-ejes-
de-la-estrategia-nacional-de-hidrogeno-verde-a-2050. Table 5
from IRENA (2020), Green Hydrogen: A guide to policy making,
International Renewable Energy Agency, Ab Dhabi, https://www.
irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/
IRENA_Green_hydrogen_policy_2020 ; E. Bianco and
S. Diab, IRENA, personal communication with REN21, 11 April
2021; R. Zeller, Vestas, personal communication with REN21,
12 April 2021; see GSR 2021 Data Pack for additional references
at www.ren21.net/gsr.
77 IEA, op. cit. note 47.
78 Government of the United Kingdom, “PM commits £350
million to fuel green recovery”, press release (London:
21 July 2020), https://www.gov.uk/government/news/
pm-commits-350-million-to-fuel-green-recovery.
277
California home solar panels to become a necessary part of new building codes
California home solar panels to become a necessary part of new building codes
California home solar panels to become a necessary part of new building codes
https://www.spokanejournal.com/up-close/building-code-updates-to-encourage-solar-power
https://www.spokanejournal.com/up-close/building-code-updates-to-encourage-solar-power
https://www.spokanejournal.com/up-close/building-code-updates-to-encourage-solar-power
https://www.nrdc.org/experts/elizabeth-stampe/honolulu-votes-build-back-better-climate
https://www.nrdc.org/experts/elizabeth-stampe/honolulu-votes-build-back-better-climate
This new building code in Minnesota is going to hurt its residential solar market
This new building code in Minnesota is going to hurt its residential solar market
This new building code in Minnesota is going to hurt its residential solar market
https://kefm.dk/Media/C/B/faktaark-klimaaftale%20(English%20august%2014)
https://kefm.dk/Media/C/B/faktaark-klimaaftale%20(English%20august%2014)
https://www.cer-rec.gc.ca/en/data-analysis/energy-commodities/electricity/report/2016-canadian-renewable-power/2016cndrnwblpwr-eng
https://www.cer-rec.gc.ca/en/data-analysis/energy-commodities/electricity/report/2016-canadian-renewable-power/2016cndrnwblpwr-eng
https://www.cer-rec.gc.ca/en/data-analysis/energy-commodities/electricity/report/2016-canadian-renewable-power/2016cndrnwblpwr-eng
https://www.greentechmedia.com/articles/read/california-moves-to-tackle-another-big-emissions-source-fossil-fuel-use-in-buildings
https://www.greentechmedia.com/articles/read/california-moves-to-tackle-another-big-emissions-source-fossil-fuel-use-in-buildings
https://www.greentechmedia.com/articles/read/california-moves-to-tackle-another-big-emissions-source-fossil-fuel-use-in-buildings
https://www.usnews.com/news/best-states/new-mexico/articles/2020-03-03/new-mexico-governor-signs-solar-energy-grid-update-bills
https://www.usnews.com/news/best-states/new-mexico/articles/2020-03-03/new-mexico-governor-signs-solar-energy-grid-update-bills
https://www.usnews.com/news/best-states/new-mexico/articles/2020-03-03/new-mexico-governor-signs-solar-energy-grid-update-bills
ACT government to build first all-electric hospital, powered by renewables
ACT government to build first all-electric hospital, powered by renewables
EUR 150m scheme to support renewable energy district heating systems in Romania
EUR 150m scheme to support renewable energy district heating systems in Romania
EUR 150m scheme to support renewable energy district heating systems in Romania
https://ec.europa.eu/commission/presscorner/detail/en/IP_20_1835
https://ec.europa.eu/commission/presscorner/detail/en/IP_20_1835
EU launches ‘renovation wave’ for greener, more stylish buildings
EU launches ‘renovation wave’ for greener, more stylish buildings
EU launches ‘renovation wave’ for greener, more stylish buildings
https://www.solarpowereurope.org/wp-content/uploads/2020/12/3520-SPE-EMO-2020-report-11-mr
https://www.solarpowereurope.org/wp-content/uploads/2020/12/3520-SPE-EMO-2020-report-11-mr
https://www.solarpowereurope.org/wp-content/uploads/2020/12/3520-SPE-EMO-2020-report-11-mr
https://www.theguardian.com/environment/2020/sep/30/green-homes-grant-apply-egland-vouchers-insulation-double-glazing
https://www.theguardian.com/environment/2020/sep/30/green-homes-grant-apply-egland-vouchers-insulation-double-glazing
https://www.timesofisrael.com/ministry-unveils-program-to-make-israeli-economy-more-energy-efficient
https://www.timesofisrael.com/ministry-unveils-program-to-make-israeli-economy-more-energy-efficient
https://www.timesofisrael.com/ministry-unveils-program-to-make-israeli-economy-more-energy-efficient
http://www.xinhuanet.com/english/2020-11/16/c_139520363.htm
http://www.xinhuanet.com/english/2020-11/16/c_139520363.htm
https://www.lexology.com/library/detail.aspx?g=df6a1e2d-b68f-4cda-8aeb-f0e34292ece
https://www.lexology.com/library/detail.aspx?g=df6a1e2d-b68f-4cda-8aeb-f0e34292ece
https://www.irena.org/energytransition/Power-Sector-Transformation/Hydrogen-from-Renewable-Power
https://www.irena.org/energytransition/Power-Sector-Transformation/Hydrogen-from-Renewable-Power
EU aims for 40GW of green hydrogen electrolysers, and one million jobs, by 2030
EU aims for 40GW of green hydrogen electrolysers, and one million jobs, by 2030
https://www.greentechmedia.com/articles/read/eu-sets-green-hydrogen-targets-now-blue-hydrogen-has-to-keep-up
https://www.greentechmedia.com/articles/read/eu-sets-green-hydrogen-targets-now-blue-hydrogen-has-to-keep-up
https://www.greentechmedia.com/articles/read/eu-sets-green-hydrogen-targets-now-blue-hydrogen-has-to-keep-up
https://energy.economictimes.indiatimes.com/news/renewable/german-government-to-agree-national-hydrogen-strategy/76299802
https://energy.economictimes.indiatimes.com/news/renewable/german-government-to-agree-national-hydrogen-strategy/76299802
https://energy.economictimes.indiatimes.com/news/renewable/german-government-to-agree-national-hydrogen-strategy/76299802
https://www.eceee.org/all-news/news/news-2020/germany-plans-to-promote-green-hydrogen-with-7-billion
https://www.eceee.org/all-news/news/news-2020/germany-plans-to-promote-green-hydrogen-with-7-billion
https://www.eceee.org/all-news/news/news-2020/germany-plans-to-promote-green-hydrogen-with-7-billion
https://www.cnbc.com/2020/02/18/uk-government-announces-funding-for-low-carbon-hydrogen-production.html
https://www.cnbc.com/2020/02/18/uk-government-announces-funding-for-low-carbon-hydrogen-production.html
https://www.cnbc.com/2020/02/18/uk-government-announces-funding-for-low-carbon-hydrogen-production.html
CEFC to kick-start Australia’s hydrogen industry with new $300m investment fund
CEFC to kick-start Australia’s hydrogen industry with new $300m investment fund
CEFC to kick-start Australia’s hydrogen industry with new $300m investment fund
https://renewablesnow.com/news/australia-opens-usd-44m-funding-round-for-green-hydrogen-695144
https://renewablesnow.com/news/australia-opens-usd-44m-funding-round-for-green-hydrogen-695144
https://renewablesnow.com/news/australia-opens-usd-44m-funding-round-for-green-hydrogen-695144
https://research.csiro.au/hyresource/wp-content/uploads/sites/378/2020/12/HyResource-Short-Report
https://research.csiro.au/hyresource/wp-content/uploads/sites/378/2020/12/HyResource-Short-Report
https://research.csiro.au/hyresource/wp-content/uploads/sites/378/2020/12/HyResource-Short-Report
NT unveils strategy to lead global renewable hydrogen market
NT unveils strategy to lead global renewable hydrogen market
Tasmania boosts renewable hydrogen aspirations with $50m “action plan”
Tasmania boosts renewable hydrogen aspirations with $50m “action plan”
Tasmania boosts renewable hydrogen aspirations with $50m “action plan”
https://www.bnamericas.com/en/news/chile-unveils-sweeping-green-hydrogen-strategy-to-become-world-class-exporter
https://www.bnamericas.com/en/news/chile-unveils-sweeping-green-hydrogen-strategy-to-become-world-class-exporter
https://acera.cl/ministerio-de-energia-adelanta-los-cuatro-ejes-de-la-estrategia-nacional-de-hidrogeno-verde-a-2050
https://acera.cl/ministerio-de-energia-adelanta-los-cuatro-ejes-de-la-estrategia-nacional-de-hidrogeno-verde-a-2050
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_Green_hydrogen_policy_20
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_Green_hydrogen_policy_20
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_Green_hydrogen_policy_20
https://www.gov.uk/government/news/pm-commits-350-million-to-fuel-green-recovery
https://www.gov.uk/government/news/pm-commits-350-million-to-fuel-green-recovery
ENDNOTES · POLICY L ANDSCAPE 02
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PE79 Netherlands Enterprise Agency, “Stimulation of sustainable
energy production and climate transition (SDE++)”, https://
english.rvo.nl/subsidies-programmes/sde, viewed 10 March 2021.
80 “Danish Climate Agreement for Energy and Industry 2020”, op. cit.
note 62.
81 Zero Waste Scotland, “SME Loan Fund”, https://energy.
zerowastescotland.org.uk/SMELoan, viewed 18 December 2020.
82 E. Bellini, “Jamaica turns to solar for irrigation,
water treatment”, pv magazine, 15 December
2020, https://www.pv-magazine.com/2020/12/15/
jamaica-turns-to-solar-for-irrigation-water-treatment.
83 J. M. Takouleu, “Egypt: $11.6 million to modernise several irrigation
systems in the north”, Afrik 21, 29 April 2020, https://www.afrik21.
africa/en/egypt-11-6-million-to-modernise-several-irrigation-
systems-in-the-north.
84 Baic, “From building retrofits and a national hydrogen strategy
to higher carbon taxes and planting trees”, op. cit. note 43;
Environment and Climate Change Canada, op. cit. note 43; Walsh,
op. cit. note 43.
85 IEA, Energy Efficiency Indicators (Paris: 2020), https://www.iea.
org/reports/energy-efficiency-indicators-2020.
86 “Trump’s agriculture department announces 30% biofuel goal
for 2050”, Reuters, 20 February 2020, https://www.reuters.
com/article/us-usa-ethanol/trumps-agriculture-department-
announces-30-biofuel-goal-for-2050-idUSKBN20E1F3.
87 Africa Energy Portal, op. cit. note 40; “Zimbabwe government
launches renewable energy policy”, op. cit. note 40.
88 Presidencia de la República del Paraguay, Ministerio de Industria
Y Comercio, “Por el cual se reglamenta la Ley N° 6389/2019, que
establece el régimen de promoción para la elaboración sostenible
y utilización obligatoria del biocombustible apto para la utilización
en motores diésel”, 30 March 2020, https://www.presidencia.gov.
py/archivos/documentos/DECRETO3500_0m7n1d1y.PDF.
89 Biofuels International, “Brazil increases volume of biodiesel in
fuel to 12%”, 3 March 2020, https://biofuels-news.com/news/
brazil-increases-volume-of-biodiesel-in-fuel-to-12; Biofuels
International, “Brazil’s ANP temporarily reduces biodiesel blend
to 10%”, 17 August 2020, https://biofuels-news.com/news/
brazils-anp-temporarily-reduces-biodiesel-blend-to-10.
90 Biofuels Digest, “Cyprus government getting flack for higher
fuel prices after boosting biofuel blend”, 21 January 2020,
https://www.biofuelsdigest.com/bdigest/2020/01/21/cyprus-
government-getting-flack-for-higher-fuel-prices-after-boosting-
biofuel-blend.
91 Standard & Poors Global, “Analysis: Indonesia’s diesel, gasoline
imports under pressure as biofuel targets increase”, 20 February
2020, https://www.spglobal.com/platts/en/market-insights/
latest-news/oil/022020-analysis-indonesias-diesel-gasoline-
imports-under-pressure-as-biofuel-targets-increase.
92 Government of Ontario, “Greener gasoline”, https://www.ontario.
ca/page/greener-gasoline, viewed 19 October 2020; Government
of Ontario, “Ontario to be national leader and require cleaner and
greener gasoline”, 26 November 2020, https://news.ontario.ca/
en/release/59352/ontario-to-be-national-leader-and-require-
cleaner-and-greener-gasoline-1.
93 Republic of Latvia, Latvia’s National Energy and Climate Plan
2021-2030 (Riga: 2020), p. 13, https://ec.europa.eu/energy/sites/
ener/files/documents/lv_final_necp_main_en .
94 “European Commission approves extension of Swedish tax
exemption regime for liquid biofuels”, Bloomberg, 13 October
2020, https://news.bloombergtax.com/daily-tax-report-
international/european-commission-approves-extension-of-
swedish-tax-exemption-regime-for-liquid-biofuels; The Iowa
Biodiesel Board and Biodiesel Magazine, “Iowa legislature
extends fuel tax incentive for biodiesel blends”, 4 June 2020,
http://www.biodieselmagazine.com/articles/2517034/
iowa-legislature-extends-fuel-tax-incentive-for-biodiesel-blends.
95 Y. Praiwan, “Energy Ministry keen to maintain
subsidies for biofuels”, Bangkok Post, 30 January 2020,
https://www.bangkokpost.com/business/1846739/
energy-ministry-keen-to-maintain-subsidies-for-biofuels.
96 Biofuels International, “Finnish postal fleet to use renewable
diesel to drive down emissions”, 15 June 2020, https://biofuels-
news.com/news/finnish-postal-fleet-to-use-renewable-diesel-to-
drive-down-emissions.
97 Biofuels International, “Paraguayan Government grants ‘free zone
regime’ for Omega Green biofuel plant”, 27 January 2020, https://
biofuels-news.com/news/paraguayan-government-grants-free-
zone-regime-for-omega-green-biofuel-plant.
98 Biofuture Platform, “Brazil’s RenovaBio emissions reduction
credits start trading in the stock exchange”, 27 April 2020, http://
www.biofutureplatform.org/post/brazil-s-renovabio-emissions-
reduction-credits-start-trading-in-the-stock-change.
99 The funding was for four plants producing biofuels from household
waste, unused straw from farmland and old wood, and the
biofuel generated at these plants is expected to help the country
decarbonise road and air transport, from Biofuels International,
“UK’s Department for Transport announces funding for biofuel
projects”, 6 January 2020, https://biofuels-news.com/news/uks-
department-for-transport-announces-funding-for-biofuel-projects.
100 Biofuels International, “US Department of Energy to provide
$75 million for biofuel crop research”, 15 January 2020, https://
biofuels-news.com/news/us-department-of-energy-to-provide-
75-million-for-biofuel-crop-research; “USDA announces
$100 million in competitive grants for biofuels infrastructure”,
Successful Farming, 4 April 2020, https://www.agriculture.com/
news/business/usda-announces-100-million-in-competitive-
grants-for-biofuels-infrastructure.
101 Iowa Renewable Fuels Association, “Iowa legislature funds state’s
biofuel infrastructure program”, Biodiesel Magazine, 16 June 2020,
http://www.biodieselmagazine.com/articles/2517045/iowa-
legislature-funds-stateundefineds-biofuel-infrastructure-program.
102 “Japan to offer up to ¥800,000 in subsidies for electric vehicles”,
Japan Times, 25 November 2020, https://www.japantimes.co.jp/
news/2020/11/25/business/subsidies-electric-vehicles; Japan
Ministry of Economy, Trade and Industry, “’Clean energy vehicle
introduction project cost subsidy that can be used even in the
event of a disaster’ was included in the third supplementary
budget for the second year of Reiwa”, 22 December 2020, https://
www.meti.go.jp/press/2020/12/20201222006/20201222006.
html; Bundesministerium Klimaschutz, Umwelt, Energie, Mobilität,
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www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_
emob2021.html, viewed 10 March 2021. Policies linking renewables
and EVs previously were in place in Germany and Luxembourg but
were no longer in place as of 2018 and 2017, respectively.
103 “Kolkata: Solar panels on depot roofs to charge e-buses”,
Economic Times, 10 February 2020, https://energy.
economictimes.indiatimes.com/news/renewable/kolkata-solar-
panels-on-depot-roofs-to-charge-e-buses/74062260.
104 K. Pyzyk, “Delaware transit agency to power electric
buses with solar array”, Smart Cities Dive, 26 August
2020, https://www.smartcitiesdive.com/news/
delaware-transit-agency-electric-bus-solar-array/584048.
105 REN21 Policy Database. See GSR 2021 Data Pack for details:
www.ren21.net/gsr-2021.
106 R. Saeed Khan, “Pakistan launches electric vehicle plan with
cars in slow lane”, Reuters, 29 June 2020, https://news.trust.org/
item/20200629031504-axvnf.
107 “Denmark agrees deal to have 775,000 electric cars by
2030”, Reuters, 4 December 2020, https://news.trust.org/
item/20201204160932-5143z.
108 Notes from Poland, “Polish government’s electric vehicle
subsidies fail to attract applications”, 10 July 2020, https://
notesfrompoland.com/2020/07/10/polish-governments-electric-
vehicle-subsidies-fail-to-attract-applications.
109 M. Mazengarb, “NSW government triples EV fleet pledge, to ease
regulations for charging infrastructure”, The Driven, 2 June 2020,
https://thedriven.io/2020/06/02/nsw-government-triples-ev-
fleet-pledge-to-ease-regulations-for-charging-infrastructure.
110 D. Wagman, “Sunrise brief: New York offers funds for
electric bus transition”, pv magazine, 30 December
2020, https://pv-magazine-usa.com/2020/12/30/
sunrise-brief-new-york-offers-funds-for-electric-bus-transition.
111 Government Technology, “New Hawaii law could help boost EV
charging access”, 21 January 2020, https://www.govtech.com/fs/
infrastructure/New-Hawaii-Law-Could-Help-Boost-EV-Charging-
Access.html; J. St. John, “California targets nearly $400M to fill gaps
in EV charging infrastructure”, Greentech Media, 16 October 2020,
https://www.greentechmedia.com/articles/read/california-targets-
384m-to-fill-gaps-in-electric-vehicle-charging-infrastructure.
278
https://english.rvo.nl/subsidies-programmes/sde
https://english.rvo.nl/subsidies-programmes/sde
https://energy.zerowastescotland.org.uk/SMELoan
https://energy.zerowastescotland.org.uk/SMELoan
EGYPT: $11.6 million to modernise several irrigation systems in the north
EGYPT: $11.6 million to modernise several irrigation systems in the north
EGYPT: $11.6 million to modernise several irrigation systems in the north
https://www.iea.org/reports/energy-efficiency-indicators-2020
https://www.iea.org/reports/energy-efficiency-indicators-2020
https://www.reuters.com/article/us-usa-ethanol/trumps-agriculture-department-announces-30-biofuel-goal-for-2050-idUSKBN20E1F3
https://www.reuters.com/article/us-usa-ethanol/trumps-agriculture-department-announces-30-biofuel-goal-for-2050-idUSKBN20E1F3
https://www.reuters.com/article/us-usa-ethanol/trumps-agriculture-department-announces-30-biofuel-goal-for-2050-idUSKBN20E1F3
https://www.presidencia.gov.py/archivos/documentos/DECRETO3500_0m7n1d1y.PDF
https://www.presidencia.gov.py/archivos/documentos/DECRETO3500_0m7n1d1y.PDF
https://www.biofuelsdigest.com/bdigest/2020/01/21/cyprus-government-getting-flack-for-higher-fuel-prices-after-boosting-biofuel-blend
https://www.biofuelsdigest.com/bdigest/2020/01/21/cyprus-government-getting-flack-for-higher-fuel-prices-after-boosting-biofuel-blend
https://www.biofuelsdigest.com/bdigest/2020/01/21/cyprus-government-getting-flack-for-higher-fuel-prices-after-boosting-biofuel-blend
https://www.spglobal.com/platts/en/market-insights/latest-news/oil/022020-analysis-indonesias-diesel-gasoline-imports-under-pressure-as-biofuel-targets-increase
https://www.spglobal.com/platts/en/market-insights/latest-news/oil/022020-analysis-indonesias-diesel-gasoline-imports-under-pressure-as-biofuel-targets-increase
https://www.spglobal.com/platts/en/market-insights/latest-news/oil/022020-analysis-indonesias-diesel-gasoline-imports-under-pressure-as-biofuel-targets-increase
https://www.ontario.ca/page/greener-gasoline
https://www.ontario.ca/page/greener-gasoline
https://news.ontario.ca/en/release/59352/ontario-to-be-national-leader-and-require-cleaner-and-greener-gasoline-1
https://news.ontario.ca/en/release/59352/ontario-to-be-national-leader-and-require-cleaner-and-greener-gasoline-1
https://news.ontario.ca/en/release/59352/ontario-to-be-national-leader-and-require-cleaner-and-greener-gasoline-1
https://ec.europa.eu/energy/sites/ener/files/documents/lv_final_necp_main_en
https://ec.europa.eu/energy/sites/ener/files/documents/lv_final_necp_main_en
https://news.bloombergtax.com/daily-tax-report-international/european-commission-approves-extension-of-swedish-tax-exemption-regime-for-liquid-biofuels
https://news.bloombergtax.com/daily-tax-report-international/european-commission-approves-extension-of-swedish-tax-exemption-regime-for-liquid-biofuels
https://news.bloombergtax.com/daily-tax-report-international/european-commission-approves-extension-of-swedish-tax-exemption-regime-for-liquid-biofuels
http://www.biodieselmagazine.com/articles/2517034/iowa-legislature-extends-fuel-tax-incentive-for-biodiesel-blends
http://www.biodieselmagazine.com/articles/2517034/iowa-legislature-extends-fuel-tax-incentive-for-biodiesel-blends
https://www.bangkokpost.com/business/1846739/energy-ministry-keen-to-maintain-subsidies-for-biofuels
https://www.bangkokpost.com/business/1846739/energy-ministry-keen-to-maintain-subsidies-for-biofuels
Finnish postal fleet to use renewable diesel to drive down emissions
Finnish postal fleet to use renewable diesel to drive down emissions
Finnish postal fleet to use renewable diesel to drive down emissions
Paraguayan Government grants ‘free zone regime’ for Omega Green biofuel plant
Paraguayan Government grants ‘free zone regime’ for Omega Green biofuel plant
Paraguayan Government grants ‘free zone regime’ for Omega Green biofuel plant
http://www.biofutureplatform.org/post/brazil-s-renovabio-emissions-reduction-credits-start-trading-in-the-stock-change
http://www.biofutureplatform.org/post/brazil-s-renovabio-emissions-reduction-credits-start-trading-in-the-stock-change
http://www.biofutureplatform.org/post/brazil-s-renovabio-emissions-reduction-credits-start-trading-in-the-stock-change
UK’s Department for Transport announces funding for biofuel projects
UK’s Department for Transport announces funding for biofuel projects
US Department of Energy to provide $75 million for biofuel crop research
US Department of Energy to provide $75 million for biofuel crop research
US Department of Energy to provide $75 million for biofuel crop research
https://www.agriculture.com/news/business/usda-announces-100-million-in-competitive-grants-for-biofuels-infrastructure
https://www.agriculture.com/news/business/usda-announces-100-million-in-competitive-grants-for-biofuels-infrastructure
https://www.agriculture.com/news/business/usda-announces-100-million-in-competitive-grants-for-biofuels-infrastructure
http://www.biodieselmagazine.com/articles/2517045/iowa-legislature-funds-stateundefineds-biofuel-infrastructure-program
http://www.biodieselmagazine.com/articles/2517045/iowa-legislature-funds-stateundefineds-biofuel-infrastructure-program
https://www.japantimes.co.jp/news/2020/11/25/business/subsidies-electric-vehicles
https://www.japantimes.co.jp/news/2020/11/25/business/subsidies-electric-vehicles
https://www.meti.go.jp/press/2020/12/20201222006/20201222006.html
https://www.meti.go.jp/press/2020/12/20201222006/20201222006.html
https://www.meti.go.jp/press/2020/12/20201222006/20201222006.html
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://www.klimaaktiv.at/mobilitaet/elektromobilitaet/foerderaktion_emob2021.html
https://energy.economictimes.indiatimes.com/news/renewable/kolkata-solar-panels-on-depot-roofs-to-charge-e-buses/74062260
https://energy.economictimes.indiatimes.com/news/renewable/kolkata-solar-panels-on-depot-roofs-to-charge-e-buses/74062260
https://energy.economictimes.indiatimes.com/news/renewable/kolkata-solar-panels-on-depot-roofs-to-charge-e-buses/74062260
https://www.smartcitiesdive.com/news/delaware-transit-agency-electric-bus-solar-array/584048
https://www.smartcitiesdive.com/news/delaware-transit-agency-electric-bus-solar-array/584048
http://www.ren21.net/gsr-2021
https://news.trust.org/item/20200629031504-axvnf
https://news.trust.org/item/20200629031504-axvnf
https://news.trust.org/item/20201204160932-5143z
https://news.trust.org/item/20201204160932-5143z
Polish government’s electric vehicle subsidies fail to attract applications
Polish government’s electric vehicle subsidies fail to attract applications
Polish government’s electric vehicle subsidies fail to attract applications
NSW government triples EV fleet pledge, to ease regulations for charging infrastructure
NSW government triples EV fleet pledge, to ease regulations for charging infrastructure
Sunrise brief: New York offers funds for electric bus transition
Sunrise brief: New York offers funds for electric bus transition
https://www.govtech.com/fs/infrastructure/New-Hawaii-Law-Could-Help-Boost-EV-Charging-Access.html
https://www.govtech.com/fs/infrastructure/New-Hawaii-Law-Could-Help-Boost-EV-Charging-Access.html
https://www.govtech.com/fs/infrastructure/New-Hawaii-Law-Could-Help-Boost-EV-Charging-Access.html
https://www.greentechmedia.com/articles/read/california-targets-384m-to-fill-gaps-in-electric-vehicle-charging-infrastructure
https://www.greentechmedia.com/articles/read/california-targets-384m-to-fill-gaps-in-electric-vehicle-charging-infrastructure
ENDNOTES · POLICY L ANDSCAPE 02
PO
LI
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L
AN
DS
CA
PE112 “Greece goes after cleaner transport with tax breaks for electric
cars”, Reuters, 5 June 2020, https://www.reuters.com/article/
us-climatechange-greece-autos-idUSKBN23C1P6; Rokas
Law Firm, “Law for the Promotion of Electric Mobility provides
economic incentives to purchase e-vehicles”, Lexology, 14
December 2020, https://www.lexology.com/library/detail.
aspx?g=3b6925aa-ded5-494f-b30e-15478c98005f.
113 Tax treatments for hybrids and EVs includes establishment of
a 0% import duty, exemption from paying VAT, and exemption
from the payment of annual registration fees. Consortium
Legal, “Trends in electric mobility: El Salvador on the road to
sustainable mobility in its regulatory framework”, Lexology,
20 October 2020, https://www.lexology.com/library/detail.
aspx?g=af058893-8c15-4b0e-947c-38de7cf6d0ea.
114 “New Jersey passes aggressive e-mobility legislation in effort
to decarbonize transport”, Renewable Energy World, 14 January
2020, https://www.renewableenergyworld.com/2020/01/14/
new-jersey-passes-aggressive-e-mobility-legislation-in-effort-to-
decarbonize-transport.
115 IEA, op. cit. note 1, p. 160.
116 M. Sharmina et al., “Decarbonising the critical sectors of aviation,
shipping, road freight and industry to limit warming to 1.5–2°C”,
Climate Policy (2020), https://doi.org/10.1080/14693062.2020.1
831430; B. Lucas, “Sectors that are challenging to decarbonise”,
K4D, 22 March 2020, p. 9, https://opendocs.ids.ac.uk/opendocs/
bitstream/handle/20.500.12413/15249/786_Sectors_challenging_
to_decarbonise .
117 “Indian Railways gears up to become ‘Green Railway’ by 2030”,
Economic Times, 13 July 2020, https://energy.economictimes.
indiatimes.com/news/power/indian-railways-gears-up-to-
become-green-railway-by-2030/76938990.
118 C. Rollet, “French railway operator buys 40 MW of power through
solar PPA”, pv magazine, 18 June 2020, https://www.pv-magazine.
com/2020/06/18/french-railway-operator-buys-40-mw-of-
power-through-solar-ppa.
119 “Network Rail’s emissions pathway to Net Zero”, Carbon
Intelligence, https://carbon.ci/case-studies/network-rail-
becomes-the-first-railway-organisation-to-set-science-based-
targets-aligned-to-1-5-degrees, viewed 10 March 2021.
120 Biofuels International,“Netherlands examines biofuels’ law
changes to meet RED II targets”, 11 December 2020, https://
biofuels-news.com/news/netherlands-examines-biofuels-law-
changes-to-meet-red-ii-targets.
121 S. Djunisic, “Port of Valencia plans to add 8.5 MW of PV for
own operations”, Renewables Now, 22 April 2020, https://
renewablesnow.com/news/port-of-valencia-plans-to-add-85-
mw-of-pv-for-own-operations-695937; E. Bellini, “Portuguese
green hydrogen for the Port of Rotterdam”, pv magazine, 24
September 2020,,https://www.pv-magazine.com/2020/09/24/
portuguese-green-hydrogen-for-the-port-of-rotterdam.
122 E. Voegele, “Norway to implement biofuel mandate for aviation
fuel in 2020”, Biodiesel Magazine, 11 October 2018, http://
www.biodieselmagazine.com/articles/2516476/norway-to-
implement-biofuel-mandate-for-aviation-fuel-in-2020; Gevo,
Inc., “Sweden and Norway target increased use of sustainable
aviation fuel”, Global Newswire, 21 September 2020, https://www.
globenewswire.com/news-release/2020/09/21/2096569/0/en/
Sweden-and-Norway-Target-Increased-Use-of-Sustainable-
Aviation-Fuel.html.
123 European Commission, “Sustainable aviation fuels – ReFuelEU
Aviation”, https://ec.europa.eu/info/law/better-regulation/
have-your-say/initiatives/12303-ReFuelEU-Aviation-Sustainable-
Aviation-Fuels, viewed 23 February 2021; “Aviation and fuel
sectors respond favourably to major EU policy initiative to boost
sustainable aviation fuels”, Green Air, 30 April 2020, https://www.
greenaironline.com/news.php?viewStory=2688.
124 Connexion, “France to oblige airlines to use green but expensive biofuel”,
12 December 2020, https://www.connexionfrance.com/French-news/
France-to-oblige-airlines-to-use-green-but-expensive-biofuel.
125 “Europe makes legislative push for aviation transition”, Argus
Media, 30 September 2020, https://www.argusmedia.com/en/
news/2145902-europe-makes-legislative-push-for-aviation-transition.
126 Neste, “Neste: Sweden becomes a frontrunner in
sustainable aviation”, 17 September 2020, https://
www.neste.com/releases-and-news/aviation/
neste-sweden-becomes-frontrunner-sustainable-aviation.
127 Government of the United Kingdom, “Jet Zero Council”, https://
www.gov.uk/government/groups/jet-zero-council, viewed 10
March 2021.
128 Globally, distributed solar PV capacity is forecast to increase
more than 250% by 2024. IEA, Renewables 2019 (Paris: 2019),
https://www.iea.org/reports/renewables-2019/distributed-
solar-pv; IRENA, Climate Change and Renewable Energy:
National Policies and the Role of Communities, Cities and Regions
(Abu Dhabi: 2019), p. 27, https://www.irena.org/-/media/Files/
IRENA/Agency/Publication/2019/Jun/IRENA_G20_climate_
sustainability_2019 ; SolarPower Europe, op. cit. note 69, p. 25;
IEA, Trends in Photovoltaic Applications 2020 (Paris: 2020), p. 4,
https://iea-pvps.org/wp-content/uploads/2020/11/IEA_PVPS_
Trends_Report_2020-1 .
129 Box 5 based on the following sources: IRENA, Towards 100%
Renewable Energy: Utilities In Transition (Abu Dhabi: 2020), pp.
14, 16, https://coalition.irena.org/-/media/Files/IRENA/Coalition-
for-Action/IRENA_Coalition_utilities_2020 ; “Greece’s PPC
to spend 3.4 bln euro on power grid, renewables by 2023”,
Reuters, 3 December 2020, https://energy.economictimes.
indiatimes.com/news/renewable/greeces-ppc-to-spend-3-4-
bln-euro-on-power-grid-renewables-by-2023/79539896. At
least 15 utilities had renewable commitments by the end of 2019.
L. Bird and T. Clevenger, “2019 was a watershed year for clean
energy commitments from U.S. states and utilities”, WRI Blog, 20
December 2019, https://www.wri.org/blog/2019/12/2019-was-
watershed-year-clean-energy-commitments-us-states-and-
utilities; H. K. Trabish, “As 100% renewables goals proliferate,
what role for utilities?” Utility Dive, 2 April 2019, https://www.
utilitydive.com/news/as-100-renewables-goals-proliferate-what-
role-for-utilities/551165; J. St. John, “As fossil fuel pipelines fall to
opposition, utilities see renewable energy as safe bet”, Greentech
Media, 6 July 2020, https://www.greentechmedia.com/articles/
read/as-fossil-fuel-pipelines-fall-to-opposition-can-clean-energy-
replace-them; S. Vorrath, “New Mexico utility to replace coal plant
with four solar and battery projects”, RenewEconomy, 16 October
2020, https://reneweconomy.com.au/new-mexico-utility-to-
replace-coal-plant-with-four-solar-and-battery-projects-31989; J.
St. John, “FirstEnergy’s carbon-reduction pledge lacks clear path
to cutting coal use”, Greentech Media, 11 November 2020,https://
www.greentechmedia.com/articles/read/firstenergys-carbon-
neutral-by-2050-pledge-lacks-clear-path-to-cutting-coal-use; T.
Bacon, “Power company commitments to cut carbon pollution are
an important step for our climate and health. Here’s what we need
next”, Environmental Defense Fund, 5 May 2020, http://blogs.edf.
org/climate411/2020/05/05/power-company-commitments-to-
cut-carbon-pollution-are-an-important-step-for-our-climate-and-
health-heres-what-we-need-next; J. St. John, “The 5 biggest us
utilities committing to zero carbon emissions by 2050”, Greentech
Media, 16 September 2020, https://www.greentechmedia.com/
articles/read/the-5-biggest-u.s-utilities-committing-to-zero-
carbon-emissions-by-mid-century; S. Carpenter, “U.S. utility
companies rush to declare net-zero targets”, Forbes, 15 October
2020, https://www.forbes.com/sites/scottcarpenter/2020/10/15/
us-utility-companies-rush-to-declare-net-zero-targets.
130 Bundesministerium Klimashutz, Umwelt, Energie, Mobilität,
Innovation und Technologie, “Energiewende für Österreich
eingeleitet: Bundesregierung präsentiert Erneuerbaren-Ausbau-
Gesetz”, 11 March 2021, https://www.bmk.gv.at/service/presse/
gewessler/20210311_eag.html.
131 Fransen et al., op. cit. note 17; IISD, “75 leaders announce…”,
op. cit. note 17; UNFCCC, “Climate Ambition Summit builds
momentum for COP26”, 12 December 2002, https://unfccc.
int/news/climate-ambition-summit-builds-momentum-for-
cop26; M. Darby, J. Lo and C. Farand, “As it happened: World
leaders upgrade climate commitments on Paris anniversary”,
12 December 2020, https://www.climatechangenews.
com/2020/12/12/live-world-leaders-upgrade-climate-
commitments-paris-anniversary-summit.
132 “Rhode Island governor aims for 100% renewable power by
2030”, Reuters, 17 January 2020, https://www.nytimes.com/
reuters/2020/01/17/us/17reuters-usa-rhode-island-renewables.html.
133 S. Vorrath, “Tasmania sets world-leading target of 200 per cent
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200-per-cent-renewables-by-2040.
134 Africa Energy Portal, “Zimbabwe launches renewable energy,
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279
https://www.reuters.com/article/us-climatechange-greece-autos-idUSKBN23C1P6
https://www.reuters.com/article/us-climatechange-greece-autos-idUSKBN23C1P6
https://www.lexology.com/library/detail.aspx?g=3b6925aa-ded5-494f-b30e-15478c98005f
https://www.lexology.com/library/detail.aspx?g=3b6925aa-ded5-494f-b30e-15478c98005f
https://www.lexology.com/library/detail.aspx?g=af058893-8c15-4b0e-947c-38de7cf6d0ea
https://www.lexology.com/library/detail.aspx?g=af058893-8c15-4b0e-947c-38de7cf6d0ea
New Jersey passes aggressive e-Mobility legislation in effort to decarbonize transport
New Jersey passes aggressive e-Mobility legislation in effort to decarbonize transport
New Jersey passes aggressive e-Mobility legislation in effort to decarbonize transport
https://doi.org/10.1080/14693062.2020.1831430
https://doi.org/10.1080/14693062.2020.1831430
https://opendocs.ids.ac.uk/opendocs/bitstream/handle/20.500.12413/15249/786_Sectors_challenging_to_decarbonise
https://opendocs.ids.ac.uk/opendocs/bitstream/handle/20.500.12413/15249/786_Sectors_challenging_to_decarbonise
https://opendocs.ids.ac.uk/opendocs/bitstream/handle/20.500.12413/15249/786_Sectors_challenging_to_decarbonise
https://energy.economictimes.indiatimes.com/news/power/indian-railways-gears-up-to-become-green-railway-by-2030/76938990
https://energy.economictimes.indiatimes.com/news/power/indian-railways-gears-up-to-become-green-railway-by-2030/76938990
https://energy.economictimes.indiatimes.com/news/power/indian-railways-gears-up-to-become-green-railway-by-2030/76938990
French railway operator buys 40 MW of power through solar PPA
French railway operator buys 40 MW of power through solar PPA
French railway operator buys 40 MW of power through solar PPA
https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
Netherlands examines biofuels’ law changes to meet RED II targets
Netherlands examines biofuels’ law changes to meet RED II targets
Netherlands examines biofuels’ law changes to meet RED II targets
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
https://renewablesnow.com/news/port-of-valencia-plans-to-add-85-mw-of-pv-for-own-operations-695937
http://www.biodieselmagazine.com/articles/2516476/norway-to-implement-biofuel-mandate-for-aviation-fuel-in-2020
http://www.biodieselmagazine.com/articles/2516476/norway-to-implement-biofuel-mandate-for-aviation-fuel-in-2020
http://www.biodieselmagazine.com/articles/2516476/norway-to-implement-biofuel-mandate-for-aviation-fuel-in-2020
https://www.globenewswire.com/news-release/2020/09/21/2096569/0/en/Sweden-and-Norway-Target-Increased-Use-of-Sustainable-Aviation-Fuel.html
https://www.globenewswire.com/news-release/2020/09/21/2096569/0/en/Sweden-and-Norway-Target-Increased-Use-of-Sustainable-Aviation-Fuel.html
https://www.globenewswire.com/news-release/2020/09/21/2096569/0/en/Sweden-and-Norway-Target-Increased-Use-of-Sustainable-Aviation-Fuel.html
https://www.globenewswire.com/news-release/2020/09/21/2096569/0/en/Sweden-and-Norway-Target-Increased-Use-of-Sustainable-Aviation-Fuel.html
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12303-ReFuelEU-Aviation-Sustainable-Aviation-Fuels
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12303-ReFuelEU-Aviation-Sustainable-Aviation-Fuels
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12303-ReFuelEU-Aviation-Sustainable-Aviation-Fuels
https://www.greenaironline.com/news.php?viewStory=2688
https://www.greenaironline.com/news.php?viewStory=2688
https://www.connexionfrance.com/French-news/France-to-oblige-airlines-to-use-green-but-expensive-biofuel
https://www.connexionfrance.com/French-news/France-to-oblige-airlines-to-use-green-but-expensive-biofuel
https://www.argusmedia.com/en/news/2145902-europe-makes-legislative-push-for-aviation-transition
https://www.argusmedia.com/en/news/2145902-europe-makes-legislative-push-for-aviation-transition
https://www.neste.com/releases-and-news/aviation/neste-sweden-becomes-frontrunner-sustainable-aviation
https://www.neste.com/releases-and-news/aviation/neste-sweden-becomes-frontrunner-sustainable-aviation
https://www.neste.com/releases-and-news/aviation/neste-sweden-becomes-frontrunner-sustainable-aviation
https://www.gov.uk/government/groups/jet-zero-council
https://www.gov.uk/government/groups/jet-zero-council
https://www.iea.org/reports/renewables-2019/distributed-solar-pv
https://www.iea.org/reports/renewables-2019/distributed-solar-pv
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Jun/IRENA_G20_climate_sustainability_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Jun/IRENA_G20_climate_sustainability_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Jun/IRENA_G20_climate_sustainability_2019
https://iea-pvps.org/wp-content/uploads/2020/11/IEA_PVPS_Trends_Report_2020-1
https://iea-pvps.org/wp-content/uploads/2020/11/IEA_PVPS_Trends_Report_2020-1
https://coalition.irena.org/-/media/Files/IRENA/Coalition-for-Action/IRENA_Coalition_utilities_2020
https://coalition.irena.org/-/media/Files/IRENA/Coalition-for-Action/IRENA_Coalition_utilities_2020
https://energy.economictimes.indiatimes.com/news/renewable/greeces-ppc-to-spend-3-4-bln-euro-on-power-grid-renewables-by-2023/79539896
https://energy.economictimes.indiatimes.com/news/renewable/greeces-ppc-to-spend-3-4-bln-euro-on-power-grid-renewables-by-2023/79539896
https://energy.economictimes.indiatimes.com/news/renewable/greeces-ppc-to-spend-3-4-bln-euro-on-power-grid-renewables-by-2023/79539896
https://www.wri.org/blog/2019/12/2019-was-watershed-year-clean-energy-commitments-us-states-and-utilities
https://www.wri.org/blog/2019/12/2019-was-watershed-year-clean-energy-commitments-us-states-and-utilities
https://www.wri.org/blog/2019/12/2019-was-watershed-year-clean-energy-commitments-us-states-and-utilities
https://www.utilitydive.com/news/as-100-renewables-goals-proliferate-what-role-for-utilities/551165
https://www.utilitydive.com/news/as-100-renewables-goals-proliferate-what-role-for-utilities/551165
https://www.utilitydive.com/news/as-100-renewables-goals-proliferate-what-role-for-utilities/551165
https://www.greentechmedia.com/articles/read/as-fossil-fuel-pipelines-fall-to-opposition-can-clean-energy-replace-them
https://www.greentechmedia.com/articles/read/as-fossil-fuel-pipelines-fall-to-opposition-can-clean-energy-replace-them
https://www.greentechmedia.com/articles/read/as-fossil-fuel-pipelines-fall-to-opposition-can-clean-energy-replace-them
New Mexico utility to replace coal plant with four solar and battery projects
New Mexico utility to replace coal plant with four solar and battery projects
https://www.greentechmedia.com/articles/read/firstenergys-carbon-neutral-by-2050-pledge-lacks-clear-path-to-cutting-coal-use
https://www.greentechmedia.com/articles/read/firstenergys-carbon-neutral-by-2050-pledge-lacks-clear-path-to-cutting-coal-use
https://www.greentechmedia.com/articles/read/firstenergys-carbon-neutral-by-2050-pledge-lacks-clear-path-to-cutting-coal-use
https://www.greentechmedia.com/articles/read/the-5-biggest-u.s-utilities-committing-to-zero-carbon-emissions-by-mid-century
https://www.greentechmedia.com/articles/read/the-5-biggest-u.s-utilities-committing-to-zero-carbon-emissions-by-mid-century
https://www.greentechmedia.com/articles/read/the-5-biggest-u.s-utilities-committing-to-zero-carbon-emissions-by-mid-century
https://www.forbes.com/sites/scottcarpenter/2020/10/15/us-utility-companies-rush-to-declare-net-zero-targets
https://www.forbes.com/sites/scottcarpenter/2020/10/15/us-utility-companies-rush-to-declare-net-zero-targets
https://www.bmk.gv.at/service/presse/gewessler/20210311_eag.html
https://www.bmk.gv.at/service/presse/gewessler/20210311_eag.html
https://unfccc.int/news/climate-ambition-summit-builds-momentum-for-cop26
https://unfccc.int/news/climate-ambition-summit-builds-momentum-for-cop26
https://unfccc.int/news/climate-ambition-summit-builds-momentum-for-cop26
AS IT HAPPENED: World leaders upgrade climate commitments on Paris anniversary
AS IT HAPPENED: World leaders upgrade climate commitments on Paris anniversary
AS IT HAPPENED: World leaders upgrade climate commitments on Paris anniversary
https://www.nytimes.com/reuters/2020/01/17/us/17reuters-usa-rhode-island-renewables.html
https://www.nytimes.com/reuters/2020/01/17/us/17reuters-usa-rhode-island-renewables.html
Tasmania sets world-leading target of 200 per cent renewables by 2040
Tasmania sets world-leading target of 200 per cent renewables by 2040
Tasmania sets world-leading target of 200 per cent renewables by 2040
https://africa-energy-portal.org/news/zimbabwe-launches-renewable-energy-biofuels-policies
ENDNOTES · POLICY L ANDSCAPE 02
PO
LI
CY
L
AN
DS
CA
PEnews/zimbabwe-launches-renewable-energy-biofuels-policies;
“Zimbabwe government launches renewable energy policy”, op.
cit. note 40.
135 H. Alshammari, “Saudi Arabia aims to generate 50% of power
from renewables by 2030”, Arab News, 20 January 2021, https://
www.arabnews.com/node/1795406/saudi-arabia; A. Aziz
Aluwaisheg, “The benefits of Saudi Arabia’s renewable energy
push”, Arab News, 29 June 2020, https://www.arabnews.com/
node/1697306; S. Surkes, “Cabinet greenlights target of 30%
renewable energy by 2030”, Times of Israel, 25 October 2020,
https://www.timesofisrael.com/cabinet-greenlights-target-of-
30-renewable-energy-by-2030; E. Bellini, “Israel wants another
15 GW of solar by 2030”, pv magazine, 3 June 2020, https://www.
pv-magazine.com/2020/06/03/israel-wants-another-15-gw-of-
solar-by-2030; E. Bellini, “Israeli government greenlights plan
to add 15 GW of solar by 2030”, pv magazine, 26 October 2020,
https://www.pv-magazine.com/2020/10/26/israeli-government-
greenlights-plan-to-add-15-gw-of-solar-by-2030.
136 Enerdata, “Papua New Guinea unveils its new Nationally
Determined Contribution”, 17 December 2020, https://www.
enerdata.net/publications/daily-energy-news/papua-new-
guinea-unveils-its-new-nationally-determined-contribution.html.
137 The Republic of Korea also committed that all coal-fired power
plants whose 30-year lifecycles expire by 2034 would be retired
(representing around 30 plants out a total of 60 currently in
operation, although 24 coal-fired plants are expected to be
converted to fossil gas). “S. Korea unveils draft plan to foster
renewable energy”, Yonhap News Agency, 8 May 2020, https://
en.yna.co.kr/view/AEN20200508002200320; “The Republic
of Korea confirms energy policy favouring renewables”, NEI
Magazine, 12 May 2020, https://www.neimagazine.com/
news/newssouth-korea-confirms-energy-policy-favouring-
renewables-7919619; I. Slav, “South Korea embarks on an
ambitious renewable energy plan”, OilPrice.com, 26 May 2020,
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Korea-Embarks-On-An-Ambitious-Renewable-Energy-Plan.html.
138 Nikkei, “Japan sets sights on 50% renewable energy by 2050”, 26
December 2020, https://asia.nikkei.com/Spotlight/Environment/
Japan-sets-sights-on-50-renewable-energy-by-2050; L. Griffith,
“Japan is setting 50% renewable energy capacity by 2050”,
Sunday Vision, 26 December 2020, https://www.sundayvision.
co.ug/japan-is-setting-50-renewable-energy-capacity-by-2050.
139 “Uzbekistan plans route to cleaner electricity mix”, World Nuclear
News, 6 May 2020, https://www.world-nuclear-news.org/
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140 J. Costa Figueira, “Government unveils new plans claiming to
make UK world leader in green energy”, Climate Action, 9 October
2020, http://www.climateaction.org/news/government-unveils-
new-plans-to-make-uk-world-leader-in-green-energy.
141 “Hungary unveils ‘Christian democratic’-based climate strategy”,
Economic Times, 17 January 2020, https://energy.economictimes.
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democratic-based-climate-strategy/73320204.
142 A. Frangoul, “Europe is planning a 25-fold increase in offshore
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in-offshore-wind-capacity-by-2050.html; Ocean Energy
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143 R. Randazzo, “Arizona power must come from 100% carbon-free
sources by 2050, regulators decide”, AZ Central, 29 October
2020, https://www.azcentral.com/story/money/business/
energy/2020/10/29/arizona-regulators-require-utilities-have-100-
carbon-free-power-2050/6071275002.
144 J. St. John, “Virginia mandates 100% clean power
by 2045”, Greentech Media, 6 March 2020, https://
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virginia-100-clean-energy-by-2050-mandate-law.
145 Deloitte, Power and Utilities Industry Outlook 2020, https://
www2.deloitte.com/content/dam/Deloitte/us/Documents/
energy-resources/us-2020-power-utilities-midyear ; R.
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todayinenergy/detail.php?id=41473.
146 IEA, op. cit. note 1, p. 146.
147 “Cabinet approves Renewable Energy Act amendment bill”,
Lexology, 23 March 2020, https://www.lexology.com/library/
detail.aspx?g=684805eb-06b4-4b73-93c6-1ea5d06048c7; Baker
McKenzie, “Vietnam increases feed-in-tariffs for biomass power
projects”, 11 March 2020, https://www.bakermckenzie.com/en/
insight/publications/2020/03/vietnam-feed-in-tariffs-biomass-
power-projects; B. Publicover, “Vietnam finally unveils new FITs
for large-scale, rooftop, floating PV”, pv magazine, 7 April 2020,
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unveils-new-fits-for-large-scale-rooftop-floating-pv.
148 A. Richter, “Turkey extends feed-in-tariff scheme for geothermal
to mid-2021”, Think GeoEnergy, 18 September 2020, https://www.
thinkgeoenergy.com/turkey-extends-feed-in-tariff-scheme-for-
geothermal-to-mid-2021; “Turkey’s clean energy production gets
nearly $570M in incentives in June”, Daily Sabah, 19 July 2020,
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energy-production-gets-nearly-570m-in-incentives-in-june.
149 E. Bellini, “Moldova introduces feed-in tariff for
small scale solar”, pv magazine, 2 March 2020,
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moldova-introduces-feed-in-tariff-for-small-scale-solar.
150 E. Bellini, “Czech government plans retroactive cuts for PV
incentives, again”, pv magazine, 25 May 2020, https://www.
pv-magazine.com/2020/05/25/czech-plans-retroactive-cuts-for-
pv-incentives-again; G. Deboutte, “French parliament approves
retroactive FIT cuts for pre-2011, large scale PV”, pv magazine, 17
December 2020, https://www.pv-magazine.com/2020/12/17/french-
parliament-approves-retroactive-fit-cuts-for-pre-2011-large-scale-pv.
151 Legislature of Ukraine, “About modification of some laws of
Ukraine concerning improvement of conditions of support of
production of electric energy from alternative energy sources”,
21 July 2020,https://zakon.rada.gov.ua/laws/show/810-20;
S. Djunisic, “Ukrainian parliament confirms retroactive FiT
cuts”, Renewables Now, 24 July 2020, https://renewablesnow.
com/news/ukrainian-parliament-confirms-retroactive-fit-
cuts-707525; M. Hall, “Ukraine defines level of retroactive FIT
cuts”, pv magazine, 22 July 2020, https://www.pv-magazine.
com/2020/07/22/ukraine-defines-level-of-retroactive-fit-cuts.
152 S. Enkhardt, “Switzerland provides additional $47m for
solar incentives”, pv magazine, 20 April 2020, https://
www.pv-magazine.com/2020/04/20/switzerland-
provides-additional-47m-for-solar-incentives; J. Spaes,
“Switzerland renews support for renewables”, pv magazine,
8 April 2020, https://www.pv-magazine.com/2020/04/08/
switzerland-renews-support-for-renewables.
153 E. Bellini, “China entering post-FIT era with
solid prospects”, pv magazine, 17 June 2020,
https://www.pv-magazine.com/2020/06/17/
china-entering-post-fit-era-with-solid-prospects.
154 Macau Hub, “Angolan minister announces new investment in solar
energy”, 12 February 2020, https://macauhub.com.mo/2020/02/12/
pt-ministro-de-angola-anuncia-novos-investimentos-em-
energia-solar; Power Engineering International, “Djibouti’s first
renewables project launched”, 13 February 2020, https://www.
powerengineeringint.com/2020/02/13/djiboutis-first-renewables-
project-launched; E. Bellini, “Nigeria launches off-grid solar
tender”, pv magazine, 24 August 2020, https://www.pv-magazine.
com/2020/08/24/nigeria-launches-off-grid-solar-tender; E. Bellini,
“Tender for 32 MW solar project subcontractors in Chad”, pv
magazine, 21 July 2020, https://www.pv-magazine.com/2020/07/21/
tender-for-32-mw-solar-project-subcontractors-in-chad.
155 E. Bellini, “Slovakia launches first renewables auction”, pv
magazine, 26 February 2020, https://www.pv-magazine.
com/2020/02/26/slovakia-launches-first-renewables-auction.
156 E. Bellini, “Bhutan launches ground-mounted PV tender”, pv
magazine, 9 September 2020, https://www.pv-magazine.
com/2020/09/09/bhutan-launches-ground-mounted-pv-tender;
A. J. Ang, “Green energy auction seen starting next year”,
BW World, 9 August 2020, https://www.bworldonline.com/
green-energy-auction-seen-starting-next-year.
157 E. Bellini, “Croatia introduces provisions to
tender 1 GW of solar”, pv magazine, 22 May 2020,
280
https://africa-energy-portal.org/news/zimbabwe-launches-renewable-energy-biofuels-policies
https://www.arabnews.com/node/1795406/saudi-arabia
https://www.arabnews.com/node/1795406/saudi-arabia
https://www.arabnews.com/node/1697306
https://www.arabnews.com/node/1697306
https://www.timesofisrael.com/cabinet-greenlights-target-of-30-renewable-energy-by-2030
https://www.timesofisrael.com/cabinet-greenlights-target-of-30-renewable-energy-by-2030
Israeli government greenlights plan to add 15 GW of solar by 2030
Israeli government greenlights plan to add 15 GW of solar by 2030
https://www.enerdata.net/publications/daily-energy-news/papua-new-guinea-unveils-its-new-nationally-determined-contribution.html
https://www.enerdata.net/publications/daily-energy-news/papua-new-guinea-unveils-its-new-nationally-determined-contribution.html
https://www.enerdata.net/publications/daily-energy-news/papua-new-guinea-unveils-its-new-nationally-determined-contribution.html
https://en.yna.co.kr/view/AEN20200508002200320
https://en.yna.co.kr/view/AEN20200508002200320
https://www.neimagazine.com/news/newssouth-korea-confirms-energy-policy-favouring-renewables-7919619
https://www.neimagazine.com/news/newssouth-korea-confirms-energy-policy-favouring-renewables-7919619
https://www.neimagazine.com/news/newssouth-korea-confirms-energy-policy-favouring-renewables-7919619
https://oilprice.com/Latest-Energy-News/World-News/South-Korea-Embarks-On-An-Ambitious-Renewable-Energy-Plan.html
https://oilprice.com/Latest-Energy-News/World-News/South-Korea-Embarks-On-An-Ambitious-Renewable-Energy-Plan.html
https://asia.nikkei.com/Spotlight/Environment/Japan-sets-sights-on-50-renewable-energy-by-2050
https://asia.nikkei.com/Spotlight/Environment/Japan-sets-sights-on-50-renewable-energy-by-2050
https://www.world-nuclear-news.org/Articles/Uzbekistan-plans-route-to-cleaner-electricity-mix
https://www.world-nuclear-news.org/Articles/Uzbekistan-plans-route-to-cleaner-electricity-mix
http://www.climateaction.org/news/government-unveils-new-plans-to-make-uk-world-leader-in-green-energy
http://www.climateaction.org/news/government-unveils-new-plans-to-make-uk-world-leader-in-green-energy
https://energy.economictimes.indiatimes.com/news/renewable/hungary-unveils-christian-democratic-based-climate-strategy/73320204
https://energy.economictimes.indiatimes.com/news/renewable/hungary-unveils-christian-democratic-based-climate-strategy/73320204
https://energy.economictimes.indiatimes.com/news/renewable/hungary-unveils-christian-democratic-based-climate-strategy/73320204
https://www.cnbc.com/2020/11/19/europe-plans-25-fold-increase-in-offshore-wind-capacity-by-2050.html
https://www.cnbc.com/2020/11/19/europe-plans-25-fold-increase-in-offshore-wind-capacity-by-2050.html
https://www.cnbc.com/2020/11/19/europe-plans-25-fold-increase-in-offshore-wind-capacity-by-2050.html
https://www.weamec.fr/en/wp-content/uploads/sites/2/2021/03/OEE-Stats-Trends-2020
https://www.weamec.fr/en/wp-content/uploads/sites/2/2021/03/OEE-Stats-Trends-2020
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https://www.azcentral.com/story/money/business/energy/2020/10/29/arizona-regulators-require-utilities-have-100-carbon-free-power-2050/6071275002
https://www.azcentral.com/story/money/business/energy/2020/10/29/arizona-regulators-require-utilities-have-100-carbon-free-power-2050/6071275002
https://www.azcentral.com/story/money/business/energy/2020/10/29/arizona-regulators-require-utilities-have-100-carbon-free-power-2050/6071275002
https://www.greentechmedia.com/articles/read/virginia-100-clean-energy-by-2050-mandate-law
https://www.greentechmedia.com/articles/read/virginia-100-clean-energy-by-2050-mandate-law
https://www.greentechmedia.com/articles/read/virginia-100-clean-energy-by-2050-mandate-law
https://www2.deloitte.com/content/dam/Deloitte/us/Documents/energy-resources/us-2020-power-utilities-midyear
https://www2.deloitte.com/content/dam/Deloitte/us/Documents/energy-resources/us-2020-power-utilities-midyear
https://www2.deloitte.com/content/dam/Deloitte/us/Documents/energy-resources/us-2020-power-utilities-midyear
https://www.eia.gov/todayinenergy/detail.php?id=41473
https://www.eia.gov/todayinenergy/detail.php?id=41473
https://www.lexology.com/library/detail.aspx?g=684805eb-06b4-4b73-93c6-1ea5d06048c7
https://www.lexology.com/library/detail.aspx?g=684805eb-06b4-4b73-93c6-1ea5d06048c7
https://www.bakermckenzie.com/en/insight/publications/2020/03/vietnam-feed-in-tariffs-biomass-power-projects
https://www.bakermckenzie.com/en/insight/publications/2020/03/vietnam-feed-in-tariffs-biomass-power-projects
https://www.bakermckenzie.com/en/insight/publications/2020/03/vietnam-feed-in-tariffs-biomass-power-projects
Vietnam finally unveils new FITs for large-scale, rooftop, floating PV
Vietnam finally unveils new FITs for large-scale, rooftop, floating PV
Turkey extends feed-in-tariff scheme for geothermal to mid-2021
Turkey extends feed-in-tariff scheme for geothermal to mid-2021
Turkey extends feed-in-tariff scheme for geothermal to mid-2021
https://www.dailysabah.com/business/energy/turkeys-clean-energy-production-gets-nearly-570m-in-incentives-in-june
https://www.dailysabah.com/business/energy/turkeys-clean-energy-production-gets-nearly-570m-in-incentives-in-june
Czech government plans retroactive cuts for PV incentives, again
Czech government plans retroactive cuts for PV incentives, again
Czech government plans retroactive cuts for PV incentives, again
French parliament approves retroactive FIT cuts for pre-2011, large scale PV
French parliament approves retroactive FIT cuts for pre-2011, large scale PV
https://zakon.rada.gov.ua/laws/show/810-20
https://renewablesnow.com/news/ukrainian-parliament-confirms-retroactive-fit-cuts-707525
https://renewablesnow.com/news/ukrainian-parliament-confirms-retroactive-fit-cuts-707525
https://renewablesnow.com/news/ukrainian-parliament-confirms-retroactive-fit-cuts-707525
https://macauhub.com.mo/2020/02/12/pt-ministro-de-angola-anuncia-novos-investimentos-em-energia-solar
https://macauhub.com.mo/2020/02/12/pt-ministro-de-angola-anuncia-novos-investimentos-em-energia-solar
https://macauhub.com.mo/2020/02/12/pt-ministro-de-angola-anuncia-novos-investimentos-em-energia-solar
https://www.bworldonline.com/green-energy-auction-seen-starting-next-year
https://www.bworldonline.com/green-energy-auction-seen-starting-next-year
ENDNOTES · POLICY L ANDSCAPE 02
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CA
PEhttps://www.pv-magazine.com/2020/05/22/
croatia-introduces-provisions-to-tender-1-gw-of-solar.
158 S. Enkhardt, “Germany launches 650 MW tender for ‘innovative’
renewables”, pv magazine, 13 July 2020, https://www.
pv-magazine.com/2020/07/13/germany-launches-650-mw-
tender-for-innovative-renewables; “New innovation rules for
German tenders”, reNEWS, 29 January 2020, , https://renews.
biz/57684/new-innovation-rules-for-german-tenders.
159 “UK plans to include onshore wind, solar in next round of
support auctions”, Economic Times, 3 March 2020, https://
energy.economictimes.indiatimes.com/news/renewable/
uk-plans-to-include-onshore-wind-solar-in-next-round-of-
support-auctions/74454411; Smart Energy, “UK govt reinstates
subsidies for wind, solar from 2021”, 17 April 2020, https://
www.smart-energy.com/industry-sectors/policy-regulation/
uk-govt-reinstates-subsidies-for-wind-solar-from-2021.
160 E. Bellini, “Botswana launches net metering scheme
for rooftop PV”, pv magazine, 10 November 2020,
https://www.pv-magazine.com/2020/11/10/
botswana-launches-net-metering-scheme-for-rooftop-pv.
161 E. Bellini, “Tunisia introduces new rules for self-
consumption, net metering”, pv magazine, 28 February
2020, https://www.pv-magazine.com/2020/02/28/
tunisia-introduces-new-rules-for-self-consumption-net-metering.
162 E. Bellini, “Zimbabwe launches smart-meter-led net metering and
500 MW solar tender”, pv magazine, 18 May 2020, https://www.
pv-magazine.com/2020/05/18/zimbabwe-launches-smart-meter-
led-net-metering-and-500-mw-solar-tender; E. Bellini, “Saudi
Arabia outlines new provisions for rooftop PV”, pv magazine,
13 July 2020, https://www.pv-magazine.com/2020/07/13/
saudi-arabia-introduces-new-provisions-for-rooftop-pv.
163 A. Parikh, “Kerala orders discoms to give net metering to prosumers
on a first come, first serve basis”, Mercom India, 20 February 2020,
https://mercomindia.com/kerala-discoms-net-metering-prosumers;
S. Weigel, “Virginia Clean Economy Act passes in the Virginia
General Assembly”, Edison Energy, 13 March 2020, https://www.
edisonenergy.com/blog/energy-policy-were-watching-in-2020-vcea.
164 A. Verma, “Kerala Commission issues renewable energy
and net metering regulations”, Saur Energy International, 24
February 2020, https://www.saurenergy.com/solar-energy-
news/kerala-commission-issues-renewable-energy-and-
net-metering-regulations; I. Tsagas, “Dubai utility clamps
down on net-metered commercial solar”, pv magazine, 26
May 2020, https://www.pv-magazine.com/2020/05/26/
dubai-utility-clamps-down-on-net-metered-commercial-solar.
165 M. Hall, “Egypt to impose ‘merger fee’ on net-metered solar”,
pv magazine, 28 September 2020, https://www.pv-magazine.
com/2020/09/28/egypt-to-impose-merger-fee-on-net-metered-
solar; M. Farag, “EgyptERA pursues solar energy users by
charging amalgamation fees”, Daily News Egypt, 22 September
2020, https://dailynewsegypt.com/2020/09/22/egyptera-
pursues-solar-energy-users-by-charging-amalgamation-fees.
166 J. Spaes, “Wallonia’s prosumer grid fee comes into force”, pv
magazine, 29 September 2020, https://www.pv-magazine.
com/2020/09/29/wallonias-prosumer-grid-fee-comes-into-force.
167 A. Proudlove, B. Lips and D. Sarkisian, The 50 States of Solar:
2020 Policy Review and Q4 2020 Quarterly Report Executive
Summary (Raleigh: North Carolina Clean Energy Technology
Center, January 2021), https://static1.squarespace.com/
static/5ac5143f9d5abb8923a86849/t/601093095908283f6
19d1b34/1611698959121/Q4-20-Solar-Exec-Summary-Final.
pdf; K. Pickerel, “Which states offer net metering?” Solar Power
World, 27 March 2020, https://www.solarpowerworldonline.
com/2020/03/which-states-offer-net-metering; A. Brentan, “A
unanimous FERC decision saves net metering, but its future
remains uncertain”, Forbes, 17 July 2020, https://www.forbes.
com/sites/brentanA./2020/07/17/a-unanimous-ferc-decision-
saves-net-metering-but-its-future-remains-uncertain.
168 Ibid., all references.
169 Ibid., all references.
170 R. Walton, “New York adopts net metering alternative, delays
implementation due to COVID-19”, Utility Dive, 17 July 2020,
https://www.utilitydive.com/news/new-york-adopts-net-
metering-alternative-delays-implementation-due-to-covi/581812.
171 Proudlove, Lips and Sarkisian, op. cit. note 167; Pickerel, op. cit.
note 167; Brentan, op. cit. note 167.
172 European Commission, EU Renewable Energy Financing
Mechanism (Brussels: 2020), https://ec.europa.eu/energy/
sites/ener/files/documents/eu_renewable_energy_financing_
mechanism_en ; J. Scully, “EU raises emissions reduction
ambition following renewables progress”, PV Tech, 18 September
2020, https://www.pv-tech.org/news/eu-announces-new-
emissions-reduction-target-following-renewables-progress.
173 T. Tsanova, “Austria sets budget, deadline for small solar
subsidy programme”, Renewables Now, 23 June 2020, https://
renewablesnow.com/news/austria-sets-budget-deadline-for-
small-solar-subsidy-programme-703741.
174 V. Spasić, “Greece earmarks EUR 850 million for energy efficiency,
prosumers”, Balkan Green Energy News, 11 August 2020, https://
balkangreenenergynews.com/greece-earmarks-eur-850-million-
for-energy-efficiency-prosumers; E. Bellini, “Greece supports
rooftop PV and residential storage through energy efficiency
program”, pv magazine, 15 December 2020, https://www.
pv-magazine.com/2020/12/15/greece-supports-rooftop-pv-and-
residential-storage-through-energy-efficiency-program.
175 “Dutch gov’t doubles 2020 renewable energy subsidies to 4 bln
euros”, National Post, 4 March 2020, https://nationalpost.com/
pmn/environment-pmn/dutch-govt-doubles-2020-renewable-
energy-subsidies-to-4-bln-euros; “Spain to offer $215 million
in renewable energy subsidies”, Economic Times, 11 September
2020, https://energy.economictimes.indiatimes.com/news/
renewable/spain-to-offer-215-million-in-renewable-energy-
subsidies/78056370.
176 S. Enkhardt, “Switzerland allocates another $513m for
solar incentives”, pv magazine, 15 November 2020, https://
www.pv-magazine.com/2020/11/16/switzerland-allocates-
another-513m-for-solar-incentives; S. Enkhardt, “Switzerland
provides additional $47m for solar incentives”, pv magazine,
20 April 2020, https://www.pv-magazine.com/2020/04/20/
switzerland-provides-additional-47m-for-solar-incentives.
177 Costa Figueira, op. cit. note 140.
178 P. Sánchez Molina, “Colombia streamlines tax
incentives for renewables”, pv magazine, 16 June
2020,https://www.pv-magazine.com/2020/06/16/
colombia-streamlines-tax-incentives-for-renewables.
179 E. Bellini, “Turkey cuts admin fee for rooftop PV systems”,
pv magazine, 13 February 2020, https://www.pv-magazine.
com/2020/02/13/turkey-cuts-admin-fee-for-small-pv-systems.
180 E. Bellini, “Soft loans for Jordan’s solar rebate scheme”, pv
magazine, 30 November 2020, https://www.pv-magazine.
com/2020/11/30/soft-loans-for-jordans-solar-rebate-scheme;J.
Rojo Martín, “Israel’s new government plots 15GW-plus solar plan
as policy priority”, PV Tech, 4 June 2020, https://www.pv-tech.
org/news/israels-new-government-plots-15gw-plus-solar-plan-
as-policy-priority.
181 R. Ranjan, “UP announces ₹15,000-30,000 subsidy for
residential rooftop solar systems up to 10 kW”, Mercom
India, 12 March 2020, https://mercomindia.com/
up-announces-subsidy-residential-rooftop-solar-systems.
182 S. Vorrath, “Renewables industry rejoices as Australia’s biggest
electricity state goes green”, RenewEconomy, 9 November 2020,
https://reneweconomy.com.au/renewables-industry-rejoices-
as-australias-biggest-electricity-state-goes-green-25202; S.
Vorrath, “New crack in solar ceiling as Victoria sweetens rooftop
deal for landlords”, One Step Off the Grid, 28 July 2020, https://
onestepoffthegrid.com.au/new-crack-in-solar-ceiling-as-victoria-
sweetens-rooftop-deal-for-landlords.
183 C. Xuewan and L. Yutong, “China to slash subsidies for renewable
energy amid drive to cut state support”, Caixin Global, 11 March 2020,
https://www.caixinglobal.com/2020-03-11/china-to-slash-subsidies-
for-renewable-energy-amid-drive-to-cut-state-support-101527138.
html; M. Xu and T. Daly, “UPDATE 2-China lifts renewable power
subsidy for 2021 by nearly 5% y/y”, Reuters, 20 November 2020,
https://www.reuters.com/article/china-renewables-subsidy/update-
2-china-lifts-renewable-power-subsidy-for-2021-by-nearly-5-y-y-
idUKL1N2I60PC; C. Xiao, “China unveils boost for 2021 renewable
subsidies, solar wins biggest share”, PV Tech, 25 November
2020,https://www.pv-tech.org/news/china-unveils-boost-for-2021-
renewable-subsidies-solar-wins-biggest-share.
184 Global Wind Energy Council, “A gust of growth in China
makes 2020 a record year for wind energy”, 21 January 2021,
https://gwec.net/a-gust-of-growth-in-china-makes-2020-
281
https://renews.biz/57684/new-innovation-rules-for-german-tenders
https://renews.biz/57684/new-innovation-rules-for-german-tenders
https://energy.economictimes.indiatimes.com/news/renewable/uk-plans-to-include-onshore-wind-solar-in-next-round-of-support-auctions/74454411
https://energy.economictimes.indiatimes.com/news/renewable/uk-plans-to-include-onshore-wind-solar-in-next-round-of-support-auctions/74454411
https://energy.economictimes.indiatimes.com/news/renewable/uk-plans-to-include-onshore-wind-solar-in-next-round-of-support-auctions/74454411
https://energy.economictimes.indiatimes.com/news/renewable/uk-plans-to-include-onshore-wind-solar-in-next-round-of-support-auctions/74454411
Tunisia introduces new rules for self-consumption, net metering
Tunisia introduces new rules for self-consumption, net metering
Zimbabwe launches smart-meter-led net metering and 500 MW solar tender
Zimbabwe launches smart-meter-led net metering and 500 MW solar tender
Zimbabwe launches smart-meter-led net metering and 500 MW solar tender
https://mercomindia.com/kerala-discoms-net-metering-prosumers
https://www.edisonenergy.com/blog/energy-policy-were-watching-in-2020-vcea
https://www.edisonenergy.com/blog/energy-policy-were-watching-in-2020-vcea
https://www.saurenergy.com/solar-energy-news/kerala-commission-issues-renewable-energy-and-net-metering-regulations
https://www.saurenergy.com/solar-energy-news/kerala-commission-issues-renewable-energy-and-net-metering-regulations
https://www.saurenergy.com/solar-energy-news/kerala-commission-issues-renewable-energy-and-net-metering-regulations
EgyptERA pursues solar energy users by charging amalgamation fees
EgyptERA pursues solar energy users by charging amalgamation fees
https://static1.squarespace.com/static/5ac5143f9d5abb8923a86849/t/601093095908283f619d1b34/1611698959121/Q4-20-Solar-Exec-Summary-Final
https://static1.squarespace.com/static/5ac5143f9d5abb8923a86849/t/601093095908283f619d1b34/1611698959121/Q4-20-Solar-Exec-Summary-Final
https://static1.squarespace.com/static/5ac5143f9d5abb8923a86849/t/601093095908283f619d1b34/1611698959121/Q4-20-Solar-Exec-Summary-Final
https://static1.squarespace.com/static/5ac5143f9d5abb8923a86849/t/601093095908283f619d1b34/1611698959121/Q4-20-Solar-Exec-Summary-Final
https://www.forbes.com/sites/brentanA./2020/07/17/a-unanimous-ferc-decision-saves-net-metering-but-its-future-remains-uncertain
https://www.forbes.com/sites/brentanA./2020/07/17/a-unanimous-ferc-decision-saves-net-metering-but-its-future-remains-uncertain
https://www.forbes.com/sites/brentanA./2020/07/17/a-unanimous-ferc-decision-saves-net-metering-but-its-future-remains-uncertain
https://www.utilitydive.com/news/new-york-adopts-net-metering-alternative-delays-implementation-due-to-covi/581812
https://www.utilitydive.com/news/new-york-adopts-net-metering-alternative-delays-implementation-due-to-covi/581812
https://ec.europa.eu/energy/sites/ener/files/documents/eu_renewable_energy_financing_mechanism_en
https://ec.europa.eu/energy/sites/ener/files/documents/eu_renewable_energy_financing_mechanism_en
https://ec.europa.eu/energy/sites/ener/files/documents/eu_renewable_energy_financing_mechanism_en
https://www.pv-tech.org/news/eu-announces-new-emissions-reduction-target-following-renewables-progress
https://www.pv-tech.org/news/eu-announces-new-emissions-reduction-target-following-renewables-progress
https://renewablesnow.com/news/austria-sets-budget-deadline-for-small-solar-subsidy-programme-703741
https://renewablesnow.com/news/austria-sets-budget-deadline-for-small-solar-subsidy-programme-703741
https://renewablesnow.com/news/austria-sets-budget-deadline-for-small-solar-subsidy-programme-703741
Greece earmarks EUR 850 million for energy efficiency, prosumers
Greece earmarks EUR 850 million for energy efficiency, prosumers
Greece earmarks EUR 850 million for energy efficiency, prosumers
Greece supports rooftop PV and residential storage through energy efficiency program
Greece supports rooftop PV and residential storage through energy efficiency program
Greece supports rooftop PV and residential storage through energy efficiency program
https://nationalpost.com/pmn/environment-pmn/dutch-govt-doubles-2020-renewable-energy-subsidies-to-4-bln-euros
https://nationalpost.com/pmn/environment-pmn/dutch-govt-doubles-2020-renewable-energy-subsidies-to-4-bln-euros
https://nationalpost.com/pmn/environment-pmn/dutch-govt-doubles-2020-renewable-energy-subsidies-to-4-bln-euros
https://energy.economictimes.indiatimes.com/news/renewable/spain-to-offer-215-million-in-renewable-energy-subsidies/78056370
https://energy.economictimes.indiatimes.com/news/renewable/spain-to-offer-215-million-in-renewable-energy-subsidies/78056370
https://energy.economictimes.indiatimes.com/news/renewable/spain-to-offer-215-million-in-renewable-energy-subsidies/78056370
https://www.pv-magazine.com/2020/11/30/soft-loans-for-jordans-solar-rebate-scheme;J
https://www.pv-magazine.com/2020/11/30/soft-loans-for-jordans-solar-rebate-scheme;J
https://www.pv-tech.org/news/israels-new-government-plots-15gw-plus-solar-plan-as-policy-priority
https://www.pv-tech.org/news/israels-new-government-plots-15gw-plus-solar-plan-as-policy-priority
https://www.pv-tech.org/news/israels-new-government-plots-15gw-plus-solar-plan-as-policy-priority
https://mercomindia.com/up-announces-subsidy-residential-rooftop-solar-systems
https://mercomindia.com/up-announces-subsidy-residential-rooftop-solar-systems
Renewables industry rejoices as Australia’s biggest electricity state goes green
Renewables industry rejoices as Australia’s biggest electricity state goes green
New crack in solar ceiling as Victoria sweetens rooftop deal for landlords
New crack in solar ceiling as Victoria sweetens rooftop deal for landlords
New crack in solar ceiling as Victoria sweetens rooftop deal for landlords
https://www.caixinglobal.com/2020-03-11/china-to-slash-subsidies-for-renewable-energy-amid-drive-to-cut-state-support-101527138.html
https://www.caixinglobal.com/2020-03-11/china-to-slash-subsidies-for-renewable-energy-amid-drive-to-cut-state-support-101527138.html
https://www.caixinglobal.com/2020-03-11/china-to-slash-subsidies-for-renewable-energy-amid-drive-to-cut-state-support-101527138.html
https://www.reuters.com/article/china-renewables-subsidy/update-2-china-lifts-renewable-power-subsidy-for-2021-by-nearly-5-y-y-idUKL1N2I60PC
https://www.reuters.com/article/china-renewables-subsidy/update-2-china-lifts-renewable-power-subsidy-for-2021-by-nearly-5-y-y-idUKL1N2I60PC
https://www.reuters.com/article/china-renewables-subsidy/update-2-china-lifts-renewable-power-subsidy-for-2021-by-nearly-5-y-y-idUKL1N2I60PC
https://www.pv-tech.org/news/china-unveils-boost-for-2021-renewable-subsidies-solar-wins-biggest-share
https://www.pv-tech.org/news/china-unveils-boost-for-2021-renewable-subsidies-solar-wins-biggest-share
A gust of growth in China makes 2020 a record year for wind energy
ENDNOTES · POLICY L ANDSCAPE 02
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LI
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DS
CA
PEa-record-year-for-wind-energy; K. Lowder, “Wind power &
renewables surge to new record in China”, CleanTechnica,
22 January 2021, https://cleantechnica.com/2021/01/22/
wind-power-renewables-surge-to-new-record-in-china.
185 Xuewan and Yutong, op. cit. note 183; Xu and Daly, op. cit. note
183; Xiao, op. cit. note 183.
186 T. Gillies, “Why California’s new solar mandate could cost new
homeowners up to an extra $10,000”, CNBC, 17 February 2019, https://
www.cnbc.com/2019/02/15/california-solar-panel-mandate-could-
cost-new-homeowners-big.html; SolarPower Europe, Global Market
Outlook for Solar Power, 2020-2024 (Brussels: June 2020), p. 34,https://
www.solarpowereurope.org/global-market-outlook-2020-2024.
187 SolarPower Europe, op. cit. note 186, p. 34.
188 Stuff, “Businesses are paying extra for ‘renewable electricity’
certificates, but are they any more than hot air?” 8 November 2020,
https://www.stuff.co.nz/environment/climate-news/123158045/
businesses-are-paying-extra-for-renewable-electricity-certificates-
but-are-they-any-more-than-hot-air; “New rules to crack down
on ‘greenwash’ in corporate clean energy claims,” Reuters, 29
October 2018, https://www.reutersevents.com/sustainability/
new-rules-crack-down-greenwash-corporate-clean-energy-claims.
189 South Pole, “Energy Attribute Certificates (EACs)”, https://www.
southpole.com/sustainability-solutions/renewable-energy-
certificates, viewed 6 May 2021.
190 Trade Arabia, “Bahrain’s SEA issues Renewable Energy
Certificate”, 19 July 2020, http://www.tradearabia.com/news/
IND_370512.html.
191 Energy Global, “Renewable energy becomes available
to buy in West Africa”, 4 February 2020, https://
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renewable-energy-becomes-available-to-buy-in-west-africa.
192 US Environmental Protection Agency, “Community Choice
Aggregation”, https://www.epa.gov/greenpower/community-
choice-aggregation, viewed 2 February 2020.
193 P. Sánchez Molina, “Chile introduces energy communities”,
pv magazine, 28 September 2020, https://www.pv-magazine.
com/2020/09/28/chile-introduces-energy-communities.
194 C. Rollett, “Energy communities are now allowed in France”,
pv magazine, 23 March 2020, https://www.pv-magazine.com/
2020/03/23/energy-communities-are-now-allowed-in-france.
195 E. Bellini, “Energy community provisions for Italy”, pv magazine, 3
March 2020, https://www.pv-magazine.com/2020/03/03/energy-
community-provisions-for-italy; S. Matalucci, “Italy awards tariff
of €0.11/kWh for shared electricity in energy communities”,
pv magazine, 25 November 2020, https://www.pv-magazine.
com/2020/11/25/italy-awards-tariff-of-e0-11-kwh-for-shared-
electricity-in-energy-communities.
196 CE Legal Matters, “A legislative boost to the energy sector in
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montenegro.
197 Virginia State Corporation Commission, “SCC adopts rules for
introduction of shared community solar projects”, 23 December
2020, https://www.scc.virginia.gov/newsreleases/release/
SCC-Sets-Rules-for-Shared-Community-Solar-Projects.
198 Intergovernmental Panel on Climate Change (IPCC), Renewable
Energy Sources and Climate Change Mitigation (Geneva: 2012),
p. 16, https://archive.ipcc.ch/pdf/special-reports/srren/SRREN_
FD_SPM_final .
199 Ibid., p. 16.
200 Ibid., p. 16.
201 Federal Energy Regulatory Commission, “FERC opens wholesale
markets to distributed resources: Landmark action breaks
down barriers to emerging technologies, boosts competition”,
17 September 2020, https://www.ferc.gov/news-events/news/
ferc-opens-wholesale-markets-distributed-resources-landmark-
action-breaks-down.
202 US National Renewable Energy Laboratory, Sources of
Operational Flexibility (Golden, CO: May 2015), https://www.nrel.
gov/docs/fy15osti/63039 .
203 S. Mahapatra, “India moves ahead with new renewable energy
transmission projects”, CleanTechnica, 10 April 2020, https://
cleantechnica.com/2020/04/10/india-moves-ahead-with-new-
renewable-energy-transmission-projects.
204 S. Dludla, “Eskom on R118bn expansion project to add 30 GW over
10 years”, IOL, 20 October 2020, https://www.iol.co.za/business-
report/energy/eskom-on-r118bn-expansion-project-to-add-30gw-
over-10-years-b5e0cdf7-cb08-4d7a-ae99-682e6d5b11d3.
205 UK Office of Gas and Energy Markets (Ofgem), “Ofgem proposes
£25 billion to transform Great Britain’s energy networks”, press
release (London: 9 July 2020), https://www.ofgem.gov.uk/
publications-and-updates/ofgem-proposes-25-billion-transform-
great-britain-s-energy-networks.
206 M. Maisch, “Queensland fast-tracks new transmission line to
unlock renewables, battery industry investment”, pv magazine, 20
May 2020, https://www.pv-magazine-australia.com/2020/05/20/
queensland-fast-tracks-new-transmission-line-to-unlock-
renewables-battery-industry-investment; Mondaq, “ UK:
Energy update – Victoria acts to enable transmission upgrades
required for renewable generation projects”, 25 February 2020,
https://www.mondaq.com/Article/896954; NSW Government,
“Renewable Energy Zones”, https://energy.nsw.gov.au/
renewables/renewable-energy-zones, viewed 20 October 2020;
M. Mazengarb, “NSW to fast-track network approvals for first
renewable energy zone”, RenewEconomy, 17 December 2020,
https://reneweconomy.com.au/nsw-to-fast-track-network-
approvals-for-first-renewable-energy-zone-53918.
207 Deloitte, “2020 Renewable Energy Industry Outlook: Exploring
renewable energy policy, innovation, and market trends”, https://
www2.deloitte.com/us/en/pages/energy-and-resources/articles/
renewable-energy-outlook.html, viewed 4 November 2019.
208 E. Bellini, “Turkey introduces new provisions for
energy storage”, pv magazine, 19 February 2020,
https://www.pv-magazine.com/2020/02/19/
turkey-introduces-new-provisions-for-energy-storage.
209 G. Parkinson, “NSW to fund four new big battery projects as it
readies to flick switch from coal”, RenewEconomy, 15 August
2020, https://reneweconomy.com.au/nsw-to-fund-four-new-big-
battery-projects-as-it-readies-to-flick-switch-from-coal-82272.
210 S. Enkhardt and E. Bellini, “Incentives for small solar-plus-storage
in Austria and Italy”, pv magazine, 11 March 2020, https://www.
pv-magazine.com/2020/03/11/incentives-for-small-solar-
plus-storage-in-austria-and-italy; E. Bellini, “Italy’s Lombardy
region adds another €20 million for residential PV+storage”,
pv magazine, 30 October 2020, https://www.pv-magazine.
com/2020/10/30/italys-lombardy-region-allocates-another-e20-
million-for-residential-solarstorage.
282
A gust of growth in China makes 2020 a record year for wind energy
https://www.cnbc.com/2019/02/15/california-solar-panel-mandate-could-cost-new-homeowners-big.html
https://www.cnbc.com/2019/02/15/california-solar-panel-mandate-could-cost-new-homeowners-big.html
https://www.cnbc.com/2019/02/15/california-solar-panel-mandate-could-cost-new-homeowners-big.html
https://www.solarpowereurope.org/global-market-outlook-2020-2024
https://www.solarpowereurope.org/global-market-outlook-2020-2024
https://www.stuff.co.nz/environment/climate-news/123158045/businesses-are-paying-extra-for-renewable-electricity-certificates-but-are-they-any-more-than-hot-air
https://www.stuff.co.nz/environment/climate-news/123158045/businesses-are-paying-extra-for-renewable-electricity-certificates-but-are-they-any-more-than-hot-air
https://www.stuff.co.nz/environment/climate-news/123158045/businesses-are-paying-extra-for-renewable-electricity-certificates-but-are-they-any-more-than-hot-air
https://www.reutersevents.com/sustainability/new-rules-crack-down-greenwash-corporate-clean-energy-claims
https://www.reutersevents.com/sustainability/new-rules-crack-down-greenwash-corporate-clean-energy-claims
https://www.southpole.com/sustainability-solutions/renewable-energy-certificates
https://www.southpole.com/sustainability-solutions/renewable-energy-certificates
https://www.southpole.com/sustainability-solutions/renewable-energy-certificates
http://www.tradearabia.com/news/IND_370512.html
http://www.tradearabia.com/news/IND_370512.html
https://www.energyglobal.com/special-reports/04022020/renewable-energy-becomes-available-to-buy-in-west-africa
https://www.energyglobal.com/special-reports/04022020/renewable-energy-becomes-available-to-buy-in-west-africa
https://www.energyglobal.com/special-reports/04022020/renewable-energy-becomes-available-to-buy-in-west-africa
https://www.epa.gov/greenpower/community-choice-aggregation
https://www.epa.gov/greenpower/community-choice-aggregation
Italy awards tariff of €0.11/kWh for shared electricity in energy communities
Italy awards tariff of €0.11/kWh for shared electricity in energy communities
Italy awards tariff of €0.11/kWh for shared electricity in energy communities
https://ceelegalmatters.com/briefings/14839-a-legislative-boost-to-the-energy-sector-in-montenegro
https://ceelegalmatters.com/briefings/14839-a-legislative-boost-to-the-energy-sector-in-montenegro
https://ceelegalmatters.com/briefings/14839-a-legislative-boost-to-the-energy-sector-in-montenegro
https://www.scc.virginia.gov/newsreleases/release/SCC-Sets-Rules-for-Shared-Community-Solar-Projects
https://www.scc.virginia.gov/newsreleases/release/SCC-Sets-Rules-for-Shared-Community-Solar-Projects
https://archive.ipcc.ch/pdf/special-reports/srren/SRREN_FD_SPM_final
https://archive.ipcc.ch/pdf/special-reports/srren/SRREN_FD_SPM_final
https://www.ferc.gov/news-events/news/ferc-opens-wholesale-markets-distributed-resources-landmark-action-breaks-down
https://www.ferc.gov/news-events/news/ferc-opens-wholesale-markets-distributed-resources-landmark-action-breaks-down
https://www.ferc.gov/news-events/news/ferc-opens-wholesale-markets-distributed-resources-landmark-action-breaks-down
https://www.nrel.gov/docs/fy15osti/63039
https://www.nrel.gov/docs/fy15osti/63039
India Moves Ahead With New Renewable Energy Transmission Projects
India Moves Ahead With New Renewable Energy Transmission Projects
India Moves Ahead With New Renewable Energy Transmission Projects
https://www.iol.co.za/business-report/energy/eskom-on-r118bn-expansion-project-to-add-30gw-over-10-years-b5e0cdf7-cb08-4d7a-ae99-682e6d5b11d3
https://www.iol.co.za/business-report/energy/eskom-on-r118bn-expansion-project-to-add-30gw-over-10-years-b5e0cdf7-cb08-4d7a-ae99-682e6d5b11d3
https://www.iol.co.za/business-report/energy/eskom-on-r118bn-expansion-project-to-add-30gw-over-10-years-b5e0cdf7-cb08-4d7a-ae99-682e6d5b11d3
https://www.ofgem.gov.uk/publications-and-updates/ofgem-proposes-25-billion-transform-great-britain-s-energy-networks
https://www.ofgem.gov.uk/publications-and-updates/ofgem-proposes-25-billion-transform-great-britain-s-energy-networks
https://www.ofgem.gov.uk/publications-and-updates/ofgem-proposes-25-billion-transform-great-britain-s-energy-networks
Queensland fast-tracks new transmission line to unlock renewables, battery industry investment
Queensland fast-tracks new transmission line to unlock renewables, battery industry investment
Queensland fast-tracks new transmission line to unlock renewables, battery industry investment
https://www.mondaq.com/Article/896954
https://energy.nsw.gov.au/renewables/renewable-energy-zones
https://energy.nsw.gov.au/renewables/renewable-energy-zones
NSW to fast-track network approvals for first renewable energy zone
NSW to fast-track network approvals for first renewable energy zone
https://www2.deloitte.com/us/en/pages/energy-and-resources/articles/renewable-energy-outlook.html
https://www2.deloitte.com/us/en/pages/energy-and-resources/articles/renewable-energy-outlook.html
https://www2.deloitte.com/us/en/pages/energy-and-resources/articles/renewable-energy-outlook.html
NSW to fund four new big battery projects as it readies to flick switch from coal
NSW to fund four new big battery projects as it readies to flick switch from coal
Incentives for small solar-plus-storage in Austria and Italy
Incentives for small solar-plus-storage in Austria and Italy
Incentives for small solar-plus-storage in Austria and Italy
Italy’s Lombardy region adds another €20 million for residential PV+storage
Italy’s Lombardy region adds another €20 million for residential PV+storage
Italy’s Lombardy region adds another €20 million for residential PV+storage
ENDNOTES · MARKE T AND INDUSTRY TRENDS · BIOENERGY 03
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1 International Energy Agency (IEA), Energy Technology
Perspectives 2020 (Paris: 2020), https://www.iea.org/reports/
energy-technology-perspectives-2020/etp-model.
2 For a description of the bioenergy options and their levels
of maturity, see, for example: Ibid.; Renewable Energy Policy
Network for the 21st Century (REN21), Renewable Energy
Pathways in Road Transport (Paris: 2020), https://www.
ren21.net/2020-re-pathways-in-road-transport; International
Renewable Energy Agency (IRENA), Recycle: Bioenergy, a report
for the G20 Energy Sustainability Working Group (Abu Dhabi:
2020), https://www.irena.org/publications/2020/Sep/Recycle-
Bioenergy; IRENA, IEA and REN21, Renewable Energy Polices in
a Time of Transition: Heating and Cooling (Paris: 2020), https://
www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/
Nov/IRENA_IEA_REN21_Policies_Heating_Cooling_2020 .
3 Based on analysis summarised in Figure 17; see endnote 5 for
this section.
4 Based on IEA, World Energy Outlook 2020 (Paris: 2020), Annex A, World
Balance, https://www.iea.org/reports/world-energy-outlook-2020.
5 Around half from IEA, Renewables 2018 (Paris: 2018), https://
www.iea.org/renewables-2018. Figure 17 estimated shares based
on sources in endnote 50 in Global Overview chapter.
6 IEA, op. cit. note 5.
7 Based on data in Figures 18, 19 and 20; see relevant endnotes.
8 Figure 18 estimated shares in 2019 based on historical data from
IEA, World Energy Balances and Statistics, op. cit. note 5. Figure of
2.81 EJ of renewable electricity for heat in buildings in 2018 from
IEA, op. cit. note 4, and for previous years based on compound
annual growth rate of 5.3% from idem. Total heat demand in
buildings includes electricity for heating and cooling, derived from
estimated renewable electricity for heat and calculated share of
renewable energy in electricity production for target year. See
also Global Overview chapter of this report, Figures 1 and 4.
9 IRENA, IEA and REN21, op. cit. note 2.
10 Based on IEA, op. cit. note 5.
11 IEA et al., Tracking SDG 7: The Energy Progress Report 2020
(Washington, DC: 2020), https://irena.org/-/media/Files/
IRENA/Agency/Publication/2020/May/SDG7Tracking_Energy_
Progress_2020 .
12 Ibid. Household air pollution from polluting cook stoves is linked
directly to 2.5 million premature deaths annually (equal to the
combined total of deaths from malaria, tuberculosis and HIV/AIDS). In
addition, the low efficiency of cooking stoves and charcoal production
means that fuel requirements are high and often exceed local
sustainable supply, leading to pressure on local forestry resources
and damage to local forests, with 27-34% of wood-fuel harvesting
in tropical regions classified as unsustainable. The collection of
biomass, such as firewood, for cooking is very time consuming and
has a high opportunity cost, as the time spent gathering fuelwood
takes time away time from other income-generating activities and
education. These issues disproportionately affect women and children,
as they are the ones often tasked with the cooking and fuel collection.
See IRENA, IEA and REN21, op. cit. note 2.
13 Biogas is a mixture of methane, carbon dioxide and other gases
produced when organic matter is broken down by bacteria in
the absence of air (anaerobic digestion). The gas can be used for
heating and electricity production in engines or turbines. If the
carbon dioxide and other gases are removed, a pure methane
stream can be produced (biomethane). It can be used in the
same way as natural gas, and pressurised and injected into gas
distribution systems for use as a heating fuel or for transport
applications.
14 IEA, op. cit. note 5.
15 IEA, op. cit. note 6.
16 Ibid.
17 Ibid.
18 IEA, op. cit. note 5.
19 IEA, op. cit. note 6
20 Ibid.
21 Ibid.
22 IEA, Renewables 2020 (Paris: 2020), https://www.iea.org/reports/
renewables-2020.
23 Ibid.
24 Ibid.
25 Ibid.
26 Ibid.
27 Ibid.
28 Ibid.
29 Ibid.
30 Ibid.
31 Ibid.
32 Ibid. China is also an important user of biomass for heating in
both buildings and industry, but this is not reflected in current
statistics due to data collection and reporting challenges.
33 REN 21, “Bioenergy”, in Renewables Global Status Report 2020
(Paris: 2020), https://www.ren21.net/gsr-2020/chapters/chapter_03/
chapter_03.
34 Such uses of bioenergy are concentrated in developing and
emerging economies. In more developed countries, large
quantities of wood are used to heat homes in inefficient and often
polluting devices such as open grates, contributing to local air
pollution problems. However, under the statistical conventions
that define traditional biomass as that used for heating in
countries outside the Organisation for Economic Co-operation
and Development (OECD), such fuel use is classified as “modern”.
See, for example, UK Department of Environment and Rural
Affairs, The Potential Air Quality Impacts of Biomass Combustion
(London: 2017), https://uk-air.defra.gov.uk/assets/documents/
reports/cat11/1708081027_170807_AQEG_Biomass_report .
35 IRENA, IEA and REN 21, op. cit. note 2.
36 This concentration in the EU is due in part to climatic reasons,
as building heating requirements are limited in more southern
countries and, to date, bioenergy plays a very limited role in
cooling. Also, by definition, the use of biomass for residential
heating outside the OECD is classified as a “traditional use of
biomass”. Thus, it is not included in the statistics as a “modern
use of biomass”. See IEA, Renewables 2019 (Paris: 2019), p. 136,
https://www.iea.org/renewables2019. Increase of 2% based on
analysis of heat data in the 2018 and 2019 Eurostat SHARES
database, https://ec.europa.eu/eurostat/web/energy/data/
shares, viewed 28 February 2021.
37 Restrictions on the use of oil for heating and on gas connections
for new properties and developments have been announced or
implemented in the United Kingdom, Germany, the Netherlands
and other countries. See IRENA, IEA and REN21, op. cit. note 2.
38 Eurostat SHARES database, op. cit. note 36.
39 Bioenergy Europe, Statistical Report 2020: Pellets (Brussels:
2021), https://bioenergyeurope.org/article.html/268. China also
uses significant quantities of pellets from wood and agricultural
residues, but reliable information on such uses is not available.
40 Ibid.
41 Ibid.
42 Based on analysis of 2019 data in Eurostat SHARES database,
op. cit. note 36.
43 US Energy Information Administration (EIA), Winter Fuels Outlook
(Washington, DC: October 2020), https://www.eia.gov/outlooks/
steo/special/winter/2020_winter_fuels .
44 Ibid.
45 US EIA, Monthly Energy Review (Washington, DC: October 2019),
Table 10.2a, https://www.eia.gov/totalenergy/data/monthly/index.
php#renewable.
46 Natural Resources Canada, “Renewable energy facts”, https://
www.nrcan.gc.ca/science-and-data/data-and-analysis/energy-
data-and-analysis/energy-facts/renewable-energy-facts/20069,
updated 3 April 2020.
47 Bioenergy Europe, op. cit. note 39.
48 Ibid.
49 Bioenergy Europe, Statistical Report 2020: Bioheat (Brussels: 2020),
https://www.bioenergyeurope.org/article/258-bioheat.html.
50 Ibid.
51 Ibid.
52 Ibid.
283
https://www.iea.org/reports/energy-technology-perspectives-2020/etp-model
https://www.iea.org/reports/energy-technology-perspectives-2020/etp-model
https://www.irena.org/publications/2020/Sep/Recycle-Bioenergy
https://www.irena.org/publications/2020/Sep/Recycle-Bioenergy
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_IEA_REN21_Policies_Heating_Cooling_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_IEA_REN21_Policies_Heating_Cooling_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_IEA_REN21_Policies_Heating_Cooling_2020
https://www.iea.org/reports/world-energy-outlook-2020
https://www.iea.org/renewables-2018
https://www.iea.org/renewables-2018
https://irena.org/-/media/Files/IRENA/Agency/Publication/2020/May/SDG7Tracking_Energy_Progress_2020
https://irena.org/-/media/Files/IRENA/Agency/Publication/2020/May/SDG7Tracking_Energy_Progress_2020
https://irena.org/-/media/Files/IRENA/Agency/Publication/2020/May/SDG7Tracking_Energy_Progress_2020
https://www.iea.org/reports/renewables-2020
https://www.iea.org/reports/renewables-2020
https://www.ren21.net/gsr-2020/chapters/chapter_03/chapter_03
https://www.ren21.net/gsr-2020/chapters/chapter_03/chapter_03
https://uk-air.defra.gov.uk/assets/documents/reports/cat11/1708081027_170807_AQEG_Biomass_report
https://uk-air.defra.gov.uk/assets/documents/reports/cat11/1708081027_170807_AQEG_Biomass_report
https://www.iea.org/renewables2019
https://ec.europa.eu/eurostat/web/energy/data/shares
https://ec.europa.eu/eurostat/web/energy/data/shares
https://bioenergyeurope.org/article.html/268
https://www.eia.gov/outlooks/steo/special/winter/2020_winter_fuels
https://www.eia.gov/outlooks/steo/special/winter/2020_winter_fuels
https://www.eia.gov/totalenergy/data/monthly/index.php#renewable
https://www.eia.gov/totalenergy/data/monthly/index.php#renewable
https://www.nrcan.gc.ca/science-and-data/data-and-analysis/energy-data-and-analysis/energy-facts/renewable-energy-facts/20069
https://www.nrcan.gc.ca/science-and-data/data-and-analysis/energy-data-and-analysis/energy-facts/renewable-energy-facts/20069
https://www.nrcan.gc.ca/science-and-data/data-and-analysis/energy-data-and-analysis/energy-facts/renewable-energy-facts/20069
https://www.bioenergyeurope.org/article/258-bioheat.html
ENDNOTES · MARKE T AND INDUSTRY TRENDS · BIOENERGY 03
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S53 Based on analysis of data on biomass for district heating in
France from Eurostat SHARES database, op. cit. note 36. Fonds
Chaleur is the French support scheme that provides for funding
for renewable heat projects; see ADEME, “Le Fonds Chaleur
en bref”, 29 March 2021, https://www.ademe.fr/expertises/
energies-renouvelables-enr-production-reseaux-stockage/
passer-a-laction/produire-chaleur/fonds-chaleur-bref.
54 Bioenergy Europe, op. cit. note 49; three-fold based on analysis
of biomass for district heating data for Lithuania in Eurostat
SHARES database, op. cit. note 36; R. Jonynas et al., “Renewables
for district heating: The case of Lithuania”, Energy, vol. 211 (15
November 2020), p. 119064, https://www.sciencedirect.com/
science/article/pii/S036054422032171X.
55 Jonynas et al., op. cit. note 54.
56 Based on national biofuels data as referenced elsewhere in this
section; biofuels supplemented by data from IEA, Oil 2021 (Paris:
March 2021), https://www.iea.org/reports/oil-2021.
57 Ibid.
58 Ibid.
59 Ibid.
60 Figure 19 based on the following sources: data for 2020 and 2021
based on national biofuels data as referenced elsewhere in this
section; biofuels supplemented by data from IEA, op. cit. note
56; for previous years, see earlier editions of the GSR and related
endnotes. Volumes of fuel converted to energy content using
conversion factors from US Department of Energy, Alternative
Fuels Data Center, https://www.afdc.energy.gov. Lower caloric
value for ethanol is 76,330 Btu/US gallon (21.27 MJ/litre) and for
biodiesel, 119,550 Btu/US gallon (33.32 MJ/litre). Caloric value
for HVO is 34.4 MJ/litre. See Neste, Neste Renewable Diesel
Handbook (Espoo, Finland: 2016), p. 15, https://www.neste.
com/sites/default/files/attachments/neste_renewable_diesel_
handbook .
61 Based on data on biomethane and other advanced biofuels
referenced elsewhere in this section.
62 Based on national biofuels data as referenced elsewhere in this
section; biofuels supplemented by data from IEA, op. cit. note 56.
63 Ibid.
64 US EIA, op. cit. note 45, Table 10.3, updated 22 February 2021.
65 Ibid.
66 IEA, op. cit. note 22, p. 119.
67 Agencia Nacional do Petroleo, Gas Natural e Biocombustiveis
(ANP), “Dados estatísticos”,http://www.anp.gov.br/dados-
estatisticos, viewed 28 February 2021.
68 Ibid., “Vendas, pelas Distribuidoras, dos Derivados Combustíveis
de Petróleo (metros cúbicos)”.
69 A. Oliveira da Costa, Empresa de Pesquisa Energética, “Analysis of
biofuels’ current outlook 2019, July 2020”, presentation, 30 July 2020,
https://www.epe.gov.br/sites-en/publicacoes-dados-abertos/
publicacoes/PublicacoesArquivos/publicacao-213/Presentation_
Biofuels_Current_Outlook-Year_2019 .
70 IEA, op. cit. note 22.
71 US Department of Agriculture (USDA), Global Agricultural Information
Network (GAIN), Corn Ethanol Production Booms in Brazil (Washington,
DC: October 2020), https://apps.fas.usda.gov/newgainapi/api/Report/
DownloadReportByFileName?fileName=Corn%20Ethanol%20
Production%20Booms%20in%20Brazil%20_Brasilia_Brazil_10-04-2020.
72 Ibid.
73 Ibid.
74 IEA, op. cit. note 56.
75 IEA, op. cit. note 22.
76 Ibid.
77 Ibid.
78 Ibid.
79 Based on national biofuels data as referenced elsewhere in this
section; biofuels supplemented by data from IEA, op. cit. note 56.
80 Ibid.
81 Based on biofuels data in Ibid., supplemented by national data as
referenced elsewhere in this section.
82 Ibid.
83 IEA, op. cit. note 22 Palm Oil Analytics, “Indonesia 2021 biodiesel
production to rise sharply. 2020 usage up 34% and production
rise by 2.30%”, 2020, https://palmoilanalytics.com/indonesia-
2021-biodiesel-production-to-rise-sharply-2020-usage-up-34-
and-production-rise-by-2-30.
84 IEA, op. cit. note 22.
85 US EIA, op. cit. note 45, Table 10.4, updated 22 February 2021.
86 The Biodiesel Blender’s tax credit provides support of USD 1
per gallon for biodiesel blended with diesel fuel. The measure
was first put in place in 2005, but was suspended several times
and then restored retroactively. In late 2019, it was restored
retroactively for 2018 and 2019 and guaranteed until 2022.
M. Schneider, “The Biodiesel Tax Credit: What does the new
extension mean?” OPIS Blog, 9 March 2020, http://blog.opisnet.
com/biodiesel-tax-credit.
87 IEA, op. cit. note 22.
88 Ibid.
89 ANP, op. cit. note 67, viewed 28 February 2021.
90 IEA, op. cit. note 22.
91 Ibid.
92 Ibid.
93 HVO is also called HEFA and renewable diesel. It is produced
by treating vegetable oils and other bio-based oils and
liquids, including waste materials such as used cooking oil,
with hydrogen, which removes the oxygen and produces a
hydrocarbon that can be refined into a product whose fuel
qualities are equivalent to fossil-based diesel. The refining
process also produces bio-based LPG and can be tuned to
produce other fuels, including biojet. Renewable diesel can be
used mixed in any proportion with fossil diesel or used on its
own.The production estimate is based on analysis of existing and
new capacity, as shown in the slides in J. Lane, “50 renewable
diesel projects and the technologies behind them”, Biofuels
Digest, 8 February 2021,https://www.biofuelsdigest.com/
bdigest/2021/02/08/50-renewable-diesel-projects-and-the-
technologies-behind-them and in research on specific plant
outputs. See Industry section of Bioenergy text.
94 Based on analysis of Renewable Fuel Standard (RFS) data for
2019 and 2020, from US Environmental Protection Agency (EPA),
“Public data for the Renewable Fuel Standard”, https://www.epa.
gov/fuels-registration-reporting-and-compliance-help/public-
data-renewable-fuel-standard, viewed February25 2021.
95 Lane, op. cit. note 93.
96 Based on analysis of RFS data for 2019 and 2020, from US EPA,
op. cit. note 94.
97 IEA, World Energy Outlook Special Report: Prospects for Biogas
and Biomethane (Paris: 2020), https://www.iea.org/reports/
outlook-for-biogas-and-biomethane-prospects-for-organic-growth.
98 S. Olson, “RNG, cellulosic fuels and the Renewable Fuel Standard”,
BioCycle, 14 February 2017, https://www.biocycle.net/2017/02/14/
biomethane-cellulosic-fuels-renewable-fuel-standard.
99 Based on data in US EPA, “RIN generation and renewable fuel
volume production by fuel type from December 2020”, https://
www.epa.gov/fuels-registration-reporting-and-compliance-help/
spreadsheet-rin-generation-and-renewable-fuel-0, updated
February 2021.
100 Based on an analysis of data to 2019 for biogas use in the
transport sector for each EU country. See Eurostat SHARES
database, “SHARES 2019 detailed results”, Transport tab, https://
ec.europa.eu/eurostat/web/energy/data/shares, viewed 26
February 2021.
101 Ibid.
102 Based on data in US EPA, op. cit. note 99.
103 Bioelectricity capacity based on the national data referenced
elsewhere in this section and for other countries based on
forecast 2020 capacity figures from IEA, op. cit. note 22, datafiles.
104 Ibid.
105 Bioelectricity generation based on national data referenced
elsewhere in this section and for other countries based on forecast
2020 generation figures from IEA, op. cit. note 22, datafiles.
106 Ibid.
107 Ibid
284
https://www.ademe.fr/expertises/energies-renouvelables-enr-production-reseaux-stockage/passer-a-laction/produire-chaleur/fonds-chaleur-bref
https://www.ademe.fr/expertises/energies-renouvelables-enr-production-reseaux-stockage/passer-a-laction/produire-chaleur/fonds-chaleur-bref
https://www.ademe.fr/expertises/energies-renouvelables-enr-production-reseaux-stockage/passer-a-laction/produire-chaleur/fonds-chaleur-bref
https://www.sciencedirect.com/science/article/pii/S036054422032171X
https://www.sciencedirect.com/science/article/pii/S036054422032171X
https://www.iea.org/reports/oil-2021
https://www.afdc.energy.gov
https://www.neste.com/sites/default/files/attachments/neste_renewable_diesel_handbook
https://www.neste.com/sites/default/files/attachments/neste_renewable_diesel_handbook
https://www.neste.com/sites/default/files/attachments/neste_renewable_diesel_handbook
http://www.anp.gov.br/dados-estatisticos
http://www.anp.gov.br/dados-estatisticos
https://www.epe.gov.br/sites-en/publicacoes-dados-abertos/publicacoes/PublicacoesArquivos/publicacao-213/Presentation_Biofuels_Current_Outlook-Year_2019
https://www.epe.gov.br/sites-en/publicacoes-dados-abertos/publicacoes/PublicacoesArquivos/publicacao-213/Presentation_Biofuels_Current_Outlook-Year_2019
https://www.epe.gov.br/sites-en/publicacoes-dados-abertos/publicacoes/PublicacoesArquivos/publicacao-213/Presentation_Biofuels_Current_Outlook-Year_2019
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Corn%20Ethanol%20Production%20Booms%20in%20Brazil%20_Brasilia_Brazil_10-04-2020
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Corn%20Ethanol%20Production%20Booms%20in%20Brazil%20_Brasilia_Brazil_10-04-2020
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Corn%20Ethanol%20Production%20Booms%20in%20Brazil%20_Brasilia_Brazil_10-04-2020
https://palmoilanalytics.com/indonesia-2021-biodiesel-production-to-rise-sharply-2020-usage-up-34-and-production-rise-by-2-30
https://palmoilanalytics.com/indonesia-2021-biodiesel-production-to-rise-sharply-2020-usage-up-34-and-production-rise-by-2-30
https://palmoilanalytics.com/indonesia-2021-biodiesel-production-to-rise-sharply-2020-usage-up-34-and-production-rise-by-2-30
http://blog.opisnet.com/biodiesel-tax-credit
http://blog.opisnet.com/biodiesel-tax-credit
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.biofuelsdigest.com/bdigest/2021/02/08/50-renewable-diesel-projects-and-the-technologies-behind-them
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/public-data-renewable-fuel-standard
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/public-data-renewable-fuel-standard
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/public-data-renewable-fuel-standard
https://www.iea.org/reports/outlook-for-biogas-and-biomethane-prospects-for-organic-growth
https://www.iea.org/reports/outlook-for-biogas-and-biomethane-prospects-for-organic-growth
https://www.biocycle.net/2017/02/14/biomethane-cellulosic-fuels-renewable-fuel-standard
https://www.biocycle.net/2017/02/14/biomethane-cellulosic-fuels-renewable-fuel-standard
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/spreadsheet-rin-generation-and-renewable-fuel-0
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/spreadsheet-rin-generation-and-renewable-fuel-0
https://www.epa.gov/fuels-registration-reporting-and-compliance-help/spreadsheet-rin-generation-and-renewable-fuel-0
https://ec.europa.eu/eurostat/web/energy/data/shares
https://ec.europa.eu/eurostat/web/energy/data/shares
ENDNOTES · MARKE T AND INDUSTRY TRENDS · BIOENERGY 03
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S108 Ibid.
109 China Energy Portal, “Notice on results of the 2020 central
government subsidy applications for biomass power generation
projects”, 17 November 2020, https://chinaenergyportal.org/en/
notice-on-results-of-the-2020-central-government-subsidy-
applications-for-biomass-power-generation-projects.
110 Ibid.
111 US Federal Energy Regulatory Commission, “Office of Energy
Projects Energy Infrastructure Update for January 2021”
(Washington, DC: 2021), https://cms.ferc.gov/sites/default/
files/2021-03/JanuaryMIR%202021 .
112 US EIA, Electric Power Monthly (Washington, DC: February 2021),
Table 1.1a, https://www.eia.gov/electricity/data.php, corrected for
difference between net and gross electricity.
113 Ibid.
114 IEA, op. cit. note 22, datafiles.
115 Ibid.
116 IEA, op. cit. note 22.
117 Ibid.
118 German Federal Ministry for Economic Affairs and Energy (BMWi),
“Zeitreihen zur Entwicklung der erneuerbaren Energien in
Deutschland, 1990-2020” (Berlin: February 2021), Tables 3 and 4,
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/
Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html.
119 IEA, op. cit. note 22, datafiles; ECN, “Dutch renewable energy
support scheme (SDE+)”, https://www.ecn.nl/collaboration/sde/
index.html, viewed 15 March 2021.
120 UK Department for Business, Energy and Industrial Strategy,
“Energy Trends: Renewables”, Table 6.1, https://www.gov.uk/
government/statistics/energy-trends-section-6-renewables,
updated 25 March 2021.
121 Ibid.
122 IEA, op. cit. note 22, datafiles.
123 Ibid.
124 Government of India, Ministry of New and Renewable Energy,
“Physical progress”, https://mnre.gov.in/the-ministry/physical-
progress, viewed 23 February 2021; IEA, op. cit. note 22, datafiles.
125 Bioenergy Europe. cit. note 39.
126 Ibid
127 Ibid.
128 Ibid.
129 Ibid.
130 Ibid.
131 Ibid.
132 Ibid.
133 Ibid.
134 Ibid.
135 Calculation based on calorific value of pellets of 17 GJ per tonne,
from Forest Research, “Typical calorific values of fuels”, https://
www.forestresearch.gov.uk/tools-and-resources/biomass-
energy-resources/reference-biomass/facts-figures/typical-
calorific-values-of-fuels and on total bioheat for buildings for
2018. See Markets section of Bioenergy text.
136 Bioenergy Europe, op. cit. note 39.
137 Ibid.
138 Based on US EIA, Monthly Densified Biomass Fuel Report
(Washington, DC: 15 April 2020), https://www.eia.gov/biofuels/
biomass/#table_data.
139 Bioenergy Europe, op. cit. note 39.
140 Ibid.
141 R. Levinson, “2021: Major changes to the Japanese biomass
market”, Biomass Magazine, 3 February 2021, http://
biomassmagazine.com/articles/17690/2021-major-changes-to-
the-japanese-biomass-market.
142 The debate focuses on the greenhouse gas savings generated
by the use of forestry materials. Some claim that greenhouse
gas emissions from pellets are higher than from coal and that
using forestry materials can also lead to loss of forestry carbon
stocks. Others call for applying a full life-cycle approach and for
harvesting and using forestry materials in line with sustainable
forest management principles, with energy use integrated
with timber production and use for long-lived products, such
as building materials. See, for example: F. Simon,“’Win-win or
lose-lose’: EU scientists highlight two-faced bioenergy policies”,
EURACTIV, 1 February 2021, https://www.euractiv.com/
section/biomass/news/win-win-or-lose-lose-eu-scientists-
highlight-two-faced-bioenergy-policies; IEA Bioenergy, “Is
woody biomass positive for the climate?” (Paris: January 2018),
https://www.ieabioenergy.com/wp-content/uploads/2018/01/
FAQ_WoodyBiomass-Climate_final-1 .
143 EU Science Hub, “Renewable Energy – Recast to 2030 (RED II)”,
https://ec.europa.eu/jrc/en/jec/renewable-energy-recast-2030-
red-ii, updated 23 July 2019. In the original RED, sustainability
criteria applied only to liquid biofuels. The revised directive
extends this to cover solid biomass feedstocks.
144 Levinson, op. cit. note 141.
145 Box 6 based on the following sources: There are many different
definitions of the bioeconomy, which the EU defines as
“using renewable biological resources from land and sea, like
crops, forests, fish, animals and micro-organisms to produce
food, materials and energy”, from European Commission,
“Bioeconomy”, https://ec.europa.eu/info/research-and-
innovation/research-area/environment/bioeconomy_en, viewed
1 March 2021. See, for example, Edinburgh Centre for Carbon
Management Ltd., Forestry Commission Scotland Greenhouse Gas
Emissions Comparison: Carbon Benefits of Timber in Construction
(Edinburgh: 2006), https://forestry.gov.scot/images/corporate/
pdf/carbon-benefits-of-timber-in-construction-2006 . High
value-added products include specialty chemicals based on
cellulose or lignin, building materials, wood-based textiles and
bio-based plastics. They include high-value, specialist bio-based
materials, such as graphene for electricity storage applications,
and novel supply chains, such as producing insect protein
animal feed from low-value residues. European Commission,
“Bioeconomy strategy”, https://ec.europa.eu/info/research-
and-innovation/research-area/environment/bioeconomy/
bioeconomy-strategy_en, viewed 1 March 2021; J. Lane,
“Renewables Chemicals Act introduced: Tax credit for biobased
chemical production, investment”, Biofuels Digest, 10 December
2020, https://www.biofuelsdigest.com/bdigest/2020/12/09/
renewable-chemicals-act-introduced-tax-credit-for-biobased-
chemical-production-investment; European Bioplastics,
“Bioplastics market data”, https://www.european-bioplastics.
org/market, viewed 1 March 2021; Bioplastics News, “Braskem”,
https://bioplasticsnews.com/braskem, viewed 1 March 2021;
UPM, “UPM invests in next generation biochemicals to drive a
switch from fossil raw materials to sustainable solutions”, press
release (Helsinki: 30 January 2020), https://www.upm.com/
about-us/for-media/releases/2020/01/upm-invests-in-next-
generation-biochemicals-to-drive-a-switch-from-fossil-raw-
materials-to-sustainable-solutions.
146 Renewable Fuels Association, Essential Energy – 2021 Ethanol
Industry Outlook (Washington, DC: 17 February 2021), https://
ethanolrfa.org/wp-content/uploads/2021/02/RFA_Outlook_2021_
fin_low .
147 M. Sapp, “ADM not sure when it will reopen idled dry milling
ethanol plants”, Biofuels Digest, 4 August 2020, https://www.
biofuelsdigest.com/bdigest/2020/08/04/adm-not-sure-when-it-
will-reopen-idled-dry-milling-ethanol-plants.
148 Based on analysis of petrol and ethanol prices in the United
States and Brazil, from GlobalPetrolPrices.com, “Download fuel
price data”, https://www.globalpetrolprices.com/data_download.
php, viewed 5 March 2021.
149 Ibid.; USDA, GAIN, Biofuels Annual: Brazil 2020 (Washington, DC:
4 September 2020), https://apps.fas.usda.gov/newgainapi/api/
Report/DownloadReportByFileName?fileName=Biofuels%20
Annual_Sao%20Paulo%20ATO_Brazil_08-03-2020.
150 IEA, op. cit. note 22.
151 Ibid.
152 Ibid.
153 Estimates based on analysis of data in Lane, op. cit. note 93,
plus additional project-specific data for individual projects and
proposals as referenced elsewhere in this section.
154 Ibid.
155 Ibid.
285
https://cms.ferc.gov/sites/default/files/2021-03/JanuaryMIR%202021
https://cms.ferc.gov/sites/default/files/2021-03/JanuaryMIR%202021
https://www.eia.gov/electricity/data.php
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.ecn.nl/collaboration/sde/index.html
https://www.ecn.nl/collaboration/sde/index.html
https://www.gov.uk/government/statistics/energy-trends-section-6-renewables
https://www.gov.uk/government/statistics/energy-trends-section-6-renewables
https://mnre.gov.in/the-ministry/physical-progress
https://mnre.gov.in/the-ministry/physical-progress
https://www.forestresearch.gov.uk/tools-and-resources/biomass-energy-resources/reference-biomass/facts-figures/typical-calorific-values-of-fuels
https://www.forestresearch.gov.uk/tools-and-resources/biomass-energy-resources/reference-biomass/facts-figures/typical-calorific-values-of-fuels
https://www.forestresearch.gov.uk/tools-and-resources/biomass-energy-resources/reference-biomass/facts-figures/typical-calorific-values-of-fuels
https://www.forestresearch.gov.uk/tools-and-resources/biomass-energy-resources/reference-biomass/facts-figures/typical-calorific-values-of-fuels
https://www.eia.gov/biofuels/biomass/#table_data
https://www.eia.gov/biofuels/biomass/#table_data
http://biomassmagazine.com/articles/17690/2021-major-changes-to-the-japanese-biomass-market
http://biomassmagazine.com/articles/17690/2021-major-changes-to-the-japanese-biomass-market
http://biomassmagazine.com/articles/17690/2021-major-changes-to-the-japanese-biomass-market
‘Win-win or lose-lose’: EU scientists highlight two-faced bioenergy policies
‘Win-win or lose-lose’: EU scientists highlight two-faced bioenergy policies
‘Win-win or lose-lose’: EU scientists highlight two-faced bioenergy policies
https://www.ieabioenergy.com/wp-content/uploads/2018/01/FAQ_WoodyBiomass-Climate_final-1
https://www.ieabioenergy.com/wp-content/uploads/2018/01/FAQ_WoodyBiomass-Climate_final-1
https://ec.europa.eu/jrc/en/jec/renewable-energy-recast-2030-red-ii
https://ec.europa.eu/jrc/en/jec/renewable-energy-recast-2030-red-ii
https://ec.europa.eu/info/research-and-innovation/research-area/environment/bioeconomy_en
https://ec.europa.eu/info/research-and-innovation/research-area/environment/bioeconomy_en
https://forestry.gov.scot/images/corporate/pdf/carbon-benefits-of-timber-in-construction-2006
https://forestry.gov.scot/images/corporate/pdf/carbon-benefits-of-timber-in-construction-2006
https://ec.europa.eu/info/research-and-innovation/research-area/environment/bioeconomy/bioeconomy-strategy_en
https://ec.europa.eu/info/research-and-innovation/research-area/environment/bioeconomy/bioeconomy-strategy_en
https://ec.europa.eu/info/research-and-innovation/research-area/environment/bioeconomy/bioeconomy-strategy_en
https://www.biofuelsdigest.com/bdigest/2020/12/09/renewable-chemicals-act-introduced-tax-credit-for-biobased-chemical-production-investment
https://www.biofuelsdigest.com/bdigest/2020/12/09/renewable-chemicals-act-introduced-tax-credit-for-biobased-chemical-production-investment
https://www.biofuelsdigest.com/bdigest/2020/12/09/renewable-chemicals-act-introduced-tax-credit-for-biobased-chemical-production-investment
https://www.upm.com/about-us/for-media/releases/2020/01/upm-invests-in-next-generation-biochemicals-to-drive-a-switch-from-fossil-raw-materials-to-sustainable-solutions
https://www.upm.com/about-us/for-media/releases/2020/01/upm-invests-in-next-generation-biochemicals-to-drive-a-switch-from-fossil-raw-materials-to-sustainable-solutions
https://www.upm.com/about-us/for-media/releases/2020/01/upm-invests-in-next-generation-biochemicals-to-drive-a-switch-from-fossil-raw-materials-to-sustainable-solutions
https://www.upm.com/about-us/for-media/releases/2020/01/upm-invests-in-next-generation-biochemicals-to-drive-a-switch-from-fossil-raw-materials-to-sustainable-solutions
https://ethanolrfa.org/wp-content/uploads/2021/02/RFA_Outlook_2021_fin_low
https://ethanolrfa.org/wp-content/uploads/2021/02/RFA_Outlook_2021_fin_low
https://ethanolrfa.org/wp-content/uploads/2021/02/RFA_Outlook_2021_fin_low
https://www.biofuelsdigest.com/bdigest/2020/08/04/adm-not-sure-when-it-will-reopen-idled-dry-milling-ethanol-plants
https://www.biofuelsdigest.com/bdigest/2020/08/04/adm-not-sure-when-it-will-reopen-idled-dry-milling-ethanol-plants
https://www.biofuelsdigest.com/bdigest/2020/08/04/adm-not-sure-when-it-will-reopen-idled-dry-milling-ethanol-plants
https://www.globalpetrolprices.com/data_download.php
https://www.globalpetrolprices.com/data_download.php
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Biofuels%20Annual_Sao%20Paulo%20ATO_Brazil_08-03-2020
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Biofuels%20Annual_Sao%20Paulo%20ATO_Brazil_08-03-2020
https://apps.fas.usda.gov/newgainapi/api/Report/DownloadReportByFileName?fileName=Biofuels%20Annual_Sao%20Paulo%20ATO_Brazil_08-03-2020
ENDNOTES · MARKE T AND INDUSTRY TRENDS · BIOENERGY 03
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S156 Based on comparison of capacity projections for HVO with current
production levels of FAME and ethanol as cited in the Markets
section Transport Biofuels Market and the data for Figure 19,
op. cit. note 8.
157 The life-cycle analysis for fuels produced from wastes and
residues does not need to take into account emissions associated
with direct or indirect land-use change, whereas this issue is
generally considered when dealing with virgin vegetable oils and
other crop-based biofuels, such as ethanol from corn or sugar or
FAME biodiesel from canola or palm oil.
158 California Air Resources Board, “LCFS Pathway Certified Carbon
Intensities”, https://ww2.arb.ca.gov/resources/documents/lcfs-
pathway-certified-carbon-intensities, viewed 1 March 2021.
159 European Commission, EU Renewable Energy Directive
(Brussels: 2018), Annex 9, https://eur-lex.europa.eu/legal-
content/EN/TXT/?uri=uriserv:OJ.L_.2018.328.01.0082.01.
ENG&toc=OJ:L:2018:328:TOC.
160 B. Fallas, “Humber’s renewable ambitions make grand entrance”,
Phillips 66, 18 November 2020, https://www.phillips66.com/
newsroom/2020-humber-uco; B. Fallas, “Phillips 66 plans world’s
largest renewable fuels plant”, Phillips 66, 12 August 2020, https://
www.phillips66.com/newsroom/rodeo-renewed.
161 Fallas, “Phillips 66 plans world’s largest renewable fuels plant”,
op. cit. note 160.
162 Total, “Energy transition: Total is investing more than EUR 500
million to convert its Grandpuits refinery into a zero-crude
platform for biofuels and bioplastics”, 24 September 2020, https://
www.polymers.total.com/latest-news/energy-transition-total-
investing-more-eu500-million-convert-its-grandpuits-refinery.
163 Total, “La Mède: A multipurpose facility for the energies of tomorrow”,
https://www.total.com/energy-expertise/projects/bioenergies/
la-mede-a-forward-looking-facility, viewed 2 March 2021.
164 ENI, “Biorefineries, a solid example of circular economy”,
https://www.eni.com/en-IT/operations/biorefineries.html,
viewed 2 March 2021.
165 R. Tuttle, “Massive refiners are turning into biofuel plants in
the west”, Bloomberg, 12 August 2020, https://www.bloomberg.
com/news/articles/2020-08-12/phillips-66-is-latest-refiner-to-
shun-crude-oil-in-favor-of-fat.
166 BioRefineries Blog, “Pertamina selects Honeywell UOP
technologies for two HVO projects in Indonesia”, 7 October
2020, https://biorrefineria.blogspot.com/2020/10/Pertamina-
selects-Honeywell-UOP-technologies-for-two-HVO-projects-in-
Indonesia.html.
167 Gasification involves heating biomass feedstocks with a limited
supply of air to produce synthesis gas, a mixture of carbon monoxide,
carbon dioxide, methane and water. This can be used to produce
hydrocarbon fuels via the Fischer-Tropsch process, which uses iron,
cobalt ruthenium or nickel catalysts. The catalyst composition and
process conditions determine the product mix. While several earlier
attempts at using such processes have not been successful, the
process was successfully demonstrated at a pre-commercial scale
in Sweden. IEA Bioenergy, Advanced Biofuels: Potential for Cost
Reduction (Paris: 2020), https://www.ieabioenergy.com/wp-content/
uploads/2020/02/T41_CostReductionBiofuels-11_02_19-final .
168 J. Lane, “Drop-in sustainable aviation fuel: The Digest’s 2020
multi-slide guide to Red Rock”, Biofuels Digest, 6 January 2021,
https://www.biofuelsdigest.com/bdigest/2021/01/06/drop-in-
sustainable-aviation-fuel-the-digests-2020-multi-slide-guide-to-
red-rock.
169 H. Tavares Kennedy, “Competitive Edge: Velocys”, Biofuels
Digest, 3 September 2020, https://www.biofuelsdigest.com/
bdigest/2020/09/03/competitive-edge-velocys.
170 M. Sapp, “Japanese consortium to study SAF production using
Fulcrum’s bioenergy technology”, Biofuels Digest, 27 February
2020, https://www.biofuelsdigest.com/bdigest/2020/02/27/
japanese-consortium-to-study-saf-production-using-fulcrum-
bioenergys-technology.
171 Pyrolysis involves heating biomass with a very restricted supply of
air. This produces gases (often used to heat the process), a char
and pyrolysis oil. This can be used as a heating oil or else further
refined to produce renewable diesel or other fuels.
172 Green Fuel Nordic, “Lieska Refinery begins bio-oil deliveries to
customers”, 4 December 2020, https://www.greenfuelnordic.fi/
en/articles/lieksa-refinery-begins-bio-oil-deliveries-customers.
173 M. Sapp, “FLITE Consortium to build first-of-its kind
Lanzajet ATJ Facility”, Biofuels Digest, 7 January 2021,
https://www.biofuelsdigest.com/bdigest/2021/01/07/
flite-consortium-to-build-first-of-its-kind-lanzajet-atj-facility.
174 Ibid.
175 P. Marchand, “You don’t say: Cellulosic ethanol’s future is
in Europe?” Transport Energy Strategies, 3 March 2021,
https://www.transportenergystrategies.com/2021/03/03/
you-dont-say-cellulosic-ethanol-future-is-in-europe.
176 M. Sapp, “Clariant expects Romanian sunliquid plant to be
online by Q4 2020”, Biofuels Digest, 5 August 2020, https://
www.biofuelsdigest.com/bdigest/2020/08/05/clariant-expects-
romanian-sunliquid-plant-to-be-online-by-q4-2021; M. Sapp,
“Clariant and Chemtex team on developing sunliquid in China”,
Biofuels Digest, 18 August 2020, https://www.biofuelsdigest.
com/bdigest/2020/08/18/clariant-and-chemtex-team-on-
developing-sunliquid-in-china; M. Sapp, “Clariant licenses
sunliquid® cellulosic ethanol technology for Bulgarian facility”,
Biofuels Digest, 27 July 2020, https://www.biofuelsdigest.com/
bdigest/2020/07/27/clariant-licenses-sunliquid-cellulosic-
ethanol-technology-for-bulgarian-facility.
177 International Air Transport Association (IATA), “Fact Sheet
2: Sustainable Aviation Fuel: Technical Certification”
(Geneva: undated), https://www.iata.org/contentassets/
d13875e9ed784f75bac90f000760e998/saf-technical-
certifications .
178 J. Lane, “Sustainable aviation fuels and the technologies,
constraints and burgeoning demand”, 16 February 2021, https://
www.biofuelsdigest.com/bdigest/2021/02/16/sustainable-
aviation-fuels-and-the-technologies-constraints-and-
burgeoning-demand/17.
179 IATA, “Developing sustainable aviation fuel (SAF)”, https://www.
iata.org/en/programs/environment/sustainable-aviation-fuels,
viewed 2 March 2021.
180 H. Tavares Kennedy, “Flying high with aviation biofuel –
continuous SAF supply arrives at SFO and LTN airports, RSB
recognized by ICAO for CORSIA”, Biofuels Digest, 13 December
2020, https://www.biofuelsdigest.com/bdigest/2020/12/13/
flying-high-with-aviation-biofuel-continuous-saf-supply-arrives-
at-sfo-and-ltn-airports-rsb-recognized-by-icao-for-corsia.
181 IEA, op. cit. note 97.
182 Ibid. Total biomethane production is estimated at 35 million tonnes
of oil equivalent (mtoe) (1.05 EJ), compared to 2018 overall global
gas demand of 3,284 mtoe (137 EJ), from IEA, op. cit. note 5.
183 IEA, op. cit. note 97.
184 Based on analysis of data from US EPA, op. cit. note 99, and from
Eurostat SHARES database,op. cit. note 36.
185 US EPA, An Overview of Renewable Natural Gas From Biogas
(Washington, DC: July 2020), https://www.epa.gov/sites/
production/files/2021-02/documents/lmop_rng_document .
186 Energy Vision, “Energy Vision/Argonne study shows rapid expansion
of the US renewable natural gas industry”, press release (New
York: 18 December 2020), https://energy-vision.org/wp-content/
uploads/2020/12/EV-Argonne-2020-RNG-Release .
187 Ibid.
188 H. Tavares Kennedy, “RNG heats up with slurry of 2020 deals,
big players involved, Chevron, BP, Brightmark, Aemetis, Verbio,
Greenlane Renewables”, Biofuels Digest, 11 October 2020, https://
www.biofuelsdigest.com/bdigest/2020/10/11/rng-heats-up-
with-slurry-of-2020-deals-big-players-involved-chevron-bp-
brightmark-aemetis-verbio-greenlane-renewables.
189 M. Sapp, “Tennessee landfill gas biomethane project commissioned
by BP and partners”, Biofuels Digest, 20 August 2020, https://www.
biofuelsdigest.com/bdigest/2020/08/20/tennessee-landfill-gas-rng-
project-commissioned-by-bp-and-partners.
190 M. Sapp, “Construction at $33M Ohio RNG project
launched”, Biofuels Digest, 17 September 2020, https://
www.biofuelsdigest.com/bdigest/2020/09/17/
construction-at-33m-ohio-rng-project-launched/.
191 H. Tavares Kennedy, “Aemetis completes construction of
Phase I dairy digester and pipeline project for RNG”, Biofuels
Digest, 23 August 2020, https://www.biofuelsdigest.com/
bdigest/2020/08/23/aemetis-completes-construction-of-phase-
i-dairy-digester-and-pipeline-project-for-rng.
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https://www.phillips66.com/newsroom/2020-humber-uco
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https://www.biofuelsdigest.com/bdigest/2020/08/05/clariant-expects-romanian-sunliquid-plant-to-be-online-by-q4-2021
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https://www.iata.org/contentassets/d13875e9ed784f75bac90f000760e998/saf-technical-certifications
https://www.iata.org/contentassets/d13875e9ed784f75bac90f000760e998/saf-technical-certifications
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https://www.biofuelsdigest.com/bdigest/2021/02/16/sustainable-aviation-fuels-and-the-technologies-constraints-and-burgeoning-demand/17
https://www.biofuelsdigest.com/bdigest/2021/02/16/sustainable-aviation-fuels-and-the-technologies-constraints-and-burgeoning-demand/17
https://www.biofuelsdigest.com/bdigest/2021/02/16/sustainable-aviation-fuels-and-the-technologies-constraints-and-burgeoning-demand/17
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https://www.iata.org/en/programs/environment/sustainable-aviation-fuels
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https://www.biofuelsdigest.com/bdigest/2020/12/13/flying-high-with-aviation-biofuel-continuous-saf-supply-arrives-at-sfo-and-ltn-airports-rsb-recognized-by-icao-for-corsia
https://www.epa.gov/sites/production/files/2021-02/documents/lmop_rng_document
https://www.epa.gov/sites/production/files/2021-02/documents/lmop_rng_document
https://energy-vision.org/wp-content/uploads/2020/12/EV-Argonne-2020-RNG-Release
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https://www.biofuelsdigest.com/bdigest/2020/10/11/rng-heats-up-with-slurry-of-2020-deals-big-players-involved-chevron-bp-brightmark-aemetis-verbio-greenlane-renewables
https://www.biofuelsdigest.com/bdigest/2020/10/11/rng-heats-up-with-slurry-of-2020-deals-big-players-involved-chevron-bp-brightmark-aemetis-verbio-greenlane-renewables
https://www.biofuelsdigest.com/bdigest/2020/10/11/rng-heats-up-with-slurry-of-2020-deals-big-players-involved-chevron-bp-brightmark-aemetis-verbio-greenlane-renewables
https://www.biofuelsdigest.com/bdigest/2020/10/11/rng-heats-up-with-slurry-of-2020-deals-big-players-involved-chevron-bp-brightmark-aemetis-verbio-greenlane-renewables
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https://www.biofuelsdigest.com/bdigest/2020/08/20/tennessee-landfill-gas-rng-project-commissioned-by-bp-and-partners
https://www.biofuelsdigest.com/bdigest/2020/09/17/construction-at-33m-ohio-rng-project-launched/
https://www.biofuelsdigest.com/bdigest/2020/09/17/construction-at-33m-ohio-rng-project-launched/
https://www.biofuelsdigest.com/bdigest/2020/09/17/construction-at-33m-ohio-rng-project-launched/
https://www.biofuelsdigest.com/bdigest/2020/08/23/aemetis-completes-construction-of-phase-i-dairy-digester-and-pipeline-project-for-rng
https://www.biofuelsdigest.com/bdigest/2020/08/23/aemetis-completes-construction-of-phase-i-dairy-digester-and-pipeline-project-for-rng
https://www.biofuelsdigest.com/bdigest/2020/08/23/aemetis-completes-construction-of-phase-i-dairy-digester-and-pipeline-project-for-rng
ENDNOTES · MARKE T AND INDUSTRY TRENDS · BIOENERGY 03
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S192 M. Sapp, “Verbio’s RNG facility at former DuPont cellulosic
ethanol plant seen for fall 2021”, Biofuels Digest, 7 September
2020, https://www.biofuelsdigest.com/bdigest/2020/09/07/
verbios-rng-facility-at-former-dupont-cellulosic-ethanol-plant-
seen-for-fall-2021.
193 European Biogas Association, Renewable Gas Success Stories 2020
(Brussels: 2020), https://www.europeanbiogas.eu/wp-content/
uploads/2020/12/EBA_Renewable-Gas-Success-Stories-2020 .
194 Bioenergy Insight, “Gasum receives €30 m to build two new biogas
plants”, 11 December 2020, https://www.bioenergy-news.com/
news/gasum-receives-e30m-to-build-two-new-biogas-plants.
195 Bioenergy Insight, “WELTEC BIOPOWER’s €11m
biomethane plant goes live in France”, 30 November
2020, https://www.bioenergy-news.com/news/
weltec-biopowers-e11m-biomethane-plant-goes-live-in-france.
196 Ibid.
197 Bioenergy Insight, “Construction underway on two EnviTec Biogas
projects in China”, 29 September 2020, https://www.bioenergy-news.
com/news/construction-underway-on-two-envitec-biogas-projects-
in-china.
198 Ibid.
199 Bioenergy Insight, “Asda welcomes 202 biomethane-fuelled trucks
to its fleet”, 10 December 2020, https://www.bioenergy-news.com/
news/asda-welcomes-202-biogas-fuelled-trucks-to-its-fleet.
200 Air Liquide, “Air Liquide steps up its biomethane
activity in the UK with a major contract with ASDA”,
21 December 2020, https://energies.airliquide.com/
air-liquide-steps-its-biomethane-activity-uk-major-contract-asda.
201 IEA, “CCUS in Clean Energy Transitions”, part of Energy
Technology Perspectives (Paris: September 2020), https://www.
iea.org/reports/ccus-in-clean-energy-transitions.
202 S. Budinis, “Going carbon negative: What are the technology
options?” IEA, 31 January 2020, https://www.iea.org/
commentaries/going-carbon-negative-what-are-the-technology-
options. “Net negative emissions” means that for each unit of
energy produced and used, there is a net reduction in greenhouse
gas emissions. In this case, the energy is produced from biomass,
which produces CO2 that is then captured and stored. Since the
biomass-based emissions do not involve transferring carbon from
fossil reserves into the atmosphere, each unit of energy produced
reduces atmospheric CO2 levels when the whole cycle is taken
into account.
203 IEA, op. cit. note 202.
204 Bioenergy Insight, “Drax to start BECCS planning application
process”, 1 March 2021, https://www.bioenergy-news.com/news/
drax-to-start-beccs-planning-application-process.
205 Bioenergy Insight, “PowerTap to produce blue
hydrogen using RNG as feedstock”, 16 February
2021, https://www.bioenergy-news.com/news/
powertap-to-produce-blue-hydrogen-using-rng-as-feedstock.
287
https://www.biofuelsdigest.com/bdigest/2020/09/07/verbios-rng-facility-at-former-dupont-cellulosic-ethanol-plant-seen-for-fall-2021
https://www.biofuelsdigest.com/bdigest/2020/09/07/verbios-rng-facility-at-former-dupont-cellulosic-ethanol-plant-seen-for-fall-2021
https://www.biofuelsdigest.com/bdigest/2020/09/07/verbios-rng-facility-at-former-dupont-cellulosic-ethanol-plant-seen-for-fall-2021
https://www.europeanbiogas.eu/wp-content/uploads/2020/12/EBA_Renewable-Gas-Success-Stories-2020
https://www.europeanbiogas.eu/wp-content/uploads/2020/12/EBA_Renewable-Gas-Success-Stories-2020
Construction underway on two EnviTec Biogas projects in China
Construction underway on two EnviTec Biogas projects in China
Construction underway on two EnviTec Biogas projects in China
https://energies.airliquide.com/air-liquide-steps-its-biomethane-activity-uk-major-contract-asda
https://energies.airliquide.com/air-liquide-steps-its-biomethane-activity-uk-major-contract-asda
https://www.iea.org/reports/ccus-in-clean-energy-transitions
https://www.iea.org/reports/ccus-in-clean-energy-transitions
https://www.iea.org/commentaries/going-carbon-negative-what-are-the-technology-options
https://www.iea.org/commentaries/going-carbon-negative-what-are-the-technology-options
https://www.iea.org/commentaries/going-carbon-negative-what-are-the-technology-options
03
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · GEOTHERMAL POWER AND HE AT
GEOTHERMAL POWER AND HEAT
1 Estimates based on the following sources: power capacity data for
Iceland, Japan and New Zealand from International Energy Agency
(IEA) Geothermal, 2019 Country Reports (Taupo, New Zealand:
February 2020), http://iea-gia.org/publications-2/annual-reports
and sources noted elsewhere in this section; power capacity
data for Indonesia, the Philippines, Turkey and the United States
from sources noted elsewhere in this section; capacity data for
other countries from International Renewable Energy Agency
(IRENA), Renewable Capacity Statistics 2021 (Abu Dhabi: 2021),
https://www.irena.org/publications/2021/March/Renewable-
Capacity-Statistics-2021; estimated electricity generation in 2020
based on 95 TWh in 2019 from G. W. Huttrer, “Geothermal power
generation in the world 2015-2020 update report”, Proceedings
World Geothermal Congress 2020, https://www.geothermal-
energy.org/pdf/IGAstandard/WGC/2020/01017 ; and 97 TWh
from Organisation for Economic Co-operation and Development
(OECD) and IEA, Market Report Series – Renewables 2020,
Databook (Paris: 2020). Heat capacity and output in 2020 an
extrapolation based on five-year average annualised growth from
2015 through 2019, from J. W. Lund and A. N. Toth, “Direct utilization
of geothermal energy 2020 worldwide review”, Proceedings World
Geothermal Congress 2020, https://www.geothermal-energy.org/
pdf/IGAstandard/WGC/2020/01018 .
2 End-2019 capacity data and capacity additions in 2020 from
sources in endnote 1.
3 Ibid. Figure 21 based on end-2019 capacity data and capacity
additions in 2020 from sources in endnote 1 and sources noted
elsewhere in this section. For the purpose of this figure, end-2019
capacity is assumed to be equal to end-2020 capacity less new
capacity installed (or capacity expansion) during 2020.
4 End-2019 capacity data from sources in endnote 1; capacity
additions in 2020, by country, from sources noted elsewhere in this
section.
5 This resource-limited capability of a geothermal plant defines its
dependable running capacity, as opposed to the total nameplate
capacity of its generator(s). For the United States, most of the
difference between nameplate and running capacity (about
800 MW) results from plant derating at the Geysers geothermal
field in California, which is not able to the produce enough
steam, due to productivity decline, to operate at nameplate
capacity. Net summer capacity from US Energy Information
Administration (EIA), Electric Power Monthly, February 2021,
Table 6.2.B, https://www.eia.gov/electricity/monthly; nameplate
capacity from US EIA, “Form EIA-860M (Preliminary Monthly
Electric Generator Inventory)”, December 2020, https://www.eia.
gov/electricity/data/eia860m; US Department of Energy (DOE),
Office of Scientific and Technical Information (OSTI), “GeoVision:
Harnessing the heat beneath our feet” (Oak Ridge, TN: June 2019),
p. 24 (footnote 34), https://www.energy.gov/eere/geothermal/
downloads/geovision-harnessing-heat-beneath-our-feet.
6 Capacity of 1,514.7 MW and 54 plants at end-2019, 60 plants
and 1,613.2 MW at end-2020, and annual capacity additions for
2014-2019 from Turkish Electricity Transmission Company (TEİAŞ),
http://www.teias.gov.tr, viewed March 2021.
7 See sum of individual installations as noted in the text.
“Sürdürülebilir Enerji Kaynağı Olan Jeotermal Enerjideki Artış
Umut Verici!” Enerji Gazetesi, 14 December 2020, https://www.
enerjigazetesi.ist/surdurulebilir-enerji-kaynagi-olan-jeotermal-
enerjideki-artis-umut-verici.
8 Exergy, “Exergy delivering more green power: A 26 MWe, a 12
MWe and a 10 MWe geothermal plants come online in Turkey”,
press release (Olgiate Olona, Italy: 9 November 2020), https://
www.exergy-orc.com/upload/pages/537/exergy-geothermal_
start_up_october ; Ormat, “Ormat I Turkey – Oct 2020”, 17
November 2020, https://www.ormat.com/en/company/news/
view/?ContentID=497.
9 Exergy, op. cit. note 8; Ormat, op. cit. note 8.
10 JESDER (Turkey’s geothermal power plants investor association),
“Çelikler Termik Elektrik Üretim A.Ş.’ye ait 32 MWe Kapasiteli
JES-5ORC7 Devreye Alındı”, 17 December 2020, http://jesder.
org/celikler-termik-elektrik-uretim-a-s-ye-ait-32-mwe-kapasiteli-
jes-5orc7-devreye-alindi; A. Richter, “Celikler Holdings brings
additional 32 MW geothermal unit online at Pamukören
Turkey”, Think GeoEnergy, 18 December 2020, https://www.
thinkgeoenergy.com/celikler-holdings-brings-additional-32-mw-
geothermal-unit-online-at-pamukoren-turkey.
11 One of two 30 MW unit completed, from Ormat, “Another
success in Turkey”, 24 December 2020, https://www.ormat.
com/en/company/news/view/?ContentID=8821; Ormat,
“Global projects”, https://www.ormat.com/en/projects/all/
main/?Country=Turkey&Seg=0&Tech=0&pageNum=1, viewed
March 2020; two 25 MW units completed, from “‘EFE 8 Jeotermal
Enerji Santrali’ Bir Dünya Rekoruyla Devreye Alındı!” Enerji Gazetesi,
29 December 2020, https://www.enerjigazetesi.ist/efe-8-jeotermal-
enerji-santrali-bir-dunya-rekoruyla-devreye-alindi; European Bank
for Reconstruction and Development, “Efeler Geothermal Power
Plant”, https://www.ebrd.com/work-with-us/projects/psd/efeler-
gpp.html, viewed March 2021; Mogan Energy Investment Holding
Co., “Energy power plants”, https://www.mogan.com.tr/EN,1102/
energy-power-plants.html, viewed March 2021.
12 See map of geothermal plants at Jesder, http://jesder.org, viewed
March 2021.
13 Capacity of 1,514.7 MW and 54 plants at end-2019, 60 plants and
1,613.2 MW at end-2020, and annual capacity additions 2014-2019
from TEİAŞ, http://www.teias.gov.tr, viewed March 2021.
14 TEİAŞ, op. cit. note 13.
15 “Support mechanism key to Turkey’s renewables growth, EBRD
official says”, Daily Sabah, 11 December 2020, https://www.
dailysabah.com/business/energy/support-mechanism-key-
to-turkeys-renewables-growth-ebrd-official-says; E. B. Erşen,
“Turkey’s renewable energy sector to continue enjoying European
financier EBRD support”, Daily Sabah, 26 February 2020, https://
www.dailysabah.com/business/energy/turkeys-renewable-energy-
sector-to-continue-enjoying-european-financier-ebrd-support.
16 “Support mechanism key to Turkey’s renewables growth”,
op. cit. note 15; “Turkey’s renewable energy sees nearly
$7B investments in 2020”, Daily Sabah, 21 January
2021, https://www.dailysabah.com/business/energy/
turkeys-renewable-energy-sees-nearly-7b-investments-in-2020.
17 Feed-in tariff reduction of around one-third based on existing
tariff of USD 0.105 (plus local content increment of up to USD
0.027) and new tariff of TRY 0.54 (plus local content increment
of TRY 0.08). Existing tariff from General Directorate of Law
and Legislation, “Law no. 5346 on the use of renewable energy
resources for the purpose of generation of electric energy”, https://
www.mevzuat.gov.tr/MevzuatMetin/1.5.5346 ; new tariff from
General Directorate of Law and Legislation, “Presidential Decision
no. 3453”, 30 January 2021, https://www.resmigazete.gov.tr/
eskiler/2021/01/20210130-9 .
18 Net summer capacity from US EIA, Electric Power Monthly,
op. cit. note 5; nameplate capacity from US EIA, “Form EIA-860M”,
op. cit. note 5.
19 Ormat, “Steamboat Hills geothermal power plant enhancement in
Nevada begins commercial operation”, press release (Reno, NV:
22 June 2020), https://investor.ormat.com/news-events/news/
news-details/2020/Steamboat-Hills-Geothermal-Power-Plant-
Enhancement-in-Nevada-Begins-Commercial-Operation/default.aspx.
20 Ibid.
21 Ormat, “Puna geothermal power plant – an island within an island”,
12 November 2020, https://www.ormat.com/en/company/news/
view/?ContentID=8820; Puna Geothermal Venture, https://
punageothermalproject.com, viewed March 2021.
22 Generation for 2020 and revised generation for 2019 from US EIA,
Electric Power Monthly, op. cit. note 5, Tables ES1.B, 1.1 and 1.1.A.
Originally reported and revised generation for 2018 and original
reported generation for 2019 from US EIA, Electric Power Monthly,
February 2019 and February 2020, Tables ES1.B, https://www.eia.
gov/electricity/monthly.
23 Mitsubishi Power, “Mitsubishi Power completes renovation of
generating facilities at Otake Geothermal Power Station – efficient
utilization of geothermal resources to curb CO2 emissions, and
contribute to decarbonized economy”, press release (Yokohama:
5 October 2020), https://power.mhi.com/news/20201005.html.
24 Ibid.
25 Climeon, “A symbolic power plant proving the synergies of Onsen
and Heat Power”, 8 July 2020, https://climeon.com/a-symbolic-
power-plant-proving-the-synergies-of-onsen-and-heat-power;
Climeon, “Geothermal heat power”, https://climeon.com/
geothermal-plants, viewed March 2021.
26 “Tiga PLTP akan Beroperasi Tahun 2020, Total Kapasitas Capai
140 MW”, OG Indonesia, March 2020, http://www.ogindonesia.
288
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01017
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01017
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01018
https://www.geothermal-energy.org/pdf/IGAstandard/WGC/2020/01018
https://www.eia.gov/electricity/monthly
https://www.eia.gov/electricity/data/eia860m
https://www.eia.gov/electricity/data/eia860m
https://www.energy.gov/eere/geothermal/downloads/geovision-harnessing-heat-beneath-our-feet
https://www.energy.gov/eere/geothermal/downloads/geovision-harnessing-heat-beneath-our-feet
http://www.teias.gov.tr
Sürdürülebilir Enerji Kaynağı Olan Jeotermal Enerjideki Artış Umut Verici!
Sürdürülebilir Enerji Kaynağı Olan Jeotermal Enerjideki Artış Umut Verici!
Sürdürülebilir Enerji Kaynağı Olan Jeotermal Enerjideki Artış Umut Verici!
https://www.exergy-orc.com/upload/pages/537/exergy-geothermal_start_up_october
https://www.exergy-orc.com/upload/pages/537/exergy-geothermal_start_up_october
https://www.exergy-orc.com/upload/pages/537/exergy-geothermal_start_up_october
https://www.ormat.com/en/company/news/view/?ContentID=497
https://www.ormat.com/en/company/news/view/?ContentID=497
http://jesder.org/celikler-termik-elektrik-uretim-a-s-ye-ait-32-mwe-kapasiteli-jes-5orc7-devreye-alindi
http://jesder.org/celikler-termik-elektrik-uretim-a-s-ye-ait-32-mwe-kapasiteli-jes-5orc7-devreye-alindi
http://jesder.org/celikler-termik-elektrik-uretim-a-s-ye-ait-32-mwe-kapasiteli-jes-5orc7-devreye-alindi
Celikler Holdings brings additional 32 MW geothermal unit online at Pamukören, Turkey
Celikler Holdings brings additional 32 MW geothermal unit online at Pamukören, Turkey
Celikler Holdings brings additional 32 MW geothermal unit online at Pamukören, Turkey
https://www.ormat.com/en/company/news/view/?ContentID=8821
https://www.ormat.com/en/company/news/view/?ContentID=8821
https://www.ormat.com/en/projects/all/main/?Country=Turkey&Seg=0&Tech=0&pageNum=1
https://www.ormat.com/en/projects/all/main/?Country=Turkey&Seg=0&Tech=0&pageNum=1
‘EFE 8 Jeotermal Enerji Santrali’ Bir Dünya Rekoruyla Devreye Alındı!
‘EFE 8 Jeotermal Enerji Santrali’ Bir Dünya Rekoruyla Devreye Alındı!
https://www.ebrd.com/work-with-us/projects/psd/efeler-gpp.html
https://www.ebrd.com/work-with-us/projects/psd/efeler-gpp.html
https://www.mogan.com.tr/EN,1102/energy-power-plants.html
https://www.mogan.com.tr/EN,1102/energy-power-plants.html
http://www.teias.gov.tr
https://www.dailysabah.com/business/energy/support-mechanism-key-to-turkeys-renewables-growth-ebrd-official-says
https://www.dailysabah.com/business/energy/support-mechanism-key-to-turkeys-renewables-growth-ebrd-official-says
https://www.dailysabah.com/business/energy/support-mechanism-key-to-turkeys-renewables-growth-ebrd-official-says
https://www.dailysabah.com/business/energy/turkeys-renewable-energy-sector-to-continue-enjoying-european-financier-ebrd-support
https://www.dailysabah.com/business/energy/turkeys-renewable-energy-sector-to-continue-enjoying-european-financier-ebrd-support
https://www.dailysabah.com/business/energy/turkeys-renewable-energy-sector-to-continue-enjoying-european-financier-ebrd-support
https://www.dailysabah.com/business/energy/turkeys-renewable-energy-sees-nearly-7b-investments-in-2020
https://www.dailysabah.com/business/energy/turkeys-renewable-energy-sees-nearly-7b-investments-in-2020
https://www.mevzuat.gov.tr/MevzuatMetin/1.5.5346
https://www.mevzuat.gov.tr/MevzuatMetin/1.5.5346
https://www.resmigazete.gov.tr/eskiler/2021/01/20210130-9
https://www.resmigazete.gov.tr/eskiler/2021/01/20210130-9
https://investor.ormat.com/news-events/news/news-details/2020/Steamboat-Hills-Geothermal-Power-Plant-Enhancement-in-Nevada-Begins-Commercial-Operation/default.aspx
https://investor.ormat.com/news-events/news/news-details/2020/Steamboat-Hills-Geothermal-Power-Plant-Enhancement-in-Nevada-Begins-Commercial-Operation/default.aspx
https://investor.ormat.com/news-events/news/news-details/2020/Steamboat-Hills-Geothermal-Power-Plant-Enhancement-in-Nevada-Begins-Commercial-Operation/default.aspx
https://www.ormat.com/en/company/news/view/?ContentID=8820
https://www.ormat.com/en/company/news/view/?ContentID=8820
https://www.eia.gov/electricity/monthly
https://www.eia.gov/electricity/monthly
https://power.mhi.com/news/20201005.html
A symbolic power plant proving the synergies of Onsen and Heat Power
A symbolic power plant proving the synergies of Onsen and Heat Power
https://climeon.com/geothermal-plants
https://climeon.com/geothermal-plants
http://www.ogindonesia.com/2020/03/tiga-pltp-akan-beroperasi-tahun-2020.html
03
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · GEOTHERMAL POWER AND HE AT
com/2020/03/tiga-pltp-akan-beroperasi-tahun-2020.html; R. Rina,
“Terpukul Corona, Sederet Proyek Energi Baru RI Molor ke 2021”,
CNBC Indonesia, 21 April 2020, https://www.cnbcindonesia.com/
news/20200421181003-4-153485/terpukul-corona-sederet-proyek-
energi-baru-ri-molor-ke-2021; “Akibat Covid-19, target tambahan
140 MW listrik panas bumi mundur ke semester I-2021”, 10 November
2020, https://industri.kontan.co.id/news/akibat-covid-19-target-
tambahan-140-mw-listrik-panas-bumi-mundur-ke-semester-i-2021.
27 Anisatul Umah, “Gas Pipa Diduga Bocor, PLTP Sorik Marapi
Dihentikan Sementara”, CNBC Indonesia, 26 January 2021, https://
www.cnbcindonesia.com/news/20210126110557-4-218729/
gas-pipa-diduga-bocor-pltp-sorik-marapi-dihentikan-sementara;
“Akibat Covid-19, target tambahan 140 MW listrik panas bumi
mundur ke semester I-2021”, op. cit. note 26.
28 Indonesian Ministry of Energy and Mineral Resources (ESDM),
“Empat Program Prioritas EBTKE di Tahun 2021”, 15 January 2021,
https://ebtke.esdm.go.id/post/2021/01/18/2768/empat.program.
prioritas.ebtke.di.tahun.2021.
29 ESDM, “Keberlangsungan Panas Bumi di Indonesia: Belajar
dari Sorik Marapi”, 10 February 2021, https://ebtke.esdm.go.id/
post/2021/02/11/2792/keberlangsungan.panas.bumi.di.indonesia.
belajar.dari.sorik.marapi; ESDM, “Hasil Investigasi Lapangan Terkait
Kejadian Diduga Paparan Gas H2s pada PLTP Sorik Marapi”, 3
February 2021, https://ebtke.esdm.go.id/post/2021/02/04/2787/
hasil.investigasi.lapangan.terkait.kejadian.diduga.paparan.gas.h2s.
pada.pltp.sorik.marapi.
30 Capacity at year-end 2015-2020 from ESDM, “Capaian Kinerja
Tahun 2020 dan Program Kerja 2021 Sektor ESDM” (Jakarta: 7
January 2021), https://www.esdm.go.id/assets/media/content/
content-capaian-kinerja-tahun-2020-dan-program-kerja-tahun-
2021-sektor-esdm .
31 ESDM, Handbook of Energy & Economic Statistics of Indonesia
(Jakarta: July 2020), https://www.esdm.go.id/id/publikasi/
handbook-of-energy-economic-statistics-of-indonesia.
32 ESDM, “Strategi Pengembangan EBT Menuju Target 23%”, 24
November 2020, https://ebtke.esdm.go.id/post/2020/11/25/2707/
strategi.pengembangan.ebt.menuju.target.23; ESDM, “Ini Strategi
Pemerintah Untuk Percepatan Pengembangan Panas Bumi”, 18
June 2020, https://ebtke.esdm.go.id/post/2020/06/18/2562/ini.
strategi.pemerintah.untuk.percepatan.pengembangan.panas.bumi.
33 ESDM, “UU Cipta Kerja dan Aturan Turunannya Dukung Kepastian
Berusaha Panas Bumi”, 26 March 2021, https://ebtke.esdm.go.id/
post/2021/03/29/2830/uu.cipta.kerja.dan.aturan.turunannya.
dukung.kepastian.berusaha.panas.bumi; F. B. Iskana, “Kementerian
ESDM Tunda Lelang Wilayah Kerja Panas Bumi Hingga 2022”,
Katadata, 6 August 2020, https://katadata.co.id/febrinaiskana/
ekonomi-hijau/5f2bd2ffaeaa7/kementerian-esdm-tunda-lelang-
wilayah-kerja-panas-bumi-hingga-2022; V. N. Setiawan, “ESDM
Targetkan Eksplorasi Panas Bumi di 3 Lokasi Rampung Tahun
ini”, Katadata, 14 January 2021, https://katadata.co.id/sortatobing/
ekonomi-hijau/60001a6196012/esdm-targetkan-eksplorasi-panas-
bumi-di-3-lokasi-rampung-tahun-ini.
34 ESDM, “Pacu Investasi Panas Bumi, Pemerintah Siapkan
Kompensasi Eksplorasi”, 30 July 2020, https://ebtke.esdm.go.id/
post/2020/07/30/2600/pacu.investasi.panas.bumi.pemerintah.
siapkan.kompensasi.eksplorasi.
35 Setiawan, op. cit. note 33; V. N. Setiawan, “Terbentur Anggaran,
Pengeboran Panas Bumi Terpangkas Jadi 2 Wilaya”, Katadata,
20 January 2021, https://katadata.co.id/sortatobing/ekonomi-
hijau/600826d609482/terbentur-anggaran-pengeboran-panas-
bumi-terpangkas-jadi-2-wilayah.
36 ESDM, “Targetkan Tambahan 16,7 Giga Watt Pembangkit EBT,
Menteri ESDM: Ini Tantangannya”, 24 September 2020, https://
ebtke.esdm.go.id/post/2020/09/26/2634/targetkan.tambahan.167.
giga.watt.pembangkit.ebt.menteri.esdm.ini.tantangannya.
37 A. D. Fronda et al., “Geothermal energy development: The
Philippines country update”, Proceedings World Geothermal
Congress 2020, https://www.geothermal-energy.org; Republic of
the Philippines, Department of Energy, 2019 Power Situation Report
(Manila: 2019), https://www.doe.gov.ph/sites/default/files/pdf/
electric_power/2019-power-situation-report .
38 M. M. Velasco, “Guidelines to push geothermal energy
investment readied”, Manila Bulletin, 1 July 2020, https://
mb.com.ph/2020/07/01/guidelines-to-push-geothermal-energy-
investment-readied; M. M. Velasco, “PH to open RE for 100%
foreign ownership”, Manila Bulletin, 12 July 2020, https://mb.com.
ph/2020/07/12/ph-to-open-re-for-100-foreign-ownership; M.
M. Velasco, “Gov’t opens full foreign ownership to integrated
geothermal projects”, Manila Bulletin, 28 October 2020, https://
mb.com.ph/2020/10/28/govt-opens-full-foreign-ownership-to-
integrated-geothermal-projects.
39 M. M. Velasco, “No foreign firm takers of PH geothermal blocks
yet”, Manila Bulletin, 22 December 2020, https://mb.com.
ph/2020/12/22/no-foreign-firm-takers-of-ph-geothermal-blocks-
yet; M. M. Velasco, “DOE eyeing 114 prospective bidders in new
hydro, geothermal projects”, Manila Bulletin, 8 January 2021,
https://mb.com.ph/2021/01/08/doe-eyeing-114-prospective-
bidders-in-new-hydro-geothermal-projects.
40 M. M. Velasco, “Geothermal investors seek ‘risk
insurance perks’ for new projects”, Manila Bulletin,
19 January 2021, https://mb.com.ph/2021/01/19/
geothermal-investors-seek-risk-insurance-perks-for-new-projects.
41 J. L. Mayuga, “Lack of incentives crimps investments in geothermal”,
Business Mirror, 2 March 2020, https://businessmirror.com.ph/2020/
03/02/lack-of-incentives-crimps-investments-in-geothermal; Velasco,
op. cit. note 40.
42 S. Daysh et al., “New Zealand country update”, Proceedings World
Geothermal Congress 2020, https://www.geothermal-energy.org.
43 New Zealand Ministry of Business Innovation and Employment,
“Electricity statistics”, https://www.mbie.govt.nz/building-and-
energy/energy-and-natural-resources/energy-statistics-and-
modelling/energy-statistics/electricity-statistics, viewed April 2021.
44 Contact Energy, “Contact says smelter closure
is ‘disappointing’”, 9 July 2020, https://contact.
co.nz/aboutus/media-centre/2020/07/08/
contact-says-smelter-closure-is-disappointing.
45 Contact Energy, “Contact confirms world-class Tauhara
geothermal resource”, 23 June 2020, https://contact.co.nz/
aboutus/media-centre/2020/06/23/contact-confirms-world-
class-tauhara-geothermal-resource; Contact Energy, “Contact
to build Tauhara geothermal power station; will raise $400m in
equity”, 15 February 2021, https://contact.co.nz/aboutus/media-
centre/2021/02/16/contact-to-build-tauhara-geothermal-power-
station-will-raise-$400m-in-equity.
46 Contact Energy, “Contact confirms world-class Tauhara
geothermal resource”, op. cit. note 45.
47 Ormat, “Top Energy new geothermal power plant”, 27
January 2021, https://www.ormat.com/en/company/news/
view/?ContentID=8835.
48 Calculation based on Lund and Toth, op. cit. note 1. Growth of 2.4
GW in 2020 based on five-year compound annual growth rate of
7.8% from 2014 through 2019 (total capacity having grown from
20,627 MW in 2014 to 30,080 MW in 2019).
49 Calculation based on Lund and Toth, op. cit. note 1. Growth of 11.3
TWh in 2020 based on five-year compound annual growth rate
of 9.6% from 2014 through 2019 (total output having grown from
265,790 TJ in 2014 to 420,906 TJ in 2019).
50 Calculation based on Lund and Toth, op. cit. note 1.
51 Ibid.
52 Ibid.
53 Figure 22 based on ibid.
54 Ibid.
55 T. Tian et al., “Rapid development of China’s geothermal industry –
China National Report of the 2020 World Geothermal Conference”,
Proceedings World Geothermal Congress 2020, https://www.
geothermal-energy.org.
56 Ibid.
57 Ibid.
58 Calculation based on Lund and Toth, op. cit. note 1.
59 O. Mertoglu et al., “Geothermal energy use: Projections and country
update for Turkey”, Proceedings World Geothermal Congress 2020,
forthcoming, https://www.geothermal-energy.org.
60 A. Ragnarsson et al., “Geothermal development in Iceland 2015-
2019”, Proceedings World Geothermal Congress 2020, forthcoming,
https://www.geothermal-energy.org.
61 K. Yasukawa et al., “Country update of Japan”, Proceedings World
Geothermal Congress 2020, forthcoming, https://www.geothermal-
energy.org.
62 Ibid.
289
http://www.ogindonesia.com/2020/03/tiga-pltp-akan-beroperasi-tahun-2020.html
https://www.cnbcindonesia.com/news/20200421181003-4-153485/terpukul-corona-sederet-proyek-energi-baru-ri-molor-ke-2021
https://www.cnbcindonesia.com/news/20200421181003-4-153485/terpukul-corona-sederet-proyek-energi-baru-ri-molor-ke-2021
https://www.cnbcindonesia.com/news/20200421181003-4-153485/terpukul-corona-sederet-proyek-energi-baru-ri-molor-ke-2021
https://industri.kontan.co.id/news/akibat-covid-19-target-tambahan-140-mw-listrik-panas-bumi-mundur-ke-semester-i-2021
https://industri.kontan.co.id/news/akibat-covid-19-target-tambahan-140-mw-listrik-panas-bumi-mundur-ke-semester-i-2021
https://www.cnbcindonesia.com/news/20210126110557-4-218729/gas-pipa-diduga-bocor-pltp-sorik-marapi-dihentikan-sementara
https://www.cnbcindonesia.com/news/20210126110557-4-218729/gas-pipa-diduga-bocor-pltp-sorik-marapi-dihentikan-sementara
https://www.cnbcindonesia.com/news/20210126110557-4-218729/gas-pipa-diduga-bocor-pltp-sorik-marapi-dihentikan-sementara
https://ebtke.esdm.go.id/post/2021/01/18/2768/empat.program.prioritas.ebtke.di.tahun.2021
https://ebtke.esdm.go.id/post/2021/01/18/2768/empat.program.prioritas.ebtke.di.tahun.2021
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https://ebtke.esdm.go.id/post/2021/02/11/2792/keberlangsungan.panas.bumi.di.indonesia.belajar.dari.sorik.marapi
https://ebtke.esdm.go.id/post/2021/02/04/2787/hasil.investigasi.lapangan.terkait.kejadian.diduga.paparan.gas.h2s.pada.pltp.sorik.marapi
https://ebtke.esdm.go.id/post/2021/02/04/2787/hasil.investigasi.lapangan.terkait.kejadian.diduga.paparan.gas.h2s.pada.pltp.sorik.marapi
https://ebtke.esdm.go.id/post/2021/02/04/2787/hasil.investigasi.lapangan.terkait.kejadian.diduga.paparan.gas.h2s.pada.pltp.sorik.marapi
https://www.esdm.go.id/assets/media/content/content-capaian-kinerja-tahun-2020-dan-program-kerja-tahun-2021-sektor-esdm
https://www.esdm.go.id/assets/media/content/content-capaian-kinerja-tahun-2020-dan-program-kerja-tahun-2021-sektor-esdm
https://www.esdm.go.id/assets/media/content/content-capaian-kinerja-tahun-2020-dan-program-kerja-tahun-2021-sektor-esdm
https://www.esdm.go.id/id/publikasi/handbook-of-energy-economic-statistics-of-indonesia
https://www.esdm.go.id/id/publikasi/handbook-of-energy-economic-statistics-of-indonesia
https://ebtke.esdm.go.id/post/2020/11/25/2707/strategi.pengembangan.ebt.menuju.target.23
https://ebtke.esdm.go.id/post/2020/11/25/2707/strategi.pengembangan.ebt.menuju.target.23
https://ebtke.esdm.go.id/post/2020/06/18/2562/ini.strategi.pemerintah.untuk.percepatan.pengembangan.panas.bumi
https://ebtke.esdm.go.id/post/2020/06/18/2562/ini.strategi.pemerintah.untuk.percepatan.pengembangan.panas.bumi
https://ebtke.esdm.go.id/post/2021/03/29/2830/uu.cipta.kerja.dan.aturan.turunannya.dukung.kepastian.berusaha.panas.bumi
https://ebtke.esdm.go.id/post/2021/03/29/2830/uu.cipta.kerja.dan.aturan.turunannya.dukung.kepastian.berusaha.panas.bumi
https://ebtke.esdm.go.id/post/2021/03/29/2830/uu.cipta.kerja.dan.aturan.turunannya.dukung.kepastian.berusaha.panas.bumi
https://katadata.co.id/febrinaiskana/ekonomi-hijau/5f2bd2ffaeaa7/kementerian-esdm-tunda-lelang-wilayah-kerja-panas-bumi-hingga-2022
https://katadata.co.id/febrinaiskana/ekonomi-hijau/5f2bd2ffaeaa7/kementerian-esdm-tunda-lelang-wilayah-kerja-panas-bumi-hingga-2022
https://katadata.co.id/febrinaiskana/ekonomi-hijau/5f2bd2ffaeaa7/kementerian-esdm-tunda-lelang-wilayah-kerja-panas-bumi-hingga-2022
https://katadata.co.id/sortatobing/ekonomi-hijau/60001a6196012/esdm-targetkan-eksplorasi-panas-bumi-di-3-lokasi-rampung-tahun-ini
https://katadata.co.id/sortatobing/ekonomi-hijau/60001a6196012/esdm-targetkan-eksplorasi-panas-bumi-di-3-lokasi-rampung-tahun-ini
https://katadata.co.id/sortatobing/ekonomi-hijau/60001a6196012/esdm-targetkan-eksplorasi-panas-bumi-di-3-lokasi-rampung-tahun-ini
https://ebtke.esdm.go.id/post/2020/07/30/2600/pacu.investasi.panas.bumi.pemerintah.siapkan.kompensasi.eksplorasi
https://ebtke.esdm.go.id/post/2020/07/30/2600/pacu.investasi.panas.bumi.pemerintah.siapkan.kompensasi.eksplorasi
https://ebtke.esdm.go.id/post/2020/07/30/2600/pacu.investasi.panas.bumi.pemerintah.siapkan.kompensasi.eksplorasi
https://katadata.co.id/sortatobing/ekonomi-hijau/600826d609482/terbentur-anggaran-pengeboran-panas-bumi-terpangkas-jadi-2-wilayah
https://katadata.co.id/sortatobing/ekonomi-hijau/600826d609482/terbentur-anggaran-pengeboran-panas-bumi-terpangkas-jadi-2-wilayah
https://katadata.co.id/sortatobing/ekonomi-hijau/600826d609482/terbentur-anggaran-pengeboran-panas-bumi-terpangkas-jadi-2-wilayah
https://ebtke.esdm.go.id/post/2020/09/26/2634/targetkan.tambahan.167.giga.watt.pembangkit.ebt.menteri.esdm.ini.tantangannya
https://ebtke.esdm.go.id/post/2020/09/26/2634/targetkan.tambahan.167.giga.watt.pembangkit.ebt.menteri.esdm.ini.tantangannya
https://ebtke.esdm.go.id/post/2020/09/26/2634/targetkan.tambahan.167.giga.watt.pembangkit.ebt.menteri.esdm.ini.tantangannya
https://www.geothermal-energy.org
https://www.doe.gov.ph/sites/default/files/pdf/electric_power/2019-power-situation-report
https://www.doe.gov.ph/sites/default/files/pdf/electric_power/2019-power-situation-report
https://mb.com.ph/2020/07/01/guidelines-to-push-geothermal-energy-investment-readied
https://mb.com.ph/2020/07/01/guidelines-to-push-geothermal-energy-investment-readied
https://mb.com.ph/2020/07/01/guidelines-to-push-geothermal-energy-investment-readied
https://mb.com.ph/2020/07/12/ph-to-open-re-for-100-foreign-ownership
https://mb.com.ph/2020/07/12/ph-to-open-re-for-100-foreign-ownership
https://mb.com.ph/2020/10/28/govt-opens-full-foreign-ownership-to-integrated-geothermal-projects
https://mb.com.ph/2020/10/28/govt-opens-full-foreign-ownership-to-integrated-geothermal-projects
https://mb.com.ph/2020/10/28/govt-opens-full-foreign-ownership-to-integrated-geothermal-projects
https://mb.com.ph/2020/12/22/no-foreign-firm-takers-of-ph-geothermal-blocks-yet
https://mb.com.ph/2020/12/22/no-foreign-firm-takers-of-ph-geothermal-blocks-yet
https://mb.com.ph/2020/12/22/no-foreign-firm-takers-of-ph-geothermal-blocks-yet
https://mb.com.ph/2021/01/08/doe-eyeing-114-prospective-bidders-in-new-hydro-geothermal-projects
https://mb.com.ph/2021/01/08/doe-eyeing-114-prospective-bidders-in-new-hydro-geothermal-projects
https://mb.com.ph/2021/01/19/geothermal-investors-seek-risk-insurance-perks-for-new-projects
https://mb.com.ph/2021/01/19/geothermal-investors-seek-risk-insurance-perks-for-new-projects
https://businessmirror.com.ph/2020/03/02/lack-of-incentives-crimps-investments-in-geothermal
https://businessmirror.com.ph/2020/03/02/lack-of-incentives-crimps-investments-in-geothermal
https://www.geothermal-energy.org
https://www.mbie.govt.nz/building-and-energy/energy-and-natural-resources/energy-statistics-and-modelling/energy-statistics/electricity-statistics
https://www.mbie.govt.nz/building-and-energy/energy-and-natural-resources/energy-statistics-and-modelling/energy-statistics/electricity-statistics
https://www.mbie.govt.nz/building-and-energy/energy-and-natural-resources/energy-statistics-and-modelling/energy-statistics/electricity-statistics
https://contact.co.nz/aboutus/media-centre/2020/07/08/contact-says-smelter-closure-is-disappointing
https://contact.co.nz/aboutus/media-centre/2020/07/08/contact-says-smelter-closure-is-disappointing
https://contact.co.nz/aboutus/media-centre/2020/07/08/contact-says-smelter-closure-is-disappointing
https://contact.co.nz/aboutus/media-centre/2020/06/23/contact-confirms-world-class-tauhara-geothermal-resource
https://contact.co.nz/aboutus/media-centre/2020/06/23/contact-confirms-world-class-tauhara-geothermal-resource
https://contact.co.nz/aboutus/media-centre/2020/06/23/contact-confirms-world-class-tauhara-geothermal-resource
https://contact.co.nz/aboutus/media-centre/2021/02/16/contact-to-build-tauhara-geothermal-power-station-will-raise-$400m-in-equity
https://contact.co.nz/aboutus/media-centre/2021/02/16/contact-to-build-tauhara-geothermal-power-station-will-raise-$400m-in-equity
https://contact.co.nz/aboutus/media-centre/2021/02/16/contact-to-build-tauhara-geothermal-power-station-will-raise-$400m-in-equity
https://www.ormat.com/en/company/news/view/?ContentID=8835
https://www.ormat.com/en/company/news/view/?ContentID=8835
https://www.geothermal-energy.org
https://www.geothermal-energy.org
https://www.geothermal-energy.org
https://www.geothermal-energy.org
https://www.geothermal-energy.org
https://www.geothermal-energy.org
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · GEOTHERMAL POWER AND HE AT
63 L. Schauer, “Geothermie in München: Sendlings Bohrinsel”,
Abendzeitung, 10 May 2019, https://www.abendzeitung-
muenchen.de/muenchen/geothermie-in-muenchen-
sendlings-bohrinsel-art-469592; Erdwerk, “Projekt
München-Schäftlarnstraße: Bohrplatz geräumt”, 27 May
2020, https://www.erdwerk.com/de/projekt-muenchen-
schaeftlarnstrasse-bohrplatz-geraeumt; “München baut
Deutschlands größtes Geothermie-Kraftwerk”, Sonnenseite,
18 February 2019, https://www.sonnenseite.com/de/energie/
muenchen-baut-deutschlands-groesstes-geothermie-kraftwerk.
64 Informationsportal Tiefe Geothermie, “München baut auf
geothermische Fernkälte statt stromfressenden Klimaanlagen”,
17 April 2020, https://www.tiefegeothermie.de/news/muenchen-
baut-auf-geothermische-fernkaelte-statt-stromfressenden-
klimaanlagen.
65 “Schöne Schwimmbad-Liegewiese soll für neues Kraftwerk der
Stadtwerke München weichen”, Merkur tz Redaktions, 4 January
2020, https://www.tz.de/muenchen/stadt/ramersdorf-perlach-
ort43348/muenchen-michaelibad-stadtwerke-geothermie-
kraftwerk-liegewiese-zr-13419040.html.
66 The project used advanced drilling technology to complete the
1,600 metre multilateral well, which exceeded expectations,
producing 400 cubic metres of water per hour at 65°C and
thermal output in excess of 16 MWth. ENGIE, “Géothermie à
Vélizy-Villacoublay: une première européenne avec 66% d’EnR !”
25 February 2021, https://www.engie-solutions.com/fr/actualites/
geothermie-velizy-66-enr; Schlumberger, “Schlumberger drilling
technology used to enable geothermal heating solution in Europe”,
press release (Paris: 8 March 2021), https://www.slb.com/
resource-library/article/2021/schlumberger-drilling-technology-
used-to-enable-geothermal-heating–solution-in-europe.
67 ENGIE, “Construction du réseau de chaleur géothermique à Noisiel
& Champs-sur-Marne”, 20 July 2020, https://www.engie-solutions.
com/fr/actualites/geothermie-noisiel-champs-marne.
68 Gényo, “Mise en service du réseau de chaleur Gényo: les villes de
Bobigny et Drancy chauffées à la géothermie”, press release (Paris:
9 March 2021), https://genyo.fr/wp-content/uploads/2021/03/
CP-GENYO-09.03.2021-VF ; Gényo, “Les travaux de forage”,
8 December 2020, https://genyo.fr/travaux-de-forage.
69 Gényo, “Mise en service du réseau de chaleur Gényo”, op. cit. note 68.
70 V. Bapt, “Chronique d’une aventure industrielle mise en
suspens”, Dernière Nouvelles D’Alsace, 4 December
2020, https://www.dna.fr/environnement/2020/12/04/
chronique-d-une-aventure-industrielle-mise-en-suspens;
A. Beckelynck, “Les ‘écarts importants’ de Fonroche à
Vendenheim”, Dernière Nouvelles D’Alsace, 30 December
2020, https://www.dna.fr/economie/2020/12/30/
les-ecarts-importants-de-fonroche-a-vendenheim.
71 A. Beckelynck, “Après les séismes, les autres projets de géothermie
suspendus autour de Strasbourg”, Dernière Nouvelles D’Alsace,
9 December 2020, https://www.dna.fr/economie/2020/12/09/
la-prefecture-suspend-les-autres-projets-de-geothermie; Bapt, op.
cit. note 70.
72 Beckelynck, op. cit.note 70.
73 De Rechtspraak, “Central Insolventieregister”, 27 October
2020, https://insolventies.rechtspraak.nl/#!/details/03.
lim.20.233.F.1300.1.20.
74 J. van Winsen, “Aardwarmteproject CLG vraagt faillissement aan”,
20 October 2020, Nieuwe Oogst, https://www.nieuweoogst.nl/
nieuws/2020/10/20/aardwarmteproject-clg-vraagt-faillissement-
aan; Californië B.V., “Negatieve reactie SodM op verzoek CLG
Geothermie BV om weer te mogen opstarten”, 10 July 2019,
https://www.californie.nu/nieuws/negatieve-reactie-sodm-op-
verzoek-clg-geothermie-bv-om-weer-te-mogen-opstarten/109;
Californië B.V., “CLG Geothermie BV vraagt Faillissement aan”,
15 October 2020, https://www.californie.nu/nieuws/archief/
clg-geothermie-bv-vraagt-faillissement-aan/110.
75 Californië B.V., “CLG Geothermie BV vraagt Faillissement aan”, op.
cit. note 74.
76 Geothermie Nederland, “Toepassing aardwarmte groeit met
10 procent”, https://geothermie.nl/index.php/nl/actueel/
nieuws/884-toepassing-aardwarmte-groeit-met-10-procent,
viewed March 2021; 2019 growth from Dutch Association of
Geothermal Operators, “Forse stijging gebruik aardwarmte
in de glastuinbouw”, 16 March 2020, https://www.dago.nu/
forse-stijging-gebruik-aardwarmte-in-de-glastuinbouw.
77 Geothermie Nederland, op. cit. note 76; G. Bakema et al.,
“Netherland country update”, Proceedings World Geothermal
Congress 2020, https://www.geothermal-energy.org; Dutch
Association of Geothermal Operators, op. cit. note 76.
78 See, for example, Well Engineering Partners, “Geothermal projects”,
https://wellengineeringpartners.com/projects/geothermal-projects,
viewed March 2021.
79 Platform Geothermie and DAGO, “Position Paper Mijnbouwwet”,
https://geothermie.nl/images/bestanden/DAGOSPG_
reactie_gewijzigde_mijnbouwwet , viewed March 2021;
Geothermie Nederland, “Voorstel wijziging Mijnbouwwet
gepubliceerd”, 21 July 2020, https://allesoveraardwarmte.nl/
voorstel-wijziging-mijnbouwwet-gepubliceerd.
80 Beckelynck, op. cit. note 71; Bapt, op. cit. note 70; M. Antoine,
“Séismes près de Strasbourg: la géothermie inquiète”,
Le Parisien, 13 November 2020, https://www.leparisien.fr/
environnement/seismes-pres-de-strasbourg-la-geothermie-
inquiete-13-11-2020-8408166.php.
81 J. Haffner, EPFL, “Reducing human-induced earthquake
risk”, 6 January 2020, https://actu.epfl.ch/news/
reducing-human-induced-earthquake-risk.
82 Geo-Energie Suisse, “Durchbruch für die Tiefengeothermie”,
press release (Zurich: 21 January 2021), https://www.geo-energie.
ch/2021/01/21/durchbruch-f%C3%BCr-die-tiefengeothermie.
83 Ibid.
84 Ibid.; Geo-Energie Suisse, “Geo-Energie Suisse hält am Geothermie-
projekt in Haute-Sorne (JU) fest”, press release (Zurich: 25 May
2020), https://www.geo-energie.ch/2020/05/25/geo-energie-
suisse-h%C3%A4lt-am-geothermieprojekt-in-haute-sorne-ju-fest.
85 Bundesverband Geothermie, “Neue Initiative ‘Wärmewende
durch Geothermie’”, press release (Berlin: 15 July 2020), https://
www.geothermie.de/fileadmin/user_upload/Aktuelles/Presse/
Pressemitteilungen/Pressemitteilungen_2020/PM_Kampagne_
Waermewende_durch_Geothermie ; Informationsportal Tiefe
Geothermie, “Initiative ‘Wärmewende durch Geothermie’ geht in
die Offensive”, 15 July 2020, https://www.tiefegeothermie.de/news/
initiative-waermewende-durch-geothermie-geht-die-offensive.
86 Geothermie Nederland, “Drie acties essentieel voor geothermie,
warmtetransitie en Klimaatakkoord”, https://geothermie.nl/images/
bestanden/210224_GNL_brief_verkiezingen , viewed March 2021.
87 Unione Geothermica Italiana, “Lettera aperta dell’Unione
Geotermica Italianaal Ministro Cingolani”, press release
(Pisa: 9 March 2021), http://www.unionegeotermica.it/
public/Comunicato%20stampa_Unione%20Geotermica%20
Italiana_9Marzo2021 ; Unione Geothermica Italiana, “L’appello
dell’Unione Geotermica Italianaal Governo Draghi”, press release
(Pisa: 18 February 2021), http://www.unionegeotermica.it/
public/Comunicato%20stampa_Unione%20Geotermica%20
Italiana_18%20Febbraio2021 .
88 See, for example, S. Akin, Y. Orucu and T. Fridriksson,
“Characterizing the declining CO2 emissions from Turkish
geothermal power plant”, Proceedings of the 45th Workshop on
Geothermal Reservoir Engineering, Stanford University, Palo Alto,
CA, 10-12 February 2020, https://pangea.stanford.edu/ERE/db/
GeoConf/papers/SGW/2020/Akin .
89 Carbfix, “Our story”, https://www.carbfix.com/our-story, viewed
March 2021.
90 Carbfix, “Carbfix and Climeworks commission the first large-scale
permanent removal of carbon dioxide from the atmosphere”, 25
August 2020, https://www.carbfix.com/carbfix-and-climeworks-
commission-the-first-large-scale-permanent-removal-of-carbon-
dioxide-from-the-atmosphere; A. Doyle, “Scared by global
warming? In Iceland, one solution is petrifying”, 4 February 2021,
https://news.trust.org/item/20210204081743-h6hoq.
91 Eavor Technologies, “Eavor announces a commercial Eavor-
Loop project to be built in Geretsried, Germany”, press release
(Calgary/Munich: 1 May 2020), https://eavor.com/press-release/
eavor-announces-commercial-eavor-loop-project-be-built-
geretsried-germany; Informationsportal Tiefe Geothermie,
“Bohrplatzerweiterung in Geretsried”, 16 December 2020, https://
www.tiefegeothermie.de/news/bohrplatzerweiterung-geretsried.
92 The first phase would include four loops providing 8.6 MW
of power capacity and 65 MWth for the local district heat
demand, with the anticipation of later adding another 48 loops.
Eavor Technologies, op. cit. note 91; Informationsportal Tiefe
290
https://www.abendzeitung-muenchen.de/muenchen/geothermie-in-muenchen-sendlings-bohrinsel-art-469592
https://www.abendzeitung-muenchen.de/muenchen/geothermie-in-muenchen-sendlings-bohrinsel-art-469592
https://www.abendzeitung-muenchen.de/muenchen/geothermie-in-muenchen-sendlings-bohrinsel-art-469592
https://www.erdwerk.com/de/projekt-muenchen-schaeftlarnstrasse-bohrplatz-geraeumt
https://www.erdwerk.com/de/projekt-muenchen-schaeftlarnstrasse-bohrplatz-geraeumt
https://www.tiefegeothermie.de/news/muenchen-baut-auf-geothermische-fernkaelte-statt-stromfressenden-klimaanlagen
https://www.tiefegeothermie.de/news/muenchen-baut-auf-geothermische-fernkaelte-statt-stromfressenden-klimaanlagen
https://www.tiefegeothermie.de/news/muenchen-baut-auf-geothermische-fernkaelte-statt-stromfressenden-klimaanlagen
https://www.tz.de/muenchen/stadt/ramersdorf-perlach-ort43348/muenchen-michaelibad-stadtwerke-geothermie-kraftwerk-liegewiese-zr-13419040.html
https://www.tz.de/muenchen/stadt/ramersdorf-perlach-ort43348/muenchen-michaelibad-stadtwerke-geothermie-kraftwerk-liegewiese-zr-13419040.html
https://www.tz.de/muenchen/stadt/ramersdorf-perlach-ort43348/muenchen-michaelibad-stadtwerke-geothermie-kraftwerk-liegewiese-zr-13419040.html
https://www.engie-solutions.com/fr/actualites/geothermie-velizy-66-enr
https://www.engie-solutions.com/fr/actualites/geothermie-velizy-66-enr
https://www.slb.com/resource-library/article/2021/schlumberger-drilling-technology-used-to-enable-geothermal-heating–solution-in-europe
https://www.slb.com/resource-library/article/2021/schlumberger-drilling-technology-used-to-enable-geothermal-heating–solution-in-europe
https://www.slb.com/resource-library/article/2021/schlumberger-drilling-technology-used-to-enable-geothermal-heating–solution-in-europe
https://www.engie-solutions.com/fr/actualites/geothermie-noisiel-champs-marne
https://www.engie-solutions.com/fr/actualites/geothermie-noisiel-champs-marne
https://genyo.fr/wp-content/uploads/2021/03/CP-GENYO-09.03.2021-VF
https://genyo.fr/wp-content/uploads/2021/03/CP-GENYO-09.03.2021-VF
https://genyo.fr/travaux-de-forage
https://www.dna.fr/environnement/2020/12/04/chronique-d-une-aventure-industrielle-mise-en-suspens
https://www.dna.fr/environnement/2020/12/04/chronique-d-une-aventure-industrielle-mise-en-suspens
https://www.dna.fr/economie/2020/12/30/les-ecarts-importants-de-fonroche-a-vendenheim
https://www.dna.fr/economie/2020/12/30/les-ecarts-importants-de-fonroche-a-vendenheim
https://www.dna.fr/economie/2020/12/09/la-prefecture-suspend-les-autres-projets-de-geothermie
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https://insolventies.rechtspraak.nl/#!/details/03.lim.20.233.F.1300.1.20
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https://www.nieuweoogst.nl/nieuws/2020/10/20/aardwarmteproject-clg-vraagt-faillissement-aan
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https://www.californie.nu/nieuws/negatieve-reactie-sodm-op-verzoek-clg-geothermie-bv-om-weer-te-mogen-opstarten/109
https://www.californie.nu/nieuws/negatieve-reactie-sodm-op-verzoek-clg-geothermie-bv-om-weer-te-mogen-opstarten/109
https://www.californie.nu/nieuws/archief/clg-geothermie-bv-vraagt-faillissement-aan/110
https://www.californie.nu/nieuws/archief/clg-geothermie-bv-vraagt-faillissement-aan/110
https://geothermie.nl/index.php/nl/actueel/nieuws/884-toepassing-aardwarmte-groeit-met-10-procent
https://geothermie.nl/index.php/nl/actueel/nieuws/884-toepassing-aardwarmte-groeit-met-10-procent
https://www.dago.nu/forse-stijging-gebruik-aardwarmte-in-de-glastuinbouw
https://www.dago.nu/forse-stijging-gebruik-aardwarmte-in-de-glastuinbouw
https://www.geothermal-energy.org
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https://geothermie.nl/images/bestanden/DAGOSPG_reactie_gewijzigde_mijnbouwwet
https://geothermie.nl/images/bestanden/DAGOSPG_reactie_gewijzigde_mijnbouwwet
https://www.leparisien.fr/environnement/seismes-pres-de-strasbourg-la-geothermie-inquiete-13-11-2020-8408166.php
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https://actu.epfl.ch/news/reducing-human-induced-earthquake-risk
https://actu.epfl.ch/news/reducing-human-induced-earthquake-risk
https://www.geo-energie.ch/2021/01/21/durchbruch-f%C3%BCr-die-tiefengeothermie
https://www.geo-energie.ch/2021/01/21/durchbruch-f%C3%BCr-die-tiefengeothermie
https://www.geo-energie.ch/2020/05/25/geo-energie-suisse-h%C3%A4lt-am-geothermieprojekt-in-haute-sorne-ju-fest
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https://www.tiefegeothermie.de/news/initiative-waermewende-durch-geothermie-geht-die-offensive
https://www.tiefegeothermie.de/news/initiative-waermewende-durch-geothermie-geht-die-offensive
https://geothermie.nl/images/bestanden/210224_GNL_brief_verkiezingen
https://geothermie.nl/images/bestanden/210224_GNL_brief_verkiezingen
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_9Marzo2021
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_9Marzo2021
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_9Marzo2021
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_18%20Febbraio2021
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_18%20Febbraio2021
http://www.unionegeotermica.it/public/Comunicato%20stampa_Unione%20Geotermica%20Italiana_18%20Febbraio2021
https://pangea.stanford.edu/ERE/db/GeoConf/papers/SGW/2020/Akin
https://pangea.stanford.edu/ERE/db/GeoConf/papers/SGW/2020/Akin
https://www.carbfix.com/our-story
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https://www.carbfix.com/carbfix-and-climeworks-commission-the-first-large-scale-permanent-removal-of-carbon-dioxide-from-the-atmosphere
https://www.carbfix.com/carbfix-and-climeworks-commission-the-first-large-scale-permanent-removal-of-carbon-dioxide-from-the-atmosphere
https://news.trust.org/item/20210204081743-h6hoq
https://eavor.com/press-release/eavor-announces-commercial-eavor-loop-project-be-built-geretsried-germany
https://eavor.com/press-release/eavor-announces-commercial-eavor-loop-project-be-built-geretsried-germany
https://eavor.com/press-release/eavor-announces-commercial-eavor-loop-project-be-built-geretsried-germany
https://www.tiefegeothermie.de/news/bohrplatzerweiterung-geretsried
https://www.tiefegeothermie.de/news/bohrplatzerweiterung-geretsried
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · GEOTHERMAL POWER AND HE AT
Geothermie, “Eavor Loop-Projekt in Geretsried im Focus on
Geothermal”, 21 July 2020, https://www.tiefegeothermie.de/news/
eavor-loop-projekt-geretsried-im-focus-geothermal.
93 Eavor Technologies Inc., “The world’s first truly scalable form
of green baseload power demonstrated by Eavor Technologies
Inc.”, 5 February 2020, https://eavor.com/press/#press16; Natural
Resources Canada, “Eavor-Loop demonstration project”, https://
www.nrcan.gc.ca/science-and-data/funding-partnerships/funding-
opportunities/current-investments/eavor-loop-demonstration-
project/21896, viewed March 2021; Eavor Technologies Inc.,
“Technology”, https://eavor.com/technology, viewed March 2021.
94 Eavor Technologies, “Global energy majors lead pivot to Eavor’s
geothermal solution with USD$40 million investment”, 16 February
2021, https://eavor.com/press-release/global-energy-majors-lead-
pivot-eavors-geothermal-solution-usd40-million-investment.
95 Chevron, “Chevron invests in geothermal development company”,
press release (Houston: 28 February 2021), https://www.chevron.
com/stories/chevron-invests-in-geothermal-development-
company; Baseload Capital, “Projects”, https://www.baseloadcap.
com/projects, viewed March 2021; Climeon, “How it works”, https://
climeon.com/how-it-works, viewed March 2021.
96 “Top 20 geothermal power companies 2019”, PR Newswire, 4 June
2019, https://markets.businessinsider.com/news/stocks/top-20-
geothermal-power-companies-2019-1028250552; Exergy, “Exergy
restarts with Tica to boost integrated systems and advanced green
power generation”, press release (Olgiate Olona, Italy: 14 January
2020), https://www.exergy-orc.com/media/news/exergy-restarts-
with-tica-to-boost-integrated-systems-and-advanced-green-
power-generation.
97 T. Garabetian, European Geothermal Energy Council (EGEC),
“EGEC geothermal market report 2018”, presentation, 7
February 2019, https://www.egec.org/wp-content/uploads/
media_publication/2-EGEC_Presentation-market-2018-TGA.
pdf; P. Dumas, EGEC, “Geothermal energy in Europe – overview,
market, business model”, presentation at Norwegian Center for
Geothermal Energy Research, 4 February 2019, http://cger.no/
doc//pdf/presentations%20GeoEnergi2019/4%20februar/05-
EGEC_Presentation%20market%202018-Philippe%20Dumas .
98 See sources on projects completed in Turkey and the United States.
291
https://www.tiefegeothermie.de/news/eavor-loop-projekt-geretsried-im-focus-geothermal
https://www.tiefegeothermie.de/news/eavor-loop-projekt-geretsried-im-focus-geothermal
https://eavor.com/press/#press16
https://www.nrcan.gc.ca/science-and-data/funding-partnerships/funding-opportunities/current-investments/eavor-loop-demonstration-project/21896
https://www.nrcan.gc.ca/science-and-data/funding-partnerships/funding-opportunities/current-investments/eavor-loop-demonstration-project/21896
https://www.nrcan.gc.ca/science-and-data/funding-partnerships/funding-opportunities/current-investments/eavor-loop-demonstration-project/21896
https://www.nrcan.gc.ca/science-and-data/funding-partnerships/funding-opportunities/current-investments/eavor-loop-demonstration-project/21896
https://eavor.com/press-release/global-energy-majors-lead-pivot-eavors-geothermal-solution-usd40-million-investment
https://eavor.com/press-release/global-energy-majors-lead-pivot-eavors-geothermal-solution-usd40-million-investment
https://www.chevron.com/stories/chevron-invests-in-geothermal-development-company
https://www.chevron.com/stories/chevron-invests-in-geothermal-development-company
https://www.chevron.com/stories/chevron-invests-in-geothermal-development-company
https://www.baseloadcap.com/projects
https://www.baseloadcap.com/projects
https://climeon.com/how-it-works
https://climeon.com/how-it-works
https://markets.businessinsider.com/news/stocks/top-20-geothermal-power-companies-2019-1028250552
https://markets.businessinsider.com/news/stocks/top-20-geothermal-power-companies-2019-1028250552
https://www.exergy-orc.com/media/news/exergy-restarts-with-tica-to-boost-integrated-systems-and-advanced-green-power-generation
https://www.exergy-orc.com/media/news/exergy-restarts-with-tica-to-boost-integrated-systems-and-advanced-green-power-generation
https://www.exergy-orc.com/media/news/exergy-restarts-with-tica-to-boost-integrated-systems-and-advanced-green-power-generation
https://www.egec.org/wp-content/uploads/media_publication/2-EGEC_Presentation-market-2018-TGA
https://www.egec.org/wp-content/uploads/media_publication/2-EGEC_Presentation-market-2018-TGA
https://www.egec.org/wp-content/uploads/media_publication/2-EGEC_Presentation-market-2018-TGA
http://cger.no/doc//pdf/presentations%20GeoEnergi2019/4%20februar/05-EGEC_Presentation%20market%202018-Philippe%20Dumas
http://cger.no/doc//pdf/presentations%20GeoEnergi2019/4%20februar/05-EGEC_Presentation%20market%202018-Philippe%20Dumas
http://cger.no/doc//pdf/presentations%20GeoEnergi2019/4%20februar/05-EGEC_Presentation%20market%202018-Philippe%20Dumas
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · HYDROPOWER
HYDROPOWER
1 International Energy Agency (IEA), Hydropower Tracking
Report (Paris: June 2020), https://www.iea.org/reports/
hydropower#tracking-progress.
2 “Hydropower and the impact of COVID-19“, International
Water Power & Dam Construction, 18 May 2020,
https://www.waterpowermagazine.com/features/
featurehydropower-and-the-impact-of-covid-19-7929537.
3 Global capacity based on International Hydropower Association
(IHA), Hydropower Status Report 2021 (London: 2021), https://www.
hydropower.org/publications/2021-hydropower-status-report and
IHA, personal communication with REN21, 25 May 2021. At the
end of 2020, total installed capacity was 1,308 GW, less 158 GW of
pumped storage.
4 Country data from IHA, op. cit. note 3, and from the following
sources: China: total capacity including pumped storage of
370.16 GW, capacity additions of 13.23 GW, utilisation and
investment, from China National Energy Administration (NEA),
2020 energy statistics, 20 January 2021, http://www.nea.gov.
cn/2021-01/20/c_139683739.htm, and from China Electricity
Council (CEC), 2020 electricity and other energy statistics,
31 December 2020, https://english.cec.org.cn/detail/index.
html?3-1090; generation of 1,360 TWh and annual growth of
4.1%, from National Bureau of Statistics of China, “Analysis and
forecast of China power demand-supply situation 2020-2021”,
press release (Beijing: 8 February 2021), https://english.cec.org.
cn/detail/index.html?3-1128. Total capacity including pumped
storage of 356.4 GW, pumped storage capacity of 30.3 GW and
hydropower capacity of 326.1 GW; capacity additions (excluding
pumped storage) of 3.9 GW; and pumped storage additions of
0.3 GW from IHA, op. cit. note 3. Brazil: 177.77 MW (0 MW large
hydropower, 176.77 MW small hydropower and 1 MW very small
hydro) added in 2020, from National Agency for Electrical Energy
(ANEEL), “Acompanhamento da expansão da oferta de geração
de energia elétrica – base de dados do RALIE (Fevereiro de
2021)”, http://www.aneel.gov.br/acompanhamento-da-expansao-
da-oferta-de-geracao-de-energia-eletrica, updated February
2021; year-end capacity of 108 GW from Government of Brazil,
ANEEL, “Aneel ultrapassa meta de expansão da geração de
energia em 2020”, 6 January 2021, https://www.gov.br/pt-br/
noticias/energia-minerais-e-combustiveis/2021/01/aneel-
ultrapassa-meta-de-expansao-da-geracao-de-energia-em-2020;
generation of 509 TWh from National Electrical System Operator
of Brazil (ONS), “Geração de energia”, http://www.ons.org.
br/Paginas/resultados-da-operacao/historico-da-operacao/
geracao_energia.aspx, viewed 26 February 2021. United
States: capacity from US Energy Information Administration
(EIA), Electric Power Monthly with Data for December 2020
(Washington, DC: February 2021), Tables 6.2.B and 6.3, http://
www.eia.gov/electricity/monthly; generation from idem, Table
1.1, viewed 26 February 2021. Canada: capacity and generation
from IHA, op. cit. note 3. Russian Federation: capacity and
generation from System Operator of the Unified Energy System
of Russia, Report on the Unified Energy System in 2020 (Moscow:
31 January 2021), p. 9, https://so-ups.ru/fileadmin/files/company/
reports/disclosure/2021/ups_rep2020 . India: installed
capacity in 2020 (units larger than 25 MW) of 42,492 MW and
installed small (<25 MW) hydropower capacity of 4,750 MW,
from Government of India, Ministry of Power, Central Electricity
Authority (CEA), “Installed capacity reports”, December 2020,
http://www.cea.nic.in/monthlyarchive.html, and 3,306 MW of
pumped storage from CEA, “Hydroelectric reports”, http://www.
cea.nic.in/monthlyarchive.html, viewed 31 January 2021. Norway:
generation from Statistics Norway, “Elektrisitet”, https://www.
ssb.no/statbank/list/elektrisitet, viewed 31 January 2021; capacity
from Norwegian Water Resources and Energy Directorate (NVE),
“Ny kraftproduksjon“, https://www.nve.no/energiforsyning/
kraftmarkedsdata-og-analyser/ny-kraftproduksjon, viewed 31
January 2020; additions of 256 MW, and year-end capacity of
33 GW and average annual production of 136.6 TWh (excluding
pumped storage), from NVE, “Vannkraft“, https://www.nve.no/
energiforsyning/kraftproduksjon/vannkraft, viewed 18 March
2021. Figure H1 based on capacity and generation sources
provided in this note.
5 Capacity values by country from sources provided in endnote
4 and from IHA, op. cit. note 3. Turkey: net installed capacity
in 2020 of 2,465 MW for impoundments of 2,266 MW and
run-of-river plants of 199 MW, from Energy Market Regulatory
Authority of Turkey (EPDK), Electricity Market Sector Report 2020
(Ankara: January to December 2020), https://www.epdk.gov.tr/
Detay/Icerik/3-0-23/aylik-sektor-raporu (using Google Translate).
Angola: net installed capacity in 2020 of 3,773 MW, from
calculations based on recorded additions and on IHA, “Country
profile – Angola”, https://www.hydropower.org/discover/
hydropower-around-the-world, viewed 14 May 2021. Figure H2
based on capacity and generation sources provided in this note
and in note 4.
6 See, for example, J. Deign, “Hydropower jostles for role in
global green recovery programs”, Greentech Media, 9 February
2021, https://www.greentechmedia.com/articles/read/
hydro-jostles-for-role-in-global-green-recovery-programs.
7 IHA, op. cit. note 3, and sources on individual pumped storage
projects noted elsewhere in this section.
8 Estimated global hydropower generation and increase from IHA,
op. cit. note 3; share of estimated global generation from Ember,
Global Electricity Review 2021 (London: 2021), https://ember-
climate.org/project/global-electricity-review-2021. Also see
Global Overview chapter.
9 Renewable Energy Policy Network for the 21st Century (REN21),
Renewables Global Status Report (Paris: various years), https://
www.ren21.net/reports/global-status-report; installed capacity
in 2019 of 358.04 MW, including 30.29 MW of pumped storage,
from CEC, “Generation”, https://english.cec.org.cn/menu/index.
html?263, viewed 18 March 2021, and from NEA, op. cit. note 4.
10 Based on total hydropower electricity generation in 2015 of
1,126 TWh and hydropower capacity of 296 GW, from REN21,
Renewables 2016 Global Status Report (Paris: 2016), https://www.
ren21.net/gsr-2016; total hydropower electricity generation in
2020 of 1,360 TWh and hydropower capacity of 341 GW, from
CEC, op. cit. note 4; CEC, “2020 electricity consumption data
of China released”, 20 January 2021,https://english.cec.org.cn/
detail/index.html?3-1109.
11 State-owned Assets Supervision and Administration Commission
of the State Council (SASAC), “Datengxia hydropower project on
left bank of Qianjiang River in full operation”, 7 August 2020, http://
en.sasac.gov.cn/2020/08/07/c_5341.htm; Voith, “Voith supports
China to develop hydropower – First Wu Dongde hydropower plant
units now in operation”, press release (Shanghai: 10 July 2020),
https://voith.com/corp-en/news-room/press-releases/2020-07-
10-vh-voith-supports-china-to-develop-hydropower.html.
12 GE, “GE Renewable Energy connects the world’s most powerful
hydro unit to the grid in Wudongde, China”, press release
(Paris: 6 July 2020), https://www.ge.com/news/press-releases/
ge-renewable-energy-connects-worlds-most-powerful-hydro-
unit-grid-wudongde-china.
13 Harbin Electric Group (HPEC), “Unit 4 of the Fengman
Reconstruction Project developed by the Electric Motor Company
was put into production with high quality”, 30 April 2020, http://
www.hpec.com/newsinfoview.asp?id=9389; “Construction of all
underground facilities at Baihetan dam complete”, International
Water Power & Dam Construction, 14 October 2020, https://
www.waterpowermagazine.com/news/newsconstruction-of-all-
underground-facilities-at-baihetan-dam-complete-8180917; Xinhua,
“Spillway tunnels for Chinese mega hydropower project completed”,
China Daily, 20 December 2020, https://www.chinadaily.com.
cn/a/202012/20/WS5fde918ca31024ad0ba9cd6a.html.
14 CEC, op. cit. note 4; SASAC, “Three Gorges Dam sets world
record on annual power output”, 20 November 2020, http://
en.sasac.gov.cn/2020/11/20/c_6065.htm.
15 EPDK, op. cit. note 5; REN21, op. cit. note 9.
16 B. Muftuoglu, “Turkish renewable additions at new high”, Argus
Media, 12 August 2020, https://www.argusmedia.com/en/
news/2131686-turkish-renewable-additions-at-new-high.
17 N. Gökmen, “Turkey: New renewable energy support
mechanism announced”, Mondaq, 2 February 2021,
https://www.mondaq.com/turkey/renewables/1031996/
new-renewable-energy-support-mechanism-announced.
18 “Opening ceremony held for Yusufeli dam in Turkey”, International
Water Power & Dam Construction, 8 June 2020, https://www.
waterpowermagazine.com/news/newsopening-ceremony-held-
for-yusufeli-dam-in-turkey-7961289; “500-MW Lower Kaleköy
Hydropower plant in Turkey now operating”, Hydro Review, 4
February 2021, https://www.hydroreview.com/hydro-industry-
news/500-mw-lower-kalekoy-hydropower-plant-in-turkey-now-
292
https://www.iea.org/reports/hydropower#tracking-progress
https://www.iea.org/reports/hydropower#tracking-progress
https://www.waterpowermagazine.com/features/featurehydropower-and-the-impact-of-covid-19-7929537
https://www.waterpowermagazine.com/features/featurehydropower-and-the-impact-of-covid-19-7929537
https://www.hydropower.org/publications/2021-hydropower-status-report
https://www.hydropower.org/publications/2021-hydropower-status-report
http://www.nea.gov.cn/2021-01/20/c_139683739.htm
http://www.nea.gov.cn/2021-01/20/c_139683739.htm
https://english.cec.org.cn/detail/index.html?3-1090
https://english.cec.org.cn/detail/index.html?3-1090
https://english.cec.org.cn/detail/index.html?3-1128
https://english.cec.org.cn/detail/index.html?3-1128
http://www.aneel.gov.br/acompanhamento-da-expansao-da-oferta-de-geracao-de-energia-eletrica
http://www.aneel.gov.br/acompanhamento-da-expansao-da-oferta-de-geracao-de-energia-eletrica
https://www.gov.br/pt-br/noticias/energia-minerais-e-combustiveis/2021/01/aneel-ultrapassa-meta-de-expansao-da-geracao-de-energia-em-2020
https://www.gov.br/pt-br/noticias/energia-minerais-e-combustiveis/2021/01/aneel-ultrapassa-meta-de-expansao-da-geracao-de-energia-em-2020
https://www.gov.br/pt-br/noticias/energia-minerais-e-combustiveis/2021/01/aneel-ultrapassa-meta-de-expansao-da-geracao-de-energia-em-2020
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.eia.gov/electricity/monthly
http://www.eia.gov/electricity/monthly
https://so-ups.ru/fileadmin/files/company/reports/disclosure/2021/ups_rep2020
https://so-ups.ru/fileadmin/files/company/reports/disclosure/2021/ups_rep2020
http://www.cea.nic.in/monthlyarchive.html
http://www.cea.nic.in/monthlyarchive.html
http://www.cea.nic.in/monthlyarchive.html
https://www.ssb.no/statbank/list/elektrisitet
https://www.ssb.no/statbank/list/elektrisitet
https://www.nve.no/energiforsyning/kraftmarkedsdata-og-analyser/ny-kraftproduksjon
https://www.nve.no/energiforsyning/kraftmarkedsdata-og-analyser/ny-kraftproduksjon
https://www.nve.no/energiforsyning/kraftproduksjon/vannkraft
https://www.nve.no/energiforsyning/kraftproduksjon/vannkraft
https://www.epdk.gov.tr/Detay/Icerik/3-0-23/aylik-sektor-raporu
https://www.epdk.gov.tr/Detay/Icerik/3-0-23/aylik-sektor-raporu
https://www.hydropower.org/discover/hydropower-around-the-world
https://www.hydropower.org/discover/hydropower-around-the-world
https://www.greentechmedia.com/articles/read/hydro-jostles-for-role-in-global-green-recovery-programs
https://www.greentechmedia.com/articles/read/hydro-jostles-for-role-in-global-green-recovery-programs
https://ember-climate.org/project/global-electricity-review-2021
https://ember-climate.org/project/global-electricity-review-2021
https://www.ren21.net/reports/global-status-report
https://www.ren21.net/reports/global-status-report
https://english.cec.org.cn/menu/index.html?263
https://english.cec.org.cn/menu/index.html?263
https://www.ren21.net/gsr-2016
https://www.ren21.net/gsr-2016
https://english.cec.org.cn/detail/index.html?3-1109
https://english.cec.org.cn/detail/index.html?3-1109
http://en.sasac.gov.cn/2020/08/07/c_5341.htm
http://en.sasac.gov.cn/2020/08/07/c_5341.htm
https://voith.com/corp-en/news-room/press-releases/2020-07-10-vh-voith-supports-china-to-develop-hydropower.html
https://voith.com/corp-en/news-room/press-releases/2020-07-10-vh-voith-supports-china-to-develop-hydropower.html
https://www.ge.com/news/press-releases/ge-renewable-energy-connects-worlds-most-powerful-hydro-unit-grid-wudongde-china
https://www.ge.com/news/press-releases/ge-renewable-energy-connects-worlds-most-powerful-hydro-unit-grid-wudongde-china
https://www.ge.com/news/press-releases/ge-renewable-energy-connects-worlds-most-powerful-hydro-unit-grid-wudongde-china
http://www.hpec.com/newsinfoview.asp?id=9389
http://www.hpec.com/newsinfoview.asp?id=9389
https://www.waterpowermagazine.com/news/newsconstruction-of-all-underground-facilities-at-baihetan-dam-complete-8180917
https://www.waterpowermagazine.com/news/newsconstruction-of-all-underground-facilities-at-baihetan-dam-complete-8180917
https://www.waterpowermagazine.com/news/newsconstruction-of-all-underground-facilities-at-baihetan-dam-complete-8180917
https://www.chinadaily.com.cn/a/202012/20/WS5fde918ca31024ad0ba9cd6a.html
https://www.chinadaily.com.cn/a/202012/20/WS5fde918ca31024ad0ba9cd6a.html
http://en.sasac.gov.cn/2020/11/20/c_6065.htm
http://en.sasac.gov.cn/2020/11/20/c_6065.htm
https://www.argusmedia.com/en/news/2131686-turkish-renewable-additions-at-new-high
https://www.argusmedia.com/en/news/2131686-turkish-renewable-additions-at-new-high
https://www.mondaq.com/turkey/renewables/1031996/new-renewable-energy-support-mechanism-announced
https://www.mondaq.com/turkey/renewables/1031996/new-renewable-energy-support-mechanism-announced
https://www.waterpowermagazine.com/news/newsopening-ceremony-held-for-yusufeli-dam-in-turkey-7961289
https://www.waterpowermagazine.com/news/newsopening-ceremony-held-for-yusufeli-dam-in-turkey-7961289
https://www.waterpowermagazine.com/news/newsopening-ceremony-held-for-yusufeli-dam-in-turkey-7961289
https://www.hydroreview.com/hydro-industry-news/500-mw-lower-kalekoy-hydropower-plant-in-turkey-now-operating
https://www.hydroreview.com/hydro-industry-news/500-mw-lower-kalekoy-hydropower-plant-in-turkey-now-operating
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · HYDROPOWER
operating; “Limak to start last turbine at new 420 MW Çetin
hydropower plant in Turkey”, Balkan Green Energy News, 2 June
2020, https://balkangreenenergynews.com/limak-to-start-last-
turbine-at-new-420-mw-cetin-hydropower-plant-in-turkey;
“Turkey’s Ilisu Dam on Tigris starts generating at full capacity”,
Reuters, 24 December 2020, https://www.reuters.com/article/
turkey-dam-int-idUSKBN28Y0WK.
19 “Threat of drought rises as dams dry up in many regions
of Turkey”, Daily Sabah, 30 November 2020, https://www.
dailysabah.com/turkey/threat-of-drought-rises-as-dams-
dry-up-in-many-regions-of-turkey/news; “Hydro plants’
electricity generation down 12 pct“, Hürriyet Daily News,
6 January 2021, https://www.hurriyetdailynews.com/
hydro-plants-electricity-generation-down-12-pct-161412.
20 Total installed capacity of 95,890 MW by end-2020; total
hydropower (dam and run-of-river) installed capacity of 30,984
MW; and global new additions of 4,434 MW and hydropower (dam
and run-of-river) additions of 2,465 MW, from EPDK, op. cit. note 5.
21 Total added capacity of 1,658 MW excludes pumped storage
capacity. Net capacity additions of 1,579 MW for hydropower
plants above 25 MW, from Government of India, Ministry of
Power, CEA, “State-wise/Station-wise installed capacity of
H.E. stations in the country”, December 2020, https://cea.nic.
in/wp-content/uploads/hpi/2021/01/hydro_stations-12 ;
implied addition of 79 MW for small hydropower (<25 MW)
from Government of India, Ministry of New and Renewable
Energy, “Physical progress”, January 2021, https://mnre.gov.in/
the-ministry/physical-progress, viewed February 2021, and from
idem, “Physical progress”, January 2020, https://mnre.gov.in/
physical-progress-achievements, viewed January 2020; total
installed capacity of 47,243 MW (excluding 3,305 MW of pumped
storage), from CEA, “All India installed capacity (in MW) of
power stations”, December 2020, https://cea.nic.in/wp-content/
uploads/installed/2020/12/installed_capacity .
22 “India to have 70,000 MW of hydropower capacity by 2030:
Official”, Economic Times, 21 May 2020, https://energy.
economictimes.indiatimes.com/news/power/india-to-have-
70000-mw-of-hydropower-capacity-by-2030-official/75859241.
23 Ibid.
24 “2000MW hydropower project to be commissioned in Subansiri,
India”, Construction Review, 14 December 2020, https://
constructionreviewonline.com/news/2000mw-hydropower-
project-to-be-commissioned-in-subansiri-india.
25 IEA, India 2020 Energy Policy Review (Paris: 2020), p. 111,
https://www.iea.org/reports/india-2020; Press Information
Bureau, Government of India, “India prepares for a change in
electricity sector through proposed Electricity (Amendment) Bill
2020”, press release (Delhi: 25 June 2020), https://pib.gov.in/
PressReleasePage.aspx?PRID=1634253; “Renewable energy in
India’s economic development: An analysis of reforms”, Economic
Times, 20 November 2020, https://energy.economictimes.
indiatimes.com/news/renewable/renewable-energy-in-indias-
economic-development-an-analysis-of-reforms/79325236.
26 Ibid., all references.
27 IHA, “Country profile – Laos”, https://www.hydropower.org/
country-profiles/laos, viewed 19 May 2021.
28 “Commercial operation confirmed for 260-MW Don Sahong
Hydropower in Laos”, Hydro Review, 9 November 2020, https://
www.hydroreview.com/hydro-industry-news/commercial-
operation-confirmed-for-260-mw-don-sahong-hydropower-in-
laos; “Laos: The first unit of Selalong Hydropower Station is about
to generate electricity”, World Energy, 31 July 2020, https://www.
world-energy.org/article/11144.html.
29 Vietnam Electricity, National Load Dispatch Center (EVN NLDC),
Summary Report for Operation Activities of National Power System
in 2020 (Hanoi: 2021); Tran Phuong Dong, Vnuhcm-University
of Science, Vietnam, personal communication with REN21,
25 March 2021.
30 “Électricité: EVN envisage d’accomplir 256 projets en 2021”,
VietnamPlus, 12 January 2021, https://fr.vietnamplus.vn/electricite-
evn-envisage-daccomplir-256-projets-en-2021/154272.vnp.
31 Ministry of Energy of the Republic of Uzbekistan, “The volume of
investments in the hydropower sector of Uzbekistan is growing”,
25 August 2020, http://minenergy.uz/ru/news/view/726; Ministry
of Energy of the Republic of Uzbekistan, “Ministry of Energy: How
the growing energy supply in Uzbekistan is ensured”, 15 January
2021, http://minenergy.uz/ru/news/view/1063; “Uzbekistan
completes modernisation of Kadyrinskaya hydropower”,
Hydro Review, 4 August 2020, https://www.hydroreview.com/
hydro-industry-news/uzbekistan-completes-modernization-of-
kadyrinskaya-hydropower; “Uzbekistan launches hydroelectric
power plant”, UZ Daily, 23 July 2020, https://www.uzdaily.uz/en/
post/58682; “New hydropower capacities launched”, UZ Daily, 24
March 2020, https://www.uzdaily.uz/en/post/55591.
32 “Commercial operations begin at 178-MW Shuakhevi hydro
in Georgia”, Hydro Review, 30 March 2020, https://www.
hydroreview.com/hydro-industry-news/commercial-operations-
begin-at-178-mw-shuakhevi-hydro-in-georgia.
33 IHA, “Country profile – Albania”, https://www.hydropower.org/
discover/hydropower-around-the-world, viewed 18 March 2021;
M. Arabidze, Ministry of Economy and Sustainable Development
of Georgia, “Renewable energy in Georgia: Challenges and
opportunities”, presentation at 10th International Forum on
Energy for Sustainable Development, 7 October 2019, https://
unece.org/fileadmin/DAM/energy/se/pp/gere/GERE.6_
Oct.2019/2_RE_Auctions/2_M.Arabidze_Georgia.6th.GERE.
pdf; National Statistics Office of Georgia, “Statistical information
– energy”, https://www.geostat.ge/ka/modules/categories/81/
energetika, available from January to November 2020, viewed
February 2021.
34 NVE, op. cit. note 4.
35 Ibid.
36 Electricité de France, “EDF commissions its new Romanche-
Gavet hydroelectric plant (Isère)”, press release (Paris: 9 October
2020), https://www.edf.fr/en/the-edf-group/dedicated-sections/
journalists/all-press-releases/edf-commissions-its-new-
romanche-gavet-hydroelectric-plant-isere; Culture Isère, “Les
centrales hydroélectriques de la vallée de la Romanche”, https://
culture.isere.fr/page/les-centrales-hydroelectriques-de-la-vallee-
de-la-romanche, viewed 12 May 2021.
37 Electricité de France, op. cit. note 36.
38 D. Proctor, “Albania seeks investment to support existing
hydropower”, POWER, 2 March 2020, https://www.powermag.
com/albania-seeks-investment-to-support-existing-hydropower;
Statkraft, “Moglicë hydropower plant”, https://www.statkraft.
com/about-statkraft/where-we-operate/albania/moglice-
hydropower-plant, viewed February 2021.
39 Total installed capacity in 2020 (including 1.4 GW of pumped
storage) of 49,912 MW, from System Operator of the Unified
Energy System of Russia, op. cit. note 4; IHA, “Pumped Storage
Tracking Tool”, https://www.hydropower.org/hydropower-
pumped-storage-tool, viewed 11 February 2021; total installed
capacity in 2019 (including 1.4 GW of pumped storage) of 49,870
MW, from System Operator of the Unified Energy System of
Russia, Report on the Unified Energy System in 2019 (Moscow:
31 January 2020), p. 7, http://www.so-ups.ru/fileadmin/files/
company/reports/disclosure/2020/ups_rep2019 .
40 RusHydro, “RusHydro inaugurates Zaramagskaya HPP-1 in North
Ossetia”, press release (Moscow: 4 February 2020), http://www.
eng.rushydro.ru/press/news/110490.html.
41 “Barsuchkovskaya hydro plant commissioned in Russia”,
International Water Power & Dam Construction, 4 January
2021, https://www.waterpowermagazine.com/news/
newsbarsuchkovskaya-hydro-plant-commissioned-in-
russia-8435786; “Ust-Dzhegutinskaya small hydropower
plant commissioned in Russia”, International Water Power
& Dam Construction, 11 November 2020, https://www.
waterpowermagazine.com/news/newsust-dzhegutinskaya-
small-hydropower-plant-commissioned-in-russia-8357592;
RusHydro, “RusHydro inaugurates Verkhnebalkarskaya
small-scale hydropower plant”, press release (Moscow: 25 June
2020), http://www.eng.rushydro.ru/press/news/111491.html;
“LUKOIL commissions renovated 1.5-MW Beshenka River small
hydropower plant”, Hydro Review, 8 October 2020, https://www.
hydroreview.com/hydro-industry-news/lukoil-commissions-
renovated-1-5-mw-beshenka-river-small-hydropower-plant.
42 Nornickel, “Stage 6 launched at Ust-Khantayskaya HPP”,
press release (Moscow: 21 September 2020), https://www.
nornickel.com/news-and-media/press-releases-and-news/
stage-6-launched-at-ust-khantayskaya-hpp.
43 Ministry of Energy and Water (MINEA), Angola Energy 2025
– Angola Power Sector Long Term Vision (Luanda: June 2016),
293
https://www.hydroreview.com/hydro-industry-news/500-mw-lower-kalekoy-hydropower-plant-in-turkey-now-operating
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https://www.nornickel.com/news-and-media/press-releases-and-news/stage-6-launched-at-ust-khantayskaya-hpp
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · HYDROPOWER
https://gestoenergy.com/wp-content/uploads/2018/04/
ANGOLA-POWER-SECTOR-LONG-TERM-VISION .
44 MINEA, “Titular do Sector da Energia e Águas constata
funcionamento do Sector na Província da Huíla”, press reléase
(Lubango: 5 November 2020), https://www.minea.gv.ao/index.
php/component/content/article/19-destaque/251-nota-de-
imprensa-titular-do-sector-da-energia-e-aguas-constata-
funcionamento-do-sector-na-provincia-da-huila; “Barragem
do Luachimo pode concluir obras em 2021”, Angola Press
News Agency, 17 August 2020, https://www.angop.ao/noticias-
o/?v_link=https://www.angop.ao/angola/pt_pt/noticias/
economia/2020/7/34/Barragem-Luachimo-pode-concluir-obras-
2021,bb297f84-2ca6-47bc-bd10-5b82ffbe4771.html; MINEA,
“Terceiro Conselho Directivo do MINEA Aprecia avanços na
implementação das Acções do Projecto Baynes”, press release
(Luanda: 2 October 2020),https://www.minea.gv.ao/index.php/
component/content/article/19-destaque/243-nota-de-imprensa-
terceiro-conselho-directivo-do-minea-aprecia-avancos-na-
implementacao-das-accoes-do-projecto-baynes?Itemid=490;
“Construção da barragem de Baynes inicia em 2021”, Angola
Press News Agency, 3 March 2020, https://www.angop.ao/
noticias-o/?v_link=https://www.angop.ao/angola/pt_pt/
noticias/economia/2020/2/10/Construcao-barragem-Baynes-
inicia-2021,b4f9f59b-4378-42dd-b756-412f71d994f0.html;
“Caculo Cabaça conclui túnel de acesso”, Jornal de Angola,
30 November 2020, https://jornaldeangola.ao/ao/noticias/
caculo-cabaca-conclui-tunel-de-acesso.
45 MINEA, “Entrada em serviço comercial da última turbina de ah
Laúca“, 9 December 2020, https://www.minea.gv.ao/index.php/
component/content/article/19-destaque/259-nota-informativa-
comissionamento-do-6-grupo-do-ahe-de-lauca?Itemid=490.
46 IHA, “Country profile – Angola”, op. cit. note 5.
47 “Phalombe HPP ready February”, BNLTimes, 7 January
2021, https://times.mw/phalombe-hydropower-plant-
ready-february; “Gilke gives update on African projects”,
International Water Power & Dam Construction, 8 December
2020, https://www.waterpowermagazine.com/news/
newsgilkes-gives-update-on-african-projects-8398614;
Gilkes, “Ruo-Ndiza hydro commissioned in Malawi by
Gilkes”, 12 June 2020, https://www.gilkes.com/news-media/
ruo-ndiza-hydro-commissioned-in-malawi.
48 Rwanda Energy Group, “Giciye III hydropower plant to add 9.8 MW to
the national grid”, Newsletter, October-December 2020, p. 8, https://
www.reg.rw/fileadmin/user_upload/NEWSLETTER_No8 .
49 Ibid.
50 “Vidullanka achieves second major leap in Africa with 6.5MW
Bukinda small hydropower project”, Daily Financial Times,
4 August 2020, http://www.ft.lk/business/Vidullanka-achieves-
second-major-leap-in-Africa-with-6-5MW-Bukinda-small-
hydropower-project/34-704051; “Spotlight: Uganda to accelerate
use of renewable energy in bid to reduce carbon footprint”,
Xinhua News Agency, 14 December 2020, http://www.xinhuanet.
com/english/2020-12/14/c_139589047.htm; “Uganda’s Karuma
hydropower plant nearing completion”, Xinhua News Agency,
14 November 2020, http://www.xinhuanet.com/english/2020-
11/14/c_139514517_2.htm.
51 I. Magoum, “Uganda: UEGCL renovates 3 power lines to operate
the Karuma dam”, Afrika21, 27 November 2020, https://www.
afrik21.africa/en/uganda-uegcl-renovates-3-power-lines-to-
operate-the-karuma-dam.
52 Ethiopian Electric Power, “The work on the Great Ethiopian
Renaissance has reached 73 percent”, 21 May 2020, https://www.
eep.com.et/en/the-work-on-the-great-ethiopian-renaissance-
has-reached-73-percent; “Ethiopia’s mega dam to generate
electricity”, New Business Ethiopia, 13 October 2020, https://
newbusinessethiopia.com/energy/ethiopias-mega-dam-to-
generate-electricity; “Three-way talks on Ethiopian dam reach
new impasse”, Reuters, 11 January 2021, https://www.reuters.com/
article/us-ethiopia-dam-sudan-egypt-idUSKBN29G0JT.
53 “Ethiopia, Egypt, Sudan make slow progress in Nile dam row”,
DW, 16 January 2020, https://www.dw.com/en/ethiopia-egypt-
sudan-make-slow-progress-in-nile-dam-row/a-52015611.
54 “Construction of Koysha hydropower dam in Ethiopia
39% complete”, Construction Review, 13 October 2020,
https://constructionreviewonline.com/news/ethiopia/
construction-of-koysha-hydropower-dam-in-ethiopia-39-
complete; SASAC, “CGGC-contracted hydropower plant
in Ethiopia starts operation”, 18 February 2020, http://
en.sasac.gov.cn/2020/02/18/c_3733.htm; A. Larson,
“Award-winning hydropower project helps electrify Ethiopia“,
POWER, 1 September 2020, https://www.powermag.com/
award-winning-hydropower-project-helps-electrify-ethiopia.
55 IHA, “Country profile – Ethiopia”, https://www.hydropower.org/
country-profiles/ethiopia, viewed 18 March 2021.
56 “Nigeria: New hydropower plant adds 60MW to national grid”,
Energy Central, 15 December 2020, https://energycentral.com/
news/nigeria-new-hydropower-plant-adds-60mw-national-grid.
57 Agence Française de Développement (AFD), “Ghana: A dam
for a greener future”, 2 December 2020, https://www.afd.fr/
en/actualites/grand-angle/ghana-dam-renewable-future; IHA,
“Country profile – Ghana”, https://www.hydropower.org/discover/
hydropower-around-the-world, updated May 2019.
58 Bui Power Authority, “President Akufo-Addo commissions
Ghana’s first micro hydroelectric plant”, 24 November 2020,
https://buipower.com/president-akufo-addo-commissions-
ghanas-first-micro-hydroelectric-plant.
59 J. M. Takouleu, “Ghana: la construction du barrage polyvalent
de Pwalugu débutera en avril 2020”, Afrik21, 3 March 2020,
https://www.afrik21.africa/ghana-la-construction-du-barrage-
polyvalent-de-pwalugu-debutera-en-avril-2020; G. Johnson,
“Ghana: les travaux de construction du barrage polyvalent de
Pwalugu démarrent finalement fin avril”, Agence Ecofin, 5 March
2020, https://www.agenceecofin.com/production/0503-74533-
ghana-les-travaux-de-construction-du-barrage-polyvalent-de-
pwalugu-demarrent-finalement-fin-avril.
60 IHA, op. cit. note 3.
61 Manitoba Hydro, “Who we are”, https://www.manitobahydropower.
com/who-we-are, viewed February 2021; N. Frew, “Another Keeyask
blockade formed despite injunction on the first”, CBC News, 19
May 2020, https://www.cbc.ca/news/canada/manitoba/manitoba-
hydro-tataskweyak-injunction-blockade-1.5575317; “Manitoba
Hydro announces temporary reduction of workforce at Keeyask”,
31 October 2020, https://www.hydro.mb.ca/articles/2020/10/
manitoba_hydro_announces_temporary_reduction_of_workforce_
at_keeyask. See also Government of Canada, “First Nations in
Canada”, https://www.rcaanc-cirnac.gc.ca/eng/1307460755710/153
6862806124, viewed 23 February 2021.
62 Muskrat Falls Project, Monthly Report – December 2020 (St.
John’s, Newfoundland and Labrador: February 2021), https://
muskratfalls.nalcorenergy.com/newsroom/reports.
63 IHA, “Country profile – Canada”, https://www.hydropower.org/
country-profiles/canada, viewed March 2021.
64 EIA, op. cit. note 4; Grant PUD, “Wanapum Dam turbine
and generator replacement“, https://www.grantpud.org/
wanapum-dam-turbine-and-generator-replacement, viewed
19 February 2021; J. Miller, “Lake Livingston hydroelectric plant
powers 12,000 households”, Texas Coop Power, February
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65 EIA, op. cit. note 4, Table 6.3 and Table 6.4.
66 Ibid., Table 6.2.B
67 Ibid., Table 1.1.A; EIA, “Electricity Data Browser, net generation”,
https://www.eia.gov/electricity/data/browser, viewed 21 April 2021.
68 SASAC, “POWERCHINA-contracted hydropower project in
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Interconectado”, http://enee.hn/index.php/centrales-
hidroelectricas/80-canaveral/L, viewed February 2021.
69 Celsia, “Celsia encendió nueva central hidroeléctrica San Andrés
de Cuerquia en Colombia”, 24 September 2020, https://www.
celsia.com/es/centrales-hidroelectricas; Asociación Colombiana
de Generadores de Energía Eléctrica (ACOLGEN), “Mapa de
generación eléctrica en Colombia”, https://www.acolgen.org.co/
mapa-generacion, viewed February 2021.
70 D. A. Mercado, “Cuenta regresiva en Hidroituango para sus dos
primeras turbinas”, El Tiempo, 16 November 2021, https://www.
eltiempo.com/colombia/medellin/hidroituango-comienza-la-
instalacion-de-dos-turbinas-549238; J. I. García, “Creciente del rio
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2018, https://www.eltiempo.com/colombia/medellin/creciente-del-
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https://www.eltiempo.com/colombia/medellin/creciente-del-rio-cauca-dejo-afectactaciones-en-localidades-cercanas-216994
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · HYDROPOWER
71 ANEEL, op. cit. note 4; REN21, op. cit. note 9.
72 L. Costa, “Brasil fecha 2020 com menor expansão em hidrelétricas
e recorde em geração fóssil”, 4 January 2021, https://www.reuters.
com/article/energia-eletrica-geracao-idBRKBN299276-OBRBS.
73 ANEEL, “Aneel ultrapassa meta de expansão da geração de
energia em 2020”, 6 January 2021, https://www.gov.br/pt-br/
noticias/energia-minerais-e-combustiveis/2021/01/aneel-
ultrapassa-meta-de-expansao-da-geracao-de-energia-em-2020.
74 Inter-American Development Bank, Impacto de las Paradas en la
Generación Hidroeléctrica de Brasil (Washington, DC: February
2019), https://publications.iadb.org/es/impacto-de-las-paradas-
en-la-generacion-hidroelectrica-de-brasil.
75 Ibid.
76 Ibid.
77 Comité de Operación Económica del Sistema Interconectado
Nacional (COES SINAC), “Ingreso Operacional de la Central H Manta”,
https://www.coes.org.pe/Portal/Planificacion/NuevosProyectos/
OperacionComercial, viewed 1 February 2021; “Cuatro centrales de
energía renovable entraron en operación el 2020”, Andina, 4 January
2021, https://andina.pe/agencia/noticia-cuatro-centrales-energia-
renovable-entraron-operacion-2020-828586.aspx.
78 “Commercial startup of 84-MW La Virgen hydro in Peru delayed
to 2021”, Hydro Review, 13 April 2020, https://www.hydroreview.
com/hydro-industry-news/commercial-startup-of-84-mw-la-
virgen-hydro-in-peru-delayed-to-2021; Government of Peru,
Supervisory Agency for Investment in Energy and Mining
(OSINERGMIN), “Centrales de generación en construcción”,
July 2020, https://www.osinergmin.gob.pe/seccion/centro_
documental/electricidad/Documentos/PROYECTOS%20GFE/
Generaci%C3%B3n/3-EN-CONSTRUCCION-MINEM .
79 REN21, Renewables 2020 Global Status Report (Paris: 2020),
https://www.ren21.net/gsr-2020; Comisión Nacional de Energía,
“Capacidad instalada de generación”, https://www.cne.cl/
estadisticas/electricidad, viewed February 2020.
80 IHA, op. cit. note 3.
81 “Israel’s 300-MW Mount Gilboa pumped storage begins operating”,
Hydro Review, 7 May 2020, https://www.hydroreview.com/hydro-
industry-news/israels-300-mw-mount-gilboa-pumped-storage-
begins-operating; “Jixi Pumped Storage Power Station”, NS Energy,
https://www.nsenergybusiness.com/projects/jixi-pumped-storage-
power-station, viewed 18 May 2020.
82 I. Todorović, “Greece asks EU to approve state aid for 680 MW
pumped storage project”, Balkan Green Energy News, 7 July
2020, https://balkangreenenergynews.com/greece-asks-eu-
to-approve-state-aid-for-680-mw-pumped-storage-project;
“SSE Renewables receives government consent for Coire Glas
pumped storage scheme”, Renewable Energy World, 23 October
2020, https://www.renewableenergyworld.com/baseload/
sse-renewables-receives-government-consent-for-coire-glas-
pumped-storage-scheme; SASAC, “CGGC to build Turkey’s first
pumped-storage power project”, 1 April 2020, http://en.sasac.
gov.cn/2020/04/01/c_4401.htm; G. Çağatay, “Turkey, China,
US to build pumped-storage hydro plant”, Andalou Agency, 4
September 2020, https://www.aa.com.tr/en/energy/finance/
turkey-china-us-to-build-pumped-storage-hydro-plant/28929.
83 “Integrated pumped-storage schemes for India”,
International Journal on Hydropower and Dams, 14
May 2020, https://www.hydropower-dams.com/news/
integrated-pumped-storage-schemes-for-india.
84 IHA, “Country profiles – Australia”, https://www.hydropower.org/
country-profiles/australia, viewed 13 February 2021; Australian
Government, “Pumped hydro”, https://www.energy.gov.au/
government-priorities/energy-supply/pumped-hydro-and-
snowy-20, viewed 18 March 2021..
85 Snow Hydro, “Snowy 2.0 about and progress”, https://www.
snowyhydro.com.au/snowy-20, viewed 13 February 2021.
86 Hydro Tasmania, “Lake Cethana selected as first pumped hydro
project”, press release (Hobart: 15 December 2020), https://www.
hydro.com.au/news/media-releases/2020/12/15/lake-cethana-
selected-as-first-pumped-hydro-project; Hydro Tasmania, “Lake
Cethana pumped hydro potential” (Hobart: September 2019),
https://www.hydro.com.au/docs/default-source/clean-energy/
battery-of-the-nation/botn---cethana-pumped-hydro-fact-sheet-
september-2019 .
87 GE, “GE Renewable Energy signs agreement with Walcha Energy
to accelerate 500MW pumped hydro storage project in Australia”,
press release (Paris: 4 August 2020), https://www.ge.com/news/
press-releases/ge-renewable-energy-signs-agreement-walcha-
energy-accelerate-500mw-pumped-hydro; “GE Renewable
Energy signs agreement with BE Power to accelerate 400 MW
pumped hydro storage project in Australia”, press release (Paris:
15 December 2020), https://www.ge.com/news/press-releases/
ge-renewable-energy-signs-agreement-with-be-power-to-
accelerate-400-mw-pumped-hydro.
88 Iberdrola, Flagship Projects, “Tâmega: One of the largest
hydroelectric projects developed in Europe in the last 25 years”,
https://www.iberdrola.com/about-us/lines-business/flagship-
projects/tamega-project, viewed February 2021; Vietnam
Electricity (EVN), “Ceremony of implementing construction
and launching emulation for completing discharge gate work
cluster of Bac Ai Pumped-Storage Hydropower Project”, press
release (Hanoi: 6 January 2020), https://en.evn.com.vn/d6/
news/Ceremony-of-implementing-construction-and-launching-
emulation-for-completing-discharge-gate-work-cluster-of-Bac-
Ai-Pumped-Storage-Hydropower-Project-66-142-1744.aspx.
89 K. Illankoon, “DEWA’s Al Tayer reviews construction progress at
the hydroelectric power station in Hatta”, Construction Business
News, 23 July 2020, https://www.cbnme.com/news/dewas-
al-tayer-reviews-construction-progress-at-the-hydroelectric-
power-station-in-hatta; A. Bagchi, “Work on schedule at
Hatta pumped hydro storage project“, ME Construction News,
7 January 2021, https://meconstructionnews.com/45520/
work-on-schedule-at-hatta-pumped-hydro-storage-project.
90 NEA, “The world’s largest total installed capacity of pumped
storage power plants for water storage”, 13 November 2020,
http://www.nea.gov.cn/2020-11/13/c_139555787.htm; Drax,
“Pumping power: Pumped storage stations around the world”,
30 December 2020, https://www.drax.com/technology/
pumping-power-pumped-storage-stations-around-the-world.
91 IEA, Sustainable Recovery World Energy Outlook Special Report
(Paris: 2020), https://www.iea.org/reports/sustainable-recovery;
IHA, Strengthening Sustainable Hydropower to Support the Covid-
19 Recovery (London: 28 May 2020), https://www.hydropower.
org/publications/iha-position-paper-strengthening-sustainable-
hydropower-to-support-the-covid-19; technologies related to the
energy transition (renewables, electric vehicles and battery storage)
and digitalisation are among the sectors that have generated the
most interest from investors in the post-COVID-19 market, from
M. Rathbone, PWC, “Infrastructure investment opportunities in
the post-COVID-19 era”, presentation at International Finance
Corporation (IFC) Korea Workshop Series, 7 October 2020, https://
www.ifc.org/wps/wcm/connect/b2364239-ebac-465c-8afc-
71a83bdb8900/%28Consolidated%29_Infra+WS_ppt_201005.
pdf?MOD=AJPERES&CVID=nk5.nPl.
92 IEA, Electricity Market Report – December 2020 (Paris: 2020),
https://www.iea.org/reports/electricity-market-report-december-
2020/2020-global-overview-prices.
93 Voith Hydro, 2020 Annual Report (Heidenheim,
Germany: December 2020), https://voith.com/uk-en/
VZ_annual-report-2020_20_vvk_en .
94 Ibid.
95 GE, Form 10-K [as incorporated into 2020 Annual Report] (Boston:
February 2021), pp. 11-13, https://www.ge.com/sites/default/files/
GE_AR20_AnnualReport .
96 Andritz Group, Annual Report 2020 (Graz, Austria: 2020), pp. 61-62,
https://www.andritz.com/group-en/investors/annual-reports.
97 IEA, op. cit. note 91.
98 IRENA, “IRENA and IHA forge partnership to advance sustainable
hydropower”, press release (Abu Dhabi: 3 February 2021), https://
www.irena.org/newsroom/pressreleases/2021/Feb/IRENA-and-
IHA-Forge-Partnership-to-Advance-Sustainable-Hydropower.
99 “Research suggests ageing dams pose growing threat”,
International Water Power & Dam Construction, 25 January 2021,
https://www.waterpowermagazine.com/news/newsresearch-
suggests-ageing-dams-pose-growing-threat-8472001; “O&M
strategies for hydropower”, International Water Power & Dam
Construction, 3 June 2020, https://www.waterpowermagazine.
com/features/featureom-strategies-for-hydropower-7954776.
100 See, for example, Končar Ket, “Replacement of USZMR (control,
signaling, protection, measuring and regulation), uninterruptible
power supply system and own consumption system at HPP Đale”,
295
https://www.reuters.com/article/energia-eletrica-geracao-idBRKBN299276-OBRBS
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https://www.hydroreview.com/hydro-industry-news/commercial-startup-of-84-mw-la-virgen-hydro-in-peru-delayed-to-2021
https://www.hydroreview.com/hydro-industry-news/commercial-startup-of-84-mw-la-virgen-hydro-in-peru-delayed-to-2021
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https://www.osinergmin.gob.pe/seccion/centro_documental/electricidad/Documentos/PROYECTOS%20GFE/Generaci%C3%B3n/3-EN-CONSTRUCCION-MINEM
https://www.osinergmin.gob.pe/seccion/centro_documental/electricidad/Documentos/PROYECTOS%20GFE/Generaci%C3%B3n/3-EN-CONSTRUCCION-MINEM
https://www.ren21.net/gsr-2020
https://www.cne.cl/estadisticas/electricidad
https://www.cne.cl/estadisticas/electricidad
https://www.hydroreview.com/hydro-industry-news/israels-300-mw-mount-gilboa-pumped-storage-begins-operating
https://www.hydroreview.com/hydro-industry-news/israels-300-mw-mount-gilboa-pumped-storage-begins-operating
https://www.hydroreview.com/hydro-industry-news/israels-300-mw-mount-gilboa-pumped-storage-begins-operating
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https://www.renewableenergyworld.com/baseload/sse-renewables-receives-government-consent-for-coire-glas-pumped-storage-scheme
https://www.renewableenergyworld.com/baseload/sse-renewables-receives-government-consent-for-coire-glas-pumped-storage-scheme
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https://www.hydropower-dams.com/news/integrated-pumped-storage-schemes-for-india
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https://www.hydropower.org/country-profiles/australia
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https://www.energy.gov.au/government-priorities/energy-supply/pumped-hydro-and-snowy-20
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https://www.energy.gov.au/government-priorities/energy-supply/pumped-hydro-and-snowy-20
https://www.snowyhydro.com.au/snowy-20
https://www.snowyhydro.com.au/snowy-20
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https://www.hydro.com.au/news/media-releases/2020/12/15/lake-cethana-selected-as-first-pumped-hydro-project
https://www.hydro.com.au/news/media-releases/2020/12/15/lake-cethana-selected-as-first-pumped-hydro-project
https://www.hydro.com.au/docs/default-source/clean-energy/battery-of-the-nation/botn---cethana-pumped-hydro-fact-sheet-september-2019
https://www.hydro.com.au/docs/default-source/clean-energy/battery-of-the-nation/botn---cethana-pumped-hydro-fact-sheet-september-2019
https://www.hydro.com.au/docs/default-source/clean-energy/battery-of-the-nation/botn---cethana-pumped-hydro-fact-sheet-september-2019
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-walcha-energy-accelerate-500mw-pumped-hydro
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-walcha-energy-accelerate-500mw-pumped-hydro
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-walcha-energy-accelerate-500mw-pumped-hydro
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-with-be-power-to-accelerate-400-mw-pumped-hydro
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-with-be-power-to-accelerate-400-mw-pumped-hydro
https://www.ge.com/news/press-releases/ge-renewable-energy-signs-agreement-with-be-power-to-accelerate-400-mw-pumped-hydro
https://www.iberdrola.com/about-us/lines-business/flagship-projects/tamega-project
https://www.iberdrola.com/about-us/lines-business/flagship-projects/tamega-project
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https://en.evn.com.vn/d6/news/Ceremony-of-implementing-construction-and-launching-emulation-for-completing-discharge-gate-work-cluster-of-Bac-Ai-Pumped-Storage-Hydropower-Project-66-142-1744.aspx
https://en.evn.com.vn/d6/news/Ceremony-of-implementing-construction-and-launching-emulation-for-completing-discharge-gate-work-cluster-of-Bac-Ai-Pumped-Storage-Hydropower-Project-66-142-1744.aspx
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https://www.cbnme.com/news/dewas-al-tayer-reviews-construction-progress-at-the-hydroelectric-power-station-in-hatta
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https://www.ifc.org/wps/wcm/connect/b2364239-ebac-465c-8afc-71a83bdb8900/%28Consolidated%29_Infra+WS_ppt_201005 ?MOD=AJPERES&CVID=nk5.nPl
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https://www.waterpowermagazine.com/news/newsresearch-suggests-ageing-dams-pose-growing-threat-8472001
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https://www.waterpowermagazine.com/features/featureom-strategies-for-hydropower-7954776
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · HYDROPOWER
27 February 2020, https://www.koncar-ket.hr/en/news/zamjena-
sustava-uszmr-sustava-besprekidnih-napajanja-i-sustava-
vlastite-potrosnje-u-he-dale, and refurbishment references
provided in Hydropower Markets section.
101 M. A. Rodríguez, “Dan inicio a proceso para instalación de tres
turbinas más en Yacyretá”, ABC Color, 31 January 2021, https://
www.abc.com.py/nacionales/2021/01/31/dan-inicio-a-proceso-
para-instalacion-de-tres-turbinas-mas-en-yacyreta; “Itaipú
invertirá US$ 660 millones para digitalizar la operatividad de
la usina”, ABC Color, 31 Mayo 2020, https://www.abc.com.py/
edicion-impresa/economia/2020/05/30/itaipu-invertira-us-660-
millones-para-digitalizar-la-operatividad-de-la-usina.
102 Voith, “Voith launches a project for intelligent hydropower in
Australia”, press release (Heidenheim, Germany: 17 August 2020),
https://voith.com/corp-en/news-room/press-releases/2020-08-
17-vh-voith-launches-a-project-for-intelligent-hydropower-in-
australia.html.
103 XFLEX Hydro, Flexibility, Technologies and Scenarios for
Hydropower Report – Report Summary (Porto, Portugal: 25
November 2020), https://xflexhydro.net/flexibility-technologies-
and-scenarios-for-hydropower-report; IHA, “Greenhouse gas
emissions”, https://www.hydropower.org/factsheets/greenhouse-
gas-emissions, viewed 23 April 2021.
104 Hydro WIRES, US Department of Energy, Hydropower Value
Study: Current Status and Future Opportunities (Washington, DC:
January 2021), https://www.energy.gov/sites/prod/files/2021/01/
f82/hydropower-value-study-v2 .
105 Ibid; Bonneville Power Administration, “Energy Imbalance
Market”, https://www.bpa.gov/PROJECTS/Initiatives/EIM/
Pages/Energy-Imbalance-Market.aspx, viewed 19 May 2021.
106 Hydro WIRES, op. cit. note 104.
107 J. Leslie, “Stability Pathfinder”, International Water
Power & Dam Construction, 4 November 2020,
https://www.waterpowermagazine.com/features/
featurestability-pathfinder-8345488.
108 Ibid.; National Grid ESO, “National Grid ESO launch Stability
Pathfinder phase one”, press release (Warwick, UK:
22 October 2019), https://www.nationalgrideso.com/news/
national-grid-eso-launch-stability-pathfinder-phase-one.
109 N. Pombo-van Zyl, “West Africa: Hydro to support solar and wind
in smart renewable grid”, ESI Africa, 1 June 2020, https://www.
esi-africa.com/industry-sectors/future-energy/west-africa-hydro-
to-support-solar-and-wind-in-smart-renewable-grid; S. Sterl et
al., “Smart renewable electricity portfolios in West Africa”, Nature
Sustainability, vol. 3 (25 May 2020), https://doi.org/10.1038/
s41893-020-0539-0.
110 See, for example: Vattenfall, “Solar power complements
German pumped hydro plants”, press release (Stockholm: 9
September 2020), https://group.vattenfall.com/press-and-media/
newsroom/2020/solar-power-complements-german-pumped-
hydro-plants; A. Colthorpe, “India’s Greenko gets nearly US$1bn
investment for big hybrid renewables-plus-storage projects”,
Energy Storage News, 14 September 2020, https://www.
energy-storage.news/news/indias-greenko-gets-nearly-us1b-
investment-for-big-hybrid-renewables-plus-s.
111 GE, “GE Renewable Energy signs agreement with Walcha Energy
to accelerate 500 MW pumped hydro storage project in Australia”,
press release (Paris: 4 August 2020), https://www.ge.com/news/
press-releases/ge-renewable-energy-signs-agreement-walcha-
energy-accelerate-500mw-pumped-hydro.
112 D. Pittis, “Why cheap wind power is making Quebec’s big,
old dams more valuable as a ‘battery’, say experts”, CBC
News, 8 February 2021, https://www.cbc.ca/news/business/
apuiat-dam-wind-power-1.5903334.
113 See, for example: G. Deboutte, “First unit of 250 MW floating
PV project comes online in Ghana”, pv magazine, 15 December
2020, https://www.pv-magazine.com/2020/12/15/first-unit-of-
250-mw-floating-pv-project-comes-online-in-ghana; RusHydro,
“RusHydro brings online first floating solar power plant at Nizhne-
Bureyskaya HPP”, 11 August 2020, http://www.eng.rushydro.ru/
press/news/111675.html; A. Doyle, “Sun, water and ice: Lithuania
tests floating solar power”, Reuters, 29 September 2020, https://
www.reuters.com/article/idUSL5N2GL5PJ; H. Figueroa Alcázar,
“Urrá le apuesta a paneles solares flotantes”, El Universal, 24
December 2020, https://www.eluniversal.com.co/economica/
paneles-solares-flotantes-en-urra-hn3971180.
114 US National Renewable Energy Laboratory (NREL), “News release:
Untapped potential exists for blending hydropower, floating PV” (Golden,
CO: 29 September 2020), https://www.nrel.gov/news/press/2020/
untapped-potential-exists-for-blending-hydropower-floating-pv.html.
115 E. Bellini, “FV flutuante para compensar o baixo desempenho da
energia hidrelétrica no Brasil”, pv magazine Latam, 16 September
2020, https://www.pv-magazine-latam.com/brasil-noticias/
fv-flutuante-para-compensar-o-baixo-desempenho-da-energia-
hidreletrica-no-brasil.
116 Hydro Québec, “Hydro-Québec to operate one of the world’s most
powerful electrolyzers to produce green hydrogen”, press release
(Montreal: 8 December 2020), http://news.hydroquebec.com/
en/press-releases/1667/hydro-quebec-to-operate-one-of-the-
worlds-most-powerful-electrolyzers-to-produce-green-hydrogen;
“Landsvirkjun to build hydrogen production facility at 16-MW
Ljosifoss hydropower”, Renewable Energy World, 9 June 2020,
https://www.renewableenergyworld.com/hydrogen/landsvirkjun-to-
build-hydrogen-production-facility-at-16-mw-ljosifoss-hydropower.
117 L. Qing, “World’s first 1-million-kw hydro-turbine generator unit
hoisted”, Beijing Review, 22 June 2020, http://www.bjreview.com/
Business/202006/t20200622_800210916.html.
118 “TUM debuts new ‘shaft hydropower plant’ in Germany”, Hydro
Review, 20 July 2020, https://www.hydroreview.com/environmental/
tum-debuts-new-shaft-hydropower-plant-in-germany; Natel Energy,
“Natel Energy commissioned the Monroe Hydro Project, first fish-
safe restoration hydro turbine installation”, press release (Alameda,
CA: 10 December 2020), https://www.natelenergy.com/2020/12/10/
natel-energy-commissioned-the-monroe-hydro-project-first-fish-
safe-restoration-hydro-turbine-installation.
119 NREL, “Novel design configuration increases market viability for
pumped-storage hydropower in the United States”, 21 August
2020, https://www.nrel.gov/news/program/2020/psh-ensures-
resilient-energy-future.html.
120 REN21, op. cit. note 79.
121 Mekong River Commission (MRC), “Mekong River drops to ‘worrying’
levels, some sections turning blue-green”, 12 February 2021, https://
www.mrcmekong.org/news-and-events/news/pr002-12022021; MRC,
“New guidelines for Mekong hydropower released to help optimise
benefits, reduce risks”, 28 September 2020, https://www.mrcmekong.
org/news-and-events/news/new-guidelines-for-mekong-
hydropower-released-to-help-optimise-benefits-reduce-risks.
122 MRC, “Mekong River drops to ‘worrying’ levels”, op. cit. note 121;
“Three-way talks on Ethiopian dam reach new impasse”, op. cit.
note 52; “Iraqi MPs: Turkey’s operation of Ilisu Dam on Tigris
River threatens water security in Iraq”, Hawar News Agency, 25
December 2020, http://www.hawarnews.com/en/haber/iraqi-
mps-turkeys-operation-of-ilisu-dam-on-tigris-river-threatens-
water-security-in-iraq-h21723.html.
123 IEA, Climate Impacts on Latin American Hydropower (Paris:
January 2021), https://www.iea.org/reports/climate-impacts-
on-latin-american-hydropower/measures-to-enhance-the-
resilience-of-latin-american-hydropower; IEA, Climate Impacts
on African Hydropower (Paris: June 2020), https://www.
iea.org/reports/climate-impacts-on-african-hydropower/
measures-to-enhance-the-resilience-of-african-hydropower.
124 I. Todorović, “Federation of BiH bans construction of small hydropower
plants”, Balkan Green Energy News, 24 June 2020, https://
balkangreenenergynews.com/federation-of-bih-bans-construction-
of-small-hydropower-plants; I. Todorović, “Montenegro’s new cabinet
to ban small hydropower, revise concessions”, World Energy, 7
December 2020, https://www.world-energy.org/article/14353.html; I.
Todorović, “Sokobanja in Serbia to ban new small hydropower plants,
wind parks”, Balkan Green Energy News, 26 February 2020, https://
balkangreenenergynews.com/sokobanja-in-serbia-to-ban-new-small-
hydropower-plants-wind-parks.
125 V. Spasić, “New initiative to support sustainable hydropower in
the Western Balkans”, Balkan Green Energy News, 13 January
2021, https://balkangreenenergynews.com/new-initiative-to-
support-sustainable-hydropower-in-the-western-balkans.
126 IHA, “IHA sustainability assessment fund expands to more
countries”, 12 February 2021, https://www.hydropower.org/
news/iha-sustainability-assessment-fund-expands-to-more-
countries; IHA, “Small hydro project leads the way in South Africa
on sustainable development”, 21 January 2021, https://www.
hydropower.org/news/small-hydro-project-leads-the-way-in-
south-africa-on-sustainable-development.
296
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https://www.hydropower.org/news/small-hydro-project-leads-the-way-in-south-africa-on-sustainable-development
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · OCE AN POWER
OCEAN POWER
1 International Renewable Energy Agency (IRENA), Renewable Capacity
Statistics 2021 (Abu Dhabi: March 2021), p. 12, https://www.irena.org/
publications/2021/March/Renewable-Capacity-Statistics-2021.
2 Ibid.
3 Ocean Energy Europe, Ocean Energy: Key Trends and
Statistics 2020 (Brussels: February 2021), p. 13, https://www.
oceanenergy-europe.eu/wp-content/uploads/2021/03/OEE-
Stats-Trends-2020 .
4 European Commission (EC), Strategy on Offshore Renewable Energy
(Brussels: November 2020), https://eur-lex.europa.eu/legal-
content/EN/TXT/?uri=COM%3A2020%3A741%3AFIN&qid
=1605792629666.
5 EC, Study on Lessons for Ocean Energy Development
(Brussels: 2017), p. iii, https://publications.europa.eu/resource/
cellar/03c9b48d-66af-11e7-b2f2-01aa75ed71a1.0001.01/DOC_1.
6 Ocean Energy Europe, op. cit. note 3, p. 4.
7 G. Smart and M. Noonan, Tidal Stream and Wave Energy
Cost Reduction and Industrial Benefit (Glasgow, Scotland:
Offshore Renewable Energy Catapult, 2018), https://www.
marineenergywales.co.uk/wp-content/uploads/2018/05/ORE-
Catapult-Tidal-Stream-and-Wave-Energy-Cost-Reduction-and-
Ind-Benefit-FINAL-v03.02 ; European Marine Energy Centre
Ltd., “Wave devices”, http://www.emec.org.uk/marine-energy/
wave-devices, viewed 15 March 2021.
8 Ocean Energy Europe, Ocean Energy: Key Trends and Statistics 2019
(Brussels: March 2020), p. 10, https://www.oceanenergy-europe.eu/
wp-content/uploads/2020/03/OEE_Trends-Stats_2019_Web .
9 SIMEC Atlantis Energy, “Overcoming the pandemic to build
a mammoth turbine in Wuhan: Atlantis helping to open up
China’s 8.2GW tidal stream renewable power potential”, press
release (Edinburgh: 27 April 2020), https://simecatlantis.
com/2020/04/27/overcoming-the-pandemic-to-build-a-
mammoth-turbine-in-wuhan.
10 Ibid.
11 International Energy Agency, Ocean Energy Systems (IEA-OES),
Annual Report 2020 (Lisbon: 2020), p. 11, https://www.ocean-energy-
systems.org/documents/40962-oes-annual-report-2020 .
12 IEA-OES, Spotlight on Ocean Energy (Lisbon: November 2018),
https://www.ocean-energy-systems.org/documents/84169-oes-
spotlight-on-ocean-energy .
13 IEA-OES, op. cit. note 11, p. 12.
14 IEA-OES, “China”, https://www.ocean-energy-systems.org/
ocean-energy-in-the-world/china, viewed 15 March 2021.
15 Verdant Power, “Three Verdant Power tidal turbines deployed in
New York City’s East River”, press release (New York: 22 October
2020), https://www.verdantpower.com/news-rite-install-10-22-20.
16 Verdant Power, “Verdant Power’s New York City tidal turbines
exceed expectations”, press release (New York: 27 January 2021),
https://www.verdantpower.com/turbine-perfrormance.
17 US Department of Energy, Water Power Technologies Office, 2019-
2020 Accomplishments Report (Washington, DC: 2021), p. 72,
https://www.energy.gov/sites/prod/files/2021/01/f82/2019-2020-
wpto-accomplishments-report .
18 Ibid.
19 ORPC, “ORPC selects Maine company to fabricate second
commercial underwater power system”, press release (Portland,
ME: 11 August 2020), https://orpc.co/uploads/news/orpc-selects-
maine-company-to-fabricate-second-commercial-underwater-
power-system_637327295969885603 ; Congresswoman
C. Pingree, “Pingree announces $3.6M grant for Maine firm
to develop renewable tidal power system”, press release
(Washington, DC: 24 November 2020), https://pingree.house.gov/
news/documentsingle.aspx?DocumentID=3549.
20 Nova Innovation, “Nova Innovation celebrates birthday with
Shetland Tidal Array expansion”, 17 October 2020, https://www.
novainnovation.com/news/news_/i/nova-innovation-celebrates-
birthday-with-shetland-tidal-array-expansion.
21 EnFAIT, “The project”, https://www.enfait.eu/the-project, viewed
15 March 2021.
22 Nova Innovation, “Europe Case Study – Shetland Tidal Array”,
https://www.novainnovation.com/markets/scotland-shetland-
tidal-array, viewed 15 March 2021.
23 DesignPro Renewables, “60kW testing successfully
concludes in Orkney Islands”, press release (Limerick,
Ireland: 28 January 2020), https://designprorenewables.
com/60kw-testing-successfully-concludes-in-orkney-islands.
24 Minesto, “Minesto reaches historic milestone – delivers first
tidal energy to the Faroese grid”, press release (Västra Frölunda,
Sweden: 1 December 2020), https://minesto.com/news-media/
minesto-reaches-historic-milestone-%E2%80%93-delivers-first-
tidal-energy-faroese-grid.
25 Ibid.; Minesto, “Minesto breaks new ground in the energy sector
as it proves its subsea kite technology”, press release (Västra
Frölunda, Sweden: 30 August 2018), https://minesto.com/news-
media/minesto-breaks-new-ground-energy-sector-it-proves-its-
subsea-kite-technology; Minesto, “Minesto generates electricity
for the first time with commercial-scale unit”, press release
(Västra Frölunda, Sweden: 9 October 2018), https://minesto.com/
news-media/minesto-generates-electricity-first-time-commercial-
scale-unit; Minesto, “Minesto signs PPA with electric utility SEV
for utility-scale tidal energy installations”, press release (Västra
Frölunda, Sweden: 19 February 2020), https://minesto.com/
news-media/minesto-signs-ppa-electric-utility-sev-utility-scale-
tidal-energy-installations; Minesto, “Minesto secures all permits
for Faroe Islands’ installations”, press release (Västra Frölunda,
Sweden: 1 April 2020), https://minesto.com/news-media/minesto-
secures-all-permits-faroe-islands%E2%80%99-installations.
26 Minesto, “Holyhead Deep – the world’s first low-flow tidal stream
project”, https://minesto.com/projects/holyhead-deep, viewed
15 March 2021.
27 Ibid.; Minesto, “Minesto’s Holyhead Assembly Hall is now fully
operational”, press release (Västra Frölunda, Sweden: 1 October
2020), https://minesto.com/news-media/minesto%E2%80%99s-
holyhead-assembly-hall-now-fully-operational.
28 Ibid.
29 Ocean Energy Europe, op. cit. note 3, p. 12.
30 SIMEC Atlantis Energy, “MeyGen Phase 1A completes
construction phase and officially enters 25 year operations
phase”, press release (Edinburgh: 12 April 2018), https://
simecatlantis.com/2018/04/12/meygen-phase-1a-completes-
construction-phase-and-officially-enters-25-year-operations-
phase; SIMEC Atlantis Energy, “MeyGen operational update”,
27 January 2020, https://simecatlantis.com/2020/01/27/4036.
31 SIMEC Atlantis Energy, “Operational update”, 9 December 2020,
https://simecatlantis.com/2020/12/09/4674; SIMEC Atlantis
Energy, “Operational update”, 7 April 2021, https://simecatlantis.
com/2021/04/07/operational-update.
32 Ibid.
33 SIMEC Atlantis Energy, “Atlantis supplied, Scottish manufactured
tidal generation equipment arrives in Nagasaki, Japan ahead
of deployment in the Naru Strait”, 22 December 2020, https://
simecatlantis.com/2020/12/22/4705.
34 Nova Scotia Canada, “Developmental Tidal Feed-in Tariff
Program”, https://energy.novascotia.ca/renewables/programs-
and-projects/tidal-fit, viewed 15 March 2021.
35 Ibid.
36 Nova Scotia Ministry of Energy and Mines, “Marine Renewable-
energy Demonstration Permit – No. 2020-70-0004 issued to
Neweast Energy Corporation n Registry of Joint Stock Companies
ID No. 3329875”, 20 August 2020, https://energy.novascotia.ca/
sites/default/files/files/Signed_DEMO_Permit_for_Neweast_
Energy_-_Aug_21_2020 .
37 Natural Resources Canada, “Canada makes historic investments
in tidal energy in Nova Scotia”, press release (Halifax, Nova Scotia:
5 November 2020), https://www.canada.ca/en/natural-resources-
canada/news/2020/11/canada-makes-historic-investments-in-
tidal-energy-in-nova-scotia.html; Nova Innovation, “Canadian
Government invests in Nova Scotia Tidal Energy Project”, 9
September 2020, https://www.novainnovation.com/news/news_
/i/canadian-government-invests-in-nova-scotia-tidal-energy.
38 Natural Resources Canada, “Minister Sohi announces major
investment in renewable tidal energy that will power 2,500
homes in Nova Scotia”, press release (Halifax, Nova Scotia: 20
September 2018), https://www.canada.ca/en/natural-resources-
canada/news/2018/09/minister-sohi-announces-major-
investment-in-renewable-tidal-energy-that-will-power-2500-
homes-in-nova-scotia.html.
297
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
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https://www.oceanenergy-europe.eu/wp-content/uploads/2021/03/OEE-Stats-Trends-2020
https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=COM%3A2020%3A741%3AFIN&qid=1605792629666
https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=COM%3A2020%3A741%3AFIN&qid=1605792629666
https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=COM%3A2020%3A741%3AFIN&qid=1605792629666
https://publications.europa.eu/resource/cellar/03c9b48d-66af-11e7-b2f2-01aa75ed71a1.0001.01/DOC_1
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https://www.marineenergywales.co.uk/wp-content/uploads/2018/05/ORE-Catapult-Tidal-Stream-and-Wave-Energy-Cost-Reduction-and-Ind-Benefit-FINAL-v03.02
https://www.marineenergywales.co.uk/wp-content/uploads/2018/05/ORE-Catapult-Tidal-Stream-and-Wave-Energy-Cost-Reduction-and-Ind-Benefit-FINAL-v03.02
http://www.emec.org.uk/marine-energy/wave-devices
http://www.emec.org.uk/marine-energy/wave-devices
https://www.oceanenergy-europe.eu/wp-content/uploads/2020/03/OEE_Trends-Stats_2019_Web
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https://www.ocean-energy-systems.org/documents/40962-oes-annual-report-2020
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https://minesto.com/news-media/minesto-breaks-new-ground-energy-sector-it-proves-its-subsea-kite-technology
https://minesto.com/news-media/minesto-breaks-new-ground-energy-sector-it-proves-its-subsea-kite-technology
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https://minesto.com/news-media/minesto-generates-electricity-first-time-commercial-scale-unit
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https://minesto.com/news-media/minesto-generates-electricity-first-time-commercial-scale-unit
https://minesto.com/news-media/minesto-signs-ppa-electric-utility-sev-utility-scale-tidal-energy-installations
https://minesto.com/news-media/minesto-signs-ppa-electric-utility-sev-utility-scale-tidal-energy-installations
https://minesto.com/news-media/minesto-signs-ppa-electric-utility-sev-utility-scale-tidal-energy-installations
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https://simecatlantis.com/2018/04/12/meygen-phase-1a-completes-construction-phase-and-officially-enters-25-year-operations-phase
https://simecatlantis.com/2018/04/12/meygen-phase-1a-completes-construction-phase-and-officially-enters-25-year-operations-phase
https://simecatlantis.com/2018/04/12/meygen-phase-1a-completes-construction-phase-and-officially-enters-25-year-operations-phase
https://simecatlantis.com/2018/04/12/meygen-phase-1a-completes-construction-phase-and-officially-enters-25-year-operations-phase
https://simecatlantis.com/2020/01/27/4036
https://simecatlantis.com/2020/12/09/4674
https://simecatlantis.com/2021/04/07/operational-update
https://simecatlantis.com/2021/04/07/operational-update
https://simecatlantis.com/2020/12/22/4705
https://simecatlantis.com/2020/12/22/4705
https://energy.novascotia.ca/renewables/programs-and-projects/tidal-fit
https://energy.novascotia.ca/renewables/programs-and-projects/tidal-fit
https://energy.novascotia.ca/sites/default/files/files/Signed_DEMO_Permit_for_Neweast_Energy_-_Aug_21_2020
https://energy.novascotia.ca/sites/default/files/files/Signed_DEMO_Permit_for_Neweast_Energy_-_Aug_21_2020
https://energy.novascotia.ca/sites/default/files/files/Signed_DEMO_Permit_for_Neweast_Energy_-_Aug_21_2020
https://www.canada.ca/en/natural-resources-canada/news/2020/11/canada-makes-historic-investments-in-tidal-energy-in-nova-scotia.html
https://www.canada.ca/en/natural-resources-canada/news/2020/11/canada-makes-historic-investments-in-tidal-energy-in-nova-scotia.html
https://www.canada.ca/en/natural-resources-canada/news/2020/11/canada-makes-historic-investments-in-tidal-energy-in-nova-scotia.html
https://www.novainnovation.com/news/news_/i/canadian-government-invests-in-nova-scotia-tidal-energy
https://www.novainnovation.com/news/news_/i/canadian-government-invests-in-nova-scotia-tidal-energy
https://www.canada.ca/en/natural-resources-canada/news/2018/09/minister-sohi-announces-major-investment-in-renewable-tidal-energy-that-will-power-2500-homes-in-nova-scotia.html
https://www.canada.ca/en/natural-resources-canada/news/2018/09/minister-sohi-announces-major-investment-in-renewable-tidal-energy-that-will-power-2500-homes-in-nova-scotia.html
https://www.canada.ca/en/natural-resources-canada/news/2018/09/minister-sohi-announces-major-investment-in-renewable-tidal-energy-that-will-power-2500-homes-in-nova-scotia.html
https://www.canada.ca/en/natural-resources-canada/news/2018/09/minister-sohi-announces-major-investment-in-renewable-tidal-energy-that-will-power-2500-homes-in-nova-scotia.html
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · OCE AN POWER
39 Nova Scotia Ministry for Energy and Mines, “New tidal energy developer
joins FORCE”, press release (Halifax, Nova Scotia: 2 September 2020),
https://novascotia.ca/news/release/?id=20200902001.
40 IEA-OES, op. cit. note 11, p. 67.
41 HydroQuest, “Project overview”, https://www.hydroquest.fr/
oceanquest, viewed 15 March 2021.
42 DesignPro Renewables, “DesignPro extends testing at SEENEOH
thanks to BlueGift support”, press release (Limerick, Ireland:
26 March 2020), https://designprorenewables.com/designpro-
extends-testing-at-seeneoh-thanks-to-bluegift-support.
43 Ocean Energy Europe, “Sabella”, https://www.oceanenergy-
europe.eu/annual/sabella, viewed 15 March 2021.
44 SIMEC Atlantis Energy, “Normandy Prefecture approves transfer
of 12MW tidal power development lease from Engie to Normandie
Hydroliennes”, press release (Edinburgh: 22 June 2020), https://
simecatlantis.com/2020/06/22/normandy-prefecture-approves-
transfer-of-12mw-tidal-power-development-lease-from-engie-to-
normandie-hydroliennes.
45 A. van Unen, “Tocardo acquires the largest tidal array in the
world”, Tocardo, 12 October 2020, https://www.tocardo.com/
tocardo-acquires-1-25mw-oosterschelde-tidal-power-plant-the-
largest-tidal-array-in-the-world; A. van Unen, “Oosterschelde
Tidal Powerplant resumed full continuous operations again”,
Tocardo, 9 February 2021), https://www.tocardo.com/
oosterschelde-tidal-powerplant-resumed-full-continuous-
operations-again.
46 Guangzhou Institute of Energy Conversion, “’Zhoushan’ – China’s
first 500kW Sharp Eagle Wave Energy Converter was officially
delivered”, 3 July 2020, http://english.giec.cas.cn/ns/tn/202007/
t20200703_240147.html.
47 IEA-OES, Wave Energy Developments: Highlights (Lisbon: 2021),
p. 7, https://www.ocean-energy-systems.org/documents/95502-
wave-energy-highlights-march-2021 .
48 Ibid., p. 6.
49 A. Garanovic, “Wavepiston deploys device off Gran Canaria”,
Offshore Energy, 18 December 2020, https://www.offshore-
energy.biz/wavepiston-deploys-device-off-gran-canaria.
50 S. Patel, “Ocean power developers made crucial progress in
2020”, POWER, 1 April 2021, https://www.powermag.com/
ocean-power-developers-made-crucial-progress-in-2020.
51 IEA-OES, op. cit. note 11, p. 12.
52 “The IHES Consortium led by GEPS Techno installs the wave
energy recovery prototype WAVEGEM® on the Centrale Nantes
offshore test site”, Central Nantes, 26 August 2019, https://sem-rev.
ec-nantes.fr/sem-rev/sem-rev-news/the-ihes-consortium-led-
by-geps-techno-installs-the-wave-energy-recovery-prototype-
wavegem%C2%AE-on-the-centrale-nantes-offshore-test-site.
53 Ocean Power Technologies (OTP), “PB3 PowerBuoy®
achieves new operational milestone”, 19 August
2020, https://oceanpowertechnologies.com/
pb3-powerbuoy-achieves-new-operational-milestone.
54 OPT, “OPT’s Italian deployment extended in current location”,
27 April 2020, https://oceanpowertechnologies.com/
opts-italian-deployment-extended-in-current-location.
55 OPT, “OPT taps SeaTrepid International for first remote
OPT PowerBuoy® deployment”, 7 December 2020, https://
oceanpowertechnologies.com/opt-taps-seatrepid-international-
for-first-remote-opt-powerbuoy-deployment.
56 Bombora, “Survey campaign completion milestone achieved for
3.0MW Lanzarote Wave Park project”, 23 April 2020, https://
bomborawave.com/wp-content/uploads/2020/04/200423-
Survey-Campaign-Completion-Milestone-Achieved-for-3MW-
Lanzarote-Wave-Park-Project- .
57 Bombora, “Project InSPIRE has commenced”, https://
bomborawave.com/latest-news/project-inspire-12mw,
viewed 15 March 2021.
58 Ibid.
59 Wave Swell Energy, “A world first project”, https://www.
waveswell.com/king-island-project-2, viewed 15 March 2021.
60 S. Vorrath, “Carnegie looks to boost CETO 6 wave power
efficiency, reliability and smarts”, RenewEconomy, 2 March 2020,
https://reneweconomy.com.au/carnegie-looks-to-boost-ceto-6-
wave-power-efficiency-reliability-and-smarts-91891.
61 A. Dokso, “Carnegie delivers wave predictor; COVID-19 delays
validation”, Offshore Energy, 6 April 2020, https://www.offshore-energy.
biz/carnegie-delivers-wave-predictor-covid-19-delays-validation.
62 A. Garanovic, “Oscilla Power opens another crowdfunding round”,
Offshore Energy, 29 December 2020, https://www.offshore-
energy.biz/oscilla-power-opens-another-crowdfunding-round.
63 Ibid.
64 B. O’Donovan, “Irish company launches wave energy
device in the US”, RTE, 10 October 2019, https://www.rte.ie/
news/2019/1010/1082377-ocean-energy-us.
65 REDstack, “Prototype development of Blue Energy Rack
completed”, 16 June 2020, https://redstack.nl/en/2020/06/16/
prototype-ontwikkeling-blue-energy-rack-afgerond.
66 Akuo, “Akuo and the IANOS European project are targeting
a zero-carbon Bora Bora”, press release (Bora Bora, French
Polynesia: 16 November 2020), https://www.akuoenergy.com/en/
documents/getPdf/cp-bora-bora-en .
67 Government of Puerto Rico, Puerto Rico Ocean Technology Complex
Proposed Roadmap for Development (San Juan: 6 July 2020), https://
refuerzoeconomico.com/images/2020-07-06%20PROTECH_
Proposed%20Roadmap%20for%20Development_Red .
68 IEA-OES, op. cit. note 11, p. 42.
69 D. Magagna, Ocean Energy Technology Development Report 2018
(Luxembourg: EC Low Carbon Energy Observatory, 2019), https://
publications.jrc.ec.europa.eu/repository/bitstream/JRC118296/
jrc118296_1 .
70 Ibid.; Directorate-General for Maritime Affairs and Fisheries of the
European Commission, Market Study on Ocean Energy (Brussels:
20 June 2018), https://publications.europa.eu/en/publication-
detail/-/publication/e38ea9ce-74ff-11e8-9483-01aa75ed71a1/
language-en/format-PDF/source-99081151.
71 SIMEC Atlantis Energy, “Atlantis announces Share Placement
Agreement”, 16 December 2020, https://simecatlantis.com/2020/
12/16/4690.
72 S. Braun, “Ocean energy about to ride a wave”, DW, 9 February 2021,
https://www.dw.com/en/ocean-energy-about-to-ride-a-wave/a-
56316422.
73 Directorate-General for Maritime Affairs and Fisheries of the
European Commission, op. cit. note 70.
74 SET Plan Temporary Working Group, Ocean Energy –
Implementation Plan (Brussels: 2018), https://setis.ec.europa.eu/
system/files/2021-04/set_plan_ocean_implementation_plan .
75 IEA-OES, An International Evaluation and Guidance Framework
for Ocean Energy Technology (Lisbon: 29 January 2021), https://
www.ocean-energy-systems.org/documents/47763-evaluation-
guidance-ocean-energy-technologies2 .
76 European Technology and Innovation Platform for Ocean Energy
(ETIP Ocean), Ocean Energy and the Environment: Research and
Strategic Actions (December 2020), https://www.oceanenergy-
europe.eu/wp-content/uploads/2020/12/ETIP-Ocean-Ocean-
energy-and-the-environment .
77 A. Copping, The State of Knowledge for Environmental Effects
Driving Consenting/Permitting for the Marine Renewable
Energy Industry (Richland, WA: IEA-OES and Pacific Northwest
National Laboratory, January 2018), https://www.ocean-
energy-systems.org/publications/position-papers/document/
the-state-of-knowledge-for-environmental-effects-2018-.
78 ETIP Ocean, op. cit. note 76.
79 Ibid.
298
https://novascotia.ca/news/release/?id=20200902001
https://www.hydroquest.fr/oceanquest
https://www.hydroquest.fr/oceanquest
https://designprorenewables.com/designpro-extends-testing-at-seeneoh-thanks-to-bluegift-support
https://designprorenewables.com/designpro-extends-testing-at-seeneoh-thanks-to-bluegift-support
https://www.oceanenergy-europe.eu/annual/sabella
https://www.oceanenergy-europe.eu/annual/sabella
https://simecatlantis.com/2020/06/22/normandy-prefecture-approves-transfer-of-12mw-tidal-power-development-lease-from-engie-to-normandie-hydroliennes
https://simecatlantis.com/2020/06/22/normandy-prefecture-approves-transfer-of-12mw-tidal-power-development-lease-from-engie-to-normandie-hydroliennes
https://simecatlantis.com/2020/06/22/normandy-prefecture-approves-transfer-of-12mw-tidal-power-development-lease-from-engie-to-normandie-hydroliennes
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https://www.tocardo.com/tocardo-acquires-1-25mw-oosterschelde-tidal-power-plant-the-largest-tidal-array-in-the-world
https://www.tocardo.com/tocardo-acquires-1-25mw-oosterschelde-tidal-power-plant-the-largest-tidal-array-in-the-world
https://www.tocardo.com/tocardo-acquires-1-25mw-oosterschelde-tidal-power-plant-the-largest-tidal-array-in-the-world
https://www.tocardo.com/oosterschelde-tidal-powerplant-resumed-full-continuous-operations-again
https://www.tocardo.com/oosterschelde-tidal-powerplant-resumed-full-continuous-operations-again
https://www.tocardo.com/oosterschelde-tidal-powerplant-resumed-full-continuous-operations-again
http://english.giec.cas.cn/ns/tn/202007/t20200703_240147.html
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https://www.ocean-energy-systems.org/documents/95502-wave-energy-highlights-march-2021
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https://www.offshore-energy.biz/wavepiston-deploys-device-off-gran-canaria
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https://www.powermag.com/ocean-power-developers-made-crucial-progress-in-2020
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https://sem-rev.ec-nantes.fr/sem-rev/sem-rev-news/the-ihes-consortium-led-by-geps-techno-installs-the-wave-energy-recovery-prototype-wavegem%C2%AE-on-the-centrale-nantes-offshore-test-site
https://sem-rev.ec-nantes.fr/sem-rev/sem-rev-news/the-ihes-consortium-led-by-geps-techno-installs-the-wave-energy-recovery-prototype-wavegem%C2%AE-on-the-centrale-nantes-offshore-test-site
https://sem-rev.ec-nantes.fr/sem-rev/sem-rev-news/the-ihes-consortium-led-by-geps-techno-installs-the-wave-energy-recovery-prototype-wavegem%C2%AE-on-the-centrale-nantes-offshore-test-site
https://sem-rev.ec-nantes.fr/sem-rev/sem-rev-news/the-ihes-consortium-led-by-geps-techno-installs-the-wave-energy-recovery-prototype-wavegem%C2%AE-on-the-centrale-nantes-offshore-test-site
https://oceanpowertechnologies.com/pb3-powerbuoy-achieves-new-operational-milestone
https://oceanpowertechnologies.com/pb3-powerbuoy-achieves-new-operational-milestone
https://oceanpowertechnologies.com/opts-italian-deployment-extended-in-current-location
https://oceanpowertechnologies.com/opts-italian-deployment-extended-in-current-location
https://oceanpowertechnologies.com/opt-taps-seatrepid-international-for-first-remote-opt-powerbuoy-deployment
https://oceanpowertechnologies.com/opt-taps-seatrepid-international-for-first-remote-opt-powerbuoy-deployment
https://oceanpowertechnologies.com/opt-taps-seatrepid-international-for-first-remote-opt-powerbuoy-deployment
https://bomborawave.com/wp-content/uploads/2020/04/200423-Survey-Campaign-Completion-Milestone-Achieved-for-3MW-Lanzarote-Wave-Park-Project-
https://bomborawave.com/wp-content/uploads/2020/04/200423-Survey-Campaign-Completion-Milestone-Achieved-for-3MW-Lanzarote-Wave-Park-Project-
https://bomborawave.com/wp-content/uploads/2020/04/200423-Survey-Campaign-Completion-Milestone-Achieved-for-3MW-Lanzarote-Wave-Park-Project-
https://bomborawave.com/wp-content/uploads/2020/04/200423-Survey-Campaign-Completion-Milestone-Achieved-for-3MW-Lanzarote-Wave-Park-Project-
https://bomborawave.com/latest-news/project-inspire-12mw
https://bomborawave.com/latest-news/project-inspire-12mw
https://www.waveswell.com/king-island-project-2
https://www.waveswell.com/king-island-project-2
https://reneweconomy.com.au/carnegie-looks-to-boost-ceto-6-wave-power-efficiency-reliability-and-smarts-91891
https://reneweconomy.com.au/carnegie-looks-to-boost-ceto-6-wave-power-efficiency-reliability-and-smarts-91891
https://www.offshore-energy.biz/carnegie-delivers-wave-predictor-covid-19-delays-validation
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https://www.offshore-energy.biz/oscilla-power-opens-another-crowdfunding-round
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https://www.rte.ie/news/2019/1010/1082377-ocean-energy-us
https://www.rte.ie/news/2019/1010/1082377-ocean-energy-us
https://redstack.nl/en/2020/06/16/prototype-ontwikkeling-blue-energy-rack-afgerond
https://redstack.nl/en/2020/06/16/prototype-ontwikkeling-blue-energy-rack-afgerond
https://www.akuoenergy.com/en/documents/getPdf/cp-bora-bora-en
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https://refuerzoeconomico.com/images/2020-07-06%20PROTECH_Proposed%20Roadmap%20for%20Development_Red
https://refuerzoeconomico.com/images/2020-07-06%20PROTECH_Proposed%20Roadmap%20for%20Development_Red
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https://publications.jrc.ec.europa.eu/repository/bitstream/JRC118296/jrc118296_1
https://publications.jrc.ec.europa.eu/repository/bitstream/JRC118296/jrc118296_1
https://publications.jrc.ec.europa.eu/repository/bitstream/JRC118296/jrc118296_1
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https://simecatlantis.com/2020/12/16/4690
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https://setis.ec.europa.eu/system/files/2021-04/set_plan_ocean_implementation_plan
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https://www.ocean-energy-systems.org/documents/47763-evaluation-guidance-ocean-energy-technologies2
https://www.ocean-energy-systems.org/documents/47763-evaluation-guidance-ocean-energy-technologies2
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https://www.ocean-energy-systems.org/publications/position-papers/document/the-state-of-knowledge-for-environmental-effects-2018-
https://www.ocean-energy-systems.org/publications/position-papers/document/the-state-of-knowledge-for-environmental-effects-2018-
https://www.ocean-energy-systems.org/publications/position-papers/document/the-state-of-knowledge-for-environmental-effects-2018-
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR PV
SOL AR PV
1 At least 139.4 gigawatts direct current (GWDC) was installed
and commissioned globally for a year-end total of at least 760.4
GWDC, preliminary data from International Energy Agency (IEA)
Photovoltaic Power Systems Programme (PVPS), Snapshot
of Global PV Markets 2021 (Paris: April 2021), p. 6, https://
iea-pvps.org/wp-content/uploads/2021/04/IEA_PVPS_
Snapshot_2021-V3 , and confirmed by G. Masson, Becquerel
Institute and IEA PVPS, Brussels, personal communication with
Renewable Energy Policy Network for the 21st Century (REN21),
25 May 2021. Estimated 139.4 GWDC of capacity was installed
and commissioned globally in 2020 (counting 136 GW of official
or industry reported data for 60 countries plus an additional
estimated 3.3 GW in the rest of the world) for a year-end global
total of an estimated 760.4 GWDC (counting 745 GW of official
or industry reported data for 69 countries plus an additional
estimated and reported 15.2 GW in rest of world), based on
preliminary reported data, from IEA PVPS and Becquerel
Institute, Brussels, personal communication with REN21, March
to May 2021. By contrast, global additions in 2019 totalled 111,585
MWDC, from IEA PVPS, Trends in Photovoltaic Applications
2020 (Paris: 2020), p. 85, https://iea-pvps.org/wp-content/
uploads/2020/11/IEA_PVPS_Trends_Report_2020-1 .
Note that capacity data are uncertain due to several factors,
including: a lack of good data in many countries, particularly with
regard to small distributed systems, both on and off the grid;
lack of information about the amount of capacity that has been
decommissioned or is inoperable; large discrepancies between
data available in alternating current (AC) and direct current (DC).
With regard to the AC/DC issue, reported capacity data often do
not specify if numbers are in AC or DC and, even where AC or
DC is specified, the conversion rate is generally not published,
all from Masson, op. cit. this note. Data from other sources
include: additions of 135 GW in 2020 from BloombergNEF, 1Q
2021 Global PV Market Outlook, cited in E. Bellini, “BloombergNEF
expects up to 209 GW of new solar for this year”, pv magazine,
23 February 2021, https://www.pv-magazine.com/2021/02/23/
bloombergnef-expects-up-to-209-gw-of-new-solar-for-this-year;
market expanded 23% with almost 135 GW installed in 2020, from
IEA, “Renewable electricity”, in Renewable Energy Market Update
2021 (Paris: 2021), https://www.iea.org/reports/renewable-
energy-market-update-2021/renewable-electricity; net additions
of 126,735 MW, including a mix of AC and DC, based on a total
of 707,495 MW at the end of 2020 and 580,760 MW at the end
of 2019, from International Renewable Energy Agency (IRENA),
Renewable Capacity Statistics 2021 (Abu Dhabi: March 2021),
https://www.irena.org/publications/2021/March/Renewable-
Capacity-Statistics-2021; global installations were up 10% to 142
GW in 2020, from IHS Markit, cited in Reuters, “Solar installations
on pace for biggest growth in five years, IHS Markit says”,
Economic Times, 30 March 2021, https://energy.economictimes.
indiatimes.com/news/renewable/solar-installations-on-pace-
for-biggest-growth-in-five-years-ihs-markit-says/81755484;
approximately 129.2-GWpeak (DC) added for a global total of 722
GWp, based on shipments during 2020 and supply- and demand-
side inventory, and considering losses due to poor quality and
breakage in transport and installation, from P. Mints, SPV Market
Research, San Francisco, CA, personal communication with
REN21, 6 May 2021. Note that cumulative shipments from 1975
through 2020 totalled 722.8 GW direct current (or peak), from
P. Mints, Photovoltaic Manufacturer Capacity, Shipments, Price
& Revenues 2020/2021 (San Francisco: SPV Market Research,
April 2021), p. 15. The numbers published by IEA PVPS include
all installations (both on-grid and off-grid) when reported, and
are based on official data in reporting countries; many of these
countries account for decommissioning of existing capacity, but
not all countries track either decommissioning or repowering
of solar PV capacity. Further, while recycling numbers might
also be helpful for determining capacity decommissioned,
recycling programmes remain uncommon and data are
extremely limited. IEA PVPS assumes that decommissioning
is relatively uncommon at this stage, given that most global
installations were commissioned in 2005 and later, from IEA
PVPS, Snapshot of Global PV Markets 2021, op. cit. this note, p.
13. Several countries report data officially in AC (i.e., Canada,
Chile, Greece, India, Japan, Malaysia, Singapore, Spain, Sweden
and the United States); these data were converted to DC by IEA
PVPS, Becquerel Institute and other sources in this section for
consistency across countries. The difference between DC and
AC power can range from as little as 5% (conversion losses,
inverter set at DC level) to as much as 60%, and most utility-scale
solar PV plants built in 2020 have an AC-DC ratio between 1.1
and 1.6, from IEA PVPS, Snapshot of Global PV Markets 2021, op.
cit. this note, p. 11. MWpeak or MWDC is the rated direct current
of a solar system under solar standard test conditions; MWAC,
measured in terms of alternating current, is the output a system
is designed to deliver to the grid. Losses occur between the solar
array and output to the grid, so capacity in AC will always be
lower than peak capacity in DC. Conversions done by IEA PVPS
and the Becquerel Institute use a multiplier of 1.3 for centralised
capacity to convert capacity from AC to DC. In the United States,
the median inverter loading ratio (ratio of DC nameplate rating
to AC inverter nameplate rating) in 2018, for both tracked and
fix-tilt utility-scale projects, was 1.33, but there is significant
variation across projects, from M. Bolinger, J. Seel and D. Robson,
Utility-scale Solar: Empirical Trends in Project Technology, Cost,
Performance, and PPA Pricing in the United States – 2019 Edition
(Berkeley, CA: Lawrence Berkeley National Laboratory (LBNL),
December 2019), p. ii, https://eta-publications.lbl.gov/sites/
default/files/lbnl_utility_scale_solar_2019_edition_final . The
argument is made that AC ratings are more appropriate for utility-
scale capacity because other conventional and renewable utility-
scale generating sources also are described in AC terms, and
because the difference between a project’s DC and AC capacity
ratings is increasing in general (at least in the United States) due
to a lower relative inverter rating, from M. Bolinger and J. Seel,
Utility-Scale Solar: Empirical Trends in Project Technology, Cost
Performance, and PPA Pricing in the United States – 2018 Edition
(Berkeley, CA: LBNL, September 2018), p. 5, https://emp.lbl.
gov/utility-scale-solar. However, most analysts, consultancies,
industry groups, the IEA and many others report data in DC, from
M. Schmela, SolarPower Europe, personal communication with
REN21, 11 May 2019. In addition, DC capacity more accurately
reflects the rating of panels, from C. Marcy, “Solar plants typically
install more panel capacity relative to their inverter capacity”,
Today in Energy, US Energy Information Administration (EIA),
16 March 2018, https://www.eia.gov/todayinenergy/detail.
php?id=35372. In order to maintain a consistent rating type
across all solar PV capacity, and because the AC capacity of
most countries is not available, GSR 2021 attempts to report all
solar PV data in DC units; in addition, the GSR aims to report only
capacity that has entered into operation by year’s end.
2 See, for example, “Coronavirus cuts PV demand; lower loads
lift operators’ share”, Reuters Events, 1 April 2020, https://
analysis.newenergyupdate.com/pv-insider/coronavirus-cuts-pv-
demand-lower-loads-lift-operators-share; N. T. Prasad, “Indian
solar industry confronts coronavirus crisis”, Mercom India, 27
March 2020, https://mercomindia.com/indian-solar-industry-
coronavirus-crisis; IEA, “2020 and 2021 forecast overview”, in
Renewable Energy Market Update: Outlook for 2020 and 2021
(Paris: May 2020), https://www.iea.org/reports/renewable-
energy-market-update/2020-and-2021-forecast-overview.
3 See, for example, “Coronavirus cuts PV demand, op. cit. note 2;
Prasad, op. cit. note 2; IEA, op. cit. note 2.
4 Below expectations in, for example, Europe, from SolarPower
Europe, EU Market Outlook for Solar Power 2020-2024 (Brussels:
December 2020), p. 3, https://www.solarpowereurope.org/
european-market-outlook-for-solar-power-2020-2024; Israel, from
IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, p.
15. Largest increases in capacity based on data for 2020, as noted
above, and historical data from IEA PVPS, Trends in Photovoltaic
Applications 2020, op. cit. note 1, p. 85.
5 BloombergNEF, “Household solar demand surges through the roof
in 2020”, 23 October 2020, https://about.bnef.com/blog/household-
solar-demand-surges-through-the-roof-in-2020; “Solar power
capacity in the U.S. will jump 43 percent this year”, New York Times,
15 December 2020, https://www.nytimes.com/live/2020/12/15/
business/us-economy-coronavirus#solar-power-capacity-in-
the-us-will-jump-43-percent-this-year. See also country-specific
information and sources below. The rooftop market grew particularly
in Vietnam, as well as in Australia, Germany and the United States,
from IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note
1, p. 12. Distributed definition in footnote from IEA PVPS, Trends in
Photovoltaic Applications 2019 (Paris: 2019), p. 9, https://iea-pvps.
org/trends_reports/2019-edition.
6 Top three markets from various sources cited throughout this
section, including IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1. Examples of other countries with noteworthy
expansion include Australia, Brazil, Germany, Japan, the
299
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https://iea-pvps.org/wp-content/uploads/2021/04/IEA_PVPS_Snapshot_2021-V3
https://iea-pvps.org/wp-content/uploads/2021/04/IEA_PVPS_Snapshot_2021-V3
https://iea-pvps.org/wp-content/uploads/2020/11/IEA_PVPS_Trends_Report_2020-1
https://iea-pvps.org/wp-content/uploads/2020/11/IEA_PVPS_Trends_Report_2020-1
https://www.pv-magazine.com/2021/02/23/bloombergnef-expects-up-to-209-gw-of-new-solar-for-this-year
https://www.pv-magazine.com/2021/02/23/bloombergnef-expects-up-to-209-gw-of-new-solar-for-this-year
https://www.iea.org/reports/renewable-energy-market-update-2021/renewable-electricity
https://www.iea.org/reports/renewable-energy-market-update-2021/renewable-electricity
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://energy.economictimes.indiatimes.com/news/renewable/solar-installations-on-pace-for-biggest-growth-in-five-years-ihs-markit-says/81755484
https://energy.economictimes.indiatimes.com/news/renewable/solar-installations-on-pace-for-biggest-growth-in-five-years-ihs-markit-says/81755484
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https://eta-publications.lbl.gov/sites/default/files/lbnl_utility_scale_solar_2019_edition_final
https://eta-publications.lbl.gov/sites/default/files/lbnl_utility_scale_solar_2019_edition_final
https://emp.lbl.gov/utility-scale-solar
https://emp.lbl.gov/utility-scale-solar
https://www.eia.gov/todayinenergy/detail.php?id=35372
https://www.eia.gov/todayinenergy/detail.php?id=35372
https://analysis.newenergyupdate.com/pv-insider/coronavirus-cuts-pv-demand-lower-loads-lift-operators-share
https://analysis.newenergyupdate.com/pv-insider/coronavirus-cuts-pv-demand-lower-loads-lift-operators-share
https://analysis.newenergyupdate.com/pv-insider/coronavirus-cuts-pv-demand-lower-loads-lift-operators-share
https://mercomindia.com/indian-solar-industry-coronavirus-crisis
https://mercomindia.com/indian-solar-industry-coronavirus-crisis
https://www.iea.org/reports/renewable-energy-market-update/2020-and-2021-forecast-overview
https://www.iea.org/reports/renewable-energy-market-update/2020-and-2021-forecast-overview
https://www.solarpowereurope.org/european-market-outlook-for-solar-power-2020-2024
https://www.solarpowereurope.org/european-market-outlook-for-solar-power-2020-2024
https://about.bnef.com/blog/household-solar-demand-surges-through-the-roof-in-2020
https://about.bnef.com/blog/household-solar-demand-surges-through-the-roof-in-2020
https://www.nytimes.com/live/2020/12/15/business/us-economy-coronavirus#solar-power-capacity-in-the-us-will-jump-43-percent-this-year
https://www.nytimes.com/live/2020/12/15/business/us-economy-coronavirus#solar-power-capacity-in-the-us-will-jump-43-percent-this-year
https://www.nytimes.com/live/2020/12/15/business/us-economy-coronavirus#solar-power-capacity-in-the-us-will-jump-43-percent-this-year
https://iea-pvps.org/trends_reports/2019-edition
https://iea-pvps.org/trends_reports/2019-edition
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Netherlands, Poland, the Republic of Korea and the Russian
Federation; see information and sources throughout this section.
Figure 25 based on historical data from IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1, pp. 84-85, from IEA
PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, and
from Becquerel Institute, op. cit. note 1.
7 See, for example, IEA, World Energy Outlook 2020, Executive
Summary (Paris: 2020), p. 18, https://iea.blob.core.windows.net/
assets/80d64d90-dc17-4a52-b41f-b14c9be1b995/WEO2020_
ES.PDF. According to the IEA, “solar PV is consistently cheaper
than new coal- or gas-fired power plants in most countries”, from
idem. See also, for example, SolarPower Europe, Global Market
Outlook for Solar Power, 2019-2023 (Brussels: 2019), pp. 9, 13, https://
www.solarpowereurope.org/global-market-outlook-2019-2023;
IRENA, Renewable Power Generation Costs in 2018 (Abu Dhabi:
2019), p. 9, https://www.irena.org/-/media/Files/IRENA/Agency/
Publication/2019/May/IRENA_Renewable-Power-Generations-
Costs-in-2018 ; B. Eckhouse, “Solar and wind cheapest source
of power in most of the world”, Bloomberg, 28 April 2020, https://
www.bloomberg.com/news/articles/2020-04-28/solar-and-wind-
cheapest-sources-of-power-in-most-of-the-world; M. Brown, “Solar
vs. coal: Why the ’74 percent report’ signals a new era for US energy”,
Inverse, 28 March 2019, https://www.inverse.com/article/54399-
solar-energy-cheaper-than-coal-whats-next; https://www.nature.
com/articles/s41560-019-0441-z; J. Weaver, “Solar price declines
slowing, energy storage in the money”, pv magazine, 8 November
2019, https://pv-magazine-usa.com/2019/11/08/sola-price-
declines-slowing-energy-storage-in-the-money; M. Hutchins, “Solar
‘could soon be UK’s cheapest source of energy’”, pv magazine, 12
December 2018, https://www.pv-magazine.com/2018/12/12/solar-
could-soon-be-uks-cheapest-source-of-energy; K. Samanta, “India’s
renewable energy cost lowest in Asia Pacific: WoodMac”, Reuters,
29 July 2019, https://www.reuters.com/article/us-india-renewables-
woodmac/indias-renewable-energy-cost-lowest-in-asia-pacific-
woodmac-idUSKCN1UO0L8; J. Yan et al., “City-level analysis of
subsidy-free solar photovoltaic electricity price, profits and grid
parity in China”, Nature Geoscience (2019), cited in J. Gabbatiss,
“Solar now ‘cheaper than grid electricity’ in every Chinese city, study
finds”, CarbonBrief, 12 August 2019, https://www.carbonbrief.org/
solar-now-cheaper-than-grid-electricity-in-every-chinese-city-
study-finds.
8 N. Ford, “Europe solar-storage costs fall below markets
as learnings kick in”, New Energy Update, 2 October
2019, https://analysis.newenergyupdate.com/pv-insider/
europe-solar-storage-costs-fall-below-markets-learnings-kick.
9 Figure of 20 in 2020 from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, p. 7; up from 18 countries (Australia, Brazil,
China, Chinese Taipei, Egypt, Germany, India, Japan, the Republic
of Korea, Mexico, the Netherlands, Pakistan, South Africa, Spain,
Ukraine, the United Arab Emirates, the United States and Vietnam)
in 2019 based on preliminary estimates from IEA PVPS, Snapshot
of Global PV Markets 2020 (Paris: April 2020), p. 4, https://iea-pvps.
org/wp-content/uploads/2020/04/IEA_PVPS_Snapshot_2020.
pdf, and on data from Becquerel Institute, op. cit. note 1, 10 April
2020. Note that 16 countries added over 1 GW in 2019, up from 11 in
2018 and 9 in 2017, from SolarPower Europe, Global Market Outlook
for Solar Power 2020-2024 (Brussels: 2020), p. 5, https://www.
solarpowereurope.org/global-market-outlook-2020-2024; up from
10 countries in 2018 from IEA PVPS, Snapshot of Global PV Markets
2020, op. cit. this note, p. 9; nine countries in 2017 from IEA PVPS,
Trends in Photovoltaic Applications 2018: Survey Report of Selected
IEA Countries Between 1992 and 2017 (Paris: 2018), p. 3, http://www.
iea-pvps.org/fileadmin/dam/public/report/statistics/2018_iea-
pvps_report_2018 ; seven countries in 2016 from SolarPower
Europe, Global Market Outlook for Solar Power 2018-2022 (Brussels:
2018), p. 5, https://www.solarpowereurope.org/wp-content/
uploads/2018/09/Global-Market-Outlook-2018-2022 .
10 Figure of 42 countries at end of 2020 based on data from IEA
PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1,
and from Becquerel Institute, op. cit. note 1. This was up from
40 countries in 2019, from IEA PVPS, Trends in Photovoltaic
Applications 2020, op. cit. note 1, p. 4. As of the end of 2020, an
estimated 95 countries had at least 10 MW of solar PV capacity
installed, from F. Jackson, “Solar soars as emerging markets
renewables investment hits record high”, Forbes, 9 December
2020, https://www.forbes.com/sites/feliciajackson/2020/12/09/
solar-soars-as-emerging-markets-renewables-investment-hits-
record-high.
11 IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1,
p. 16. Based on cumulative capacity in operation at end-2019
and assumes close to optimum siting, orientation and long-term
average weather conditions, from idem.
12 Honduras sourced 11.2% of its net electricity generation from
solar PV, based on data from Empresa Nacional de Energía
Eléctrica, p. 7, Boletín Estadístico – Diciembre 2020 (Tegucigalpa:
2020), http://www.enee.hn/planificacion/2021/12%20diciembre.
pdf. Germany’s share of electricity production was 10.5% in
2020 (up from 9% in 2019), from Fraunhofer ISE, “Annual solar
share of electricity production in Germany”, Energy-Charts,
https://energy-charts.info/charts/renewable_share/chart.
htm?l=en&c=DE&share=solar_share&interval=year, updated
24 April 2021; solar PV generation accounted for 9.2% of
Germany’s gross electricity consumption in 2020 (up from 8.0%
in 2019), from Federal Ministry for Economic Affairs and Energy
(BMWi) and Arbeitsgruppe Erneuerbare Energien-Statistik
(AGEE-Stat), Time Series for the Development of Renewable
Energy Sources in Germany, Based on Statistical Data from the
Working Group on Renewable Energy-Statistics (AGEE-Stat)
(Status: February 2021) (Dessa-Roßlau: February 2021), pp. 45,
46, https://www.erneuerbare-energien.de/EE/Navigation/DE/
Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.
html. Greece based on4,392 GWh of solar PV generation
(including 494 GWh from rooftop systems) and 42,230 GWh
of total electricity generation, from multiple original sources,
all in Greek (including Manager of Renewable Energy Sources
and Guarantees of Origin (DAPEEP SA), Μηνιαίο Δελτίο Ειδικού
ΛογαριασμούΑΠΕ & ΣΗΘΥΑ, 2021, p. 15, https://www.dapeep.
gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_
ELAPE_v1.0_21.03.2021 , and total generation, based on
data from the Greek Independent Power Transmission Operator
(ADMIE), ΜΗΝΙΑΙΟΔΕΛΤΙΟ ΕΝΕΡΓΕΙΑΣ, 2021, pp. 3, 12, 13,
24, 35, https://www.admie.gr/sites/default/files/attached-
files/type-file/2021/03/Energy_Report_202012_v2 , and
provided by I. Tsipouridis, REDPro Consultants, Athens, personal
communication with REN21, April 2021. Australia from Clean
Energy Council, Clean Energy Australia Report 2021 (Melbourne:
April 2021), p. 9, https://assets.cleanenergycouncil.org.au/
documents/resources/reports/clean-energy-australia/clean-
energy-australia-report-2021 . Chile share of generation from
Asociación Chilena de Energías Renovables y Almacenamiento
AG. (ACERA), Estadísticas Sector de Generación de Energía
Eléctrica Renovable (December 2020), p. 1, https://acera.cl/
wp-content/uploads/2021/01/2020-12-Bolet%C3%ADn-
Estad%C3%ADsticas-ACERA . Italy generated 25,549 GWh
of electricity with solar PV in 2020, and total net production in
the system was 273,108 GWh, for a solar PV share of 9.35%, from
Terna, Rapporto mensile sul Sistema Elettrico December 2020
(Rome: 2020), p. 9, https://download.terna.it/terna/Rapporto_
Mensile_Dicembre%202020_8d8b615dca4dafe . Japan
from Institute for Sustainable Energy Policies (ISEP), “Share of
electricity generated from renewable energy in 2020 (preliminary
report)”, 12 April 2021, https://www.isep.or.jp/en/1075.
13 Spain and United Kingdom from J. Parnell, “Clean air, clear skies
and fresh megawatts cause Europe’s solar records to tumble”,
Greentech Media, 22 April 2020, https://www.greentechmedia.
com/articles/read/clean-air-clear-skies-and-fresh-megawatts-
see-europes-solar-records-tumble; T. Barrett, “Less air pollution
helps UK solar break generation record”, Air Quality News, 23 April
2020, https://airqualitynews.com/2020/04/23/less-air-pollution-
helps-uk-solar-generation-break-generation-record; S. Vorrath,
“Solar generation in Delhi ‘clearly’ boosted by clear skies of Covid
lockdown”, RenewEconomy, 29 June 2020, https://reneweconomy.
com.au/solar-generation-in-delhi-clearly-boosted-by-clear-skies-
of-covid-lockdown-22289; United Arab Emirates from Middle East
Solar Industry Association (MESIA), Solar Outlook Report 2021
(Dubai: January 2021), p. 14, https://mesia.com/information-center/
research-papers-reports. Note that sources also mention Germany,
from J. Parnell, op. cit. this note, and from S. Hanley, “Clear skies over
Germany lead to record amount of solar energy”, CleanTechnica, 22
April 2020, https://cleantechnica.com/2020/04/22/clear-skies-over-
germany-lead-to-record-amount-of-solar-energy, but it appears
that additional capacity was the main driver, along with generally
sunny skies throughout the year, because output and capacity
both increased by about the same percentage, from S. Hermann,
German Environment Agency, Germany, personal communication
with REN21, 13 April 2021. Also note that solar output declined in
the United Kingdom for all of 2020, down 0.9% relative to 2019,
from UK Department for Business, Energy & Industrial Strategy
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https://acera.cl/wp-content/uploads/2021/01/2020-12-Bolet%C3%ADn-Estad%C3%ADsticas-ACERA
https://download.terna.it/terna/Rapporto_Mensile_Dicembre%202020_8d8b615dca4dafe
https://download.terna.it/terna/Rapporto_Mensile_Dicembre%202020_8d8b615dca4dafe
https://www.isep.or.jp/en/1075
https://www.greentechmedia.com/articles/read/clean-air-clear-skies-and-fresh-megawatts-see-europes-solar-records-tumble
https://www.greentechmedia.com/articles/read/clean-air-clear-skies-and-fresh-megawatts-see-europes-solar-records-tumble
https://www.greentechmedia.com/articles/read/clean-air-clear-skies-and-fresh-megawatts-see-europes-solar-records-tumble
https://airqualitynews.com/2020/04/23/less-air-pollution-helps-uk-solar-generation-break-generation-record
https://airqualitynews.com/2020/04/23/less-air-pollution-helps-uk-solar-generation-break-generation-record
https://reneweconomy.com.au/solar-generation-in-delhi-clearly-boosted-by-clear-skies-of-covid-lockdown-22289
https://reneweconomy.com.au/solar-generation-in-delhi-clearly-boosted-by-clear-skies-of-covid-lockdown-22289
https://reneweconomy.com.au/solar-generation-in-delhi-clearly-boosted-by-clear-skies-of-covid-lockdown-22289
https://mesia.com/information-center/research-papers-reports
https://mesia.com/information-center/research-papers-reports
https://cleantechnica.com/2020/04/22/clear-skies-over-germany-lead-to-record-amount-of-solar-energy
https://cleantechnica.com/2020/04/22/clear-skies-over-germany-lead-to-record-amount-of-solar-energy
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(BEIS), Energy Trends – UK, October to December 2020 and 2020
(London: 25 March 2021), p. 17, https://assets.publishing.service.
gov.uk/government/uploads/system/uploads/attachment_data/
file/972790/Energy_Trends_March_2021 .
14 California output from E. F. Merchant, “California’s wildfires
hampered solar energy production in September”, Greentech
Media, 1 October 2020, https://www.greentechmedia.com/
articles/read/wildfires-in-california-undercut-solar-production-
in-september, and from S. York, “Smoke from California wildfires
decreases solar generation in CAISO”, Today in Energy, US
EIA, 30 September 2020, https://www.eia.gov/todayinenergy/
detail.php?id=45336. California variability and forecasting
from California Independent System Operator (CAISO), cited
in Merchant, op. cit. this note. In California, generation from
large-scale solar projects (including concentrating solar power
output) in the service territory of CAISO (which covers 90% of the
state’s utility solar capacity) in the first two weeks of September
fell almost 30% below the July average, and 13% year-over-year,
despite increased capacity, due to the increase in airborne
particulate matter during wildfires, from Merchant, op. cit. this
note, and York, op. cit. this note. Australia from Solar Trust Centre
Team, “Understanding bushfires and their effect on solar output”,
Solar Trust Centre, 9 January 2020, https://solartrustcentre.com.
au/understanding-bushfires-and-their-effect-on-solar-output.
15 SolarPower Europe, op. cit. note 4; IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1; IEA PVPS, Trends
in Photovoltaic Applications 2019, op. cit. note 5, p. 91; grid
infrastructure from IEA PVPS and Becquerel Institute, op. cit.
note 1, 20 February 2020, from P. Mints, SPV Market Research,
The Solar Flare, no. 4 (31 August 2019), pp. 8, 10, and from
information and sources throughout this section. Financial and
bankability challenges are issues of concern particularly in sub-
Saharan Africa, from J. Nyokabi, Green Energy, Kenya, personal
communication with REN21, 2 April 2021.
16 IEA PVPS, Trends in Photovoltaic Applications 2020, op. cit.
note 1, pp. 34-35.
17 Lower than a decade ago but challenges remain, fossil and
nuclear, from Masson, op. cit. note 1, 20 February 2020, 4 May
2020 and 9 March 2021; IEA PVPS, Snapshot of Global PV
Markets 2021, op. cit. note 1, p. 17. Regarding utilities, in Brazil,
for example, utilities have restricted approval and authorization
of solar PV systems, saying that they lack the capacity to make
grid connections, to integrate solar energy into the grid, among
other things, from R. Baitelo, Associação Brasileira de Energia
Solar Fotovoltaica (ABSOLAR), personal communication with
REN21, 7 April 2020; in India, distribution companies have
pressured policy makers to remove net metering policies and
adopt grid usage charges, from Bridge to India, “Bridge to India
webinar – India rooftop solar policy round up”, email received
2 December 2020. In Australia, the energy market operator has
largely prevented attempts by electricity network operators to
discriminate against and financially penalise solar customers,
but in past years network operators have imposed delays and
conditions on the approval of grid connections, which leads to
increases in the soft costs of solar deployment, from IEA PVPS,
Australian Photovoltaic Institute (APVI) and Australian Renewable
Energy Agency (ARENA), National Survey Report of PV Power
Applications in Australia 2018 (Paris: 2019), prepared by R. Egan,
APVI, p. 36, https://iea-pvps.org/wp-content/uploads/2020/01/
NSR_Australia_2018 .
18 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 5.
19 IEA PVPS, Trends in Photovoltaic Applications 2020, op. cit. note 1,
pp. 27, 56; IEA PVPS, Trends in Photovoltaic Applications 2019, op. cit.
note 5, pp. 48-56; Masson, op. cit. note 1, 9 March and 25 May 2021.
20 IEA PVPS, Trends in Photovoltaic Applications 2020, op. cit. note
1, p. 28. US tax credits continued to play an important role, from
Masson, op. cit. note 1, 9 March 2021.
21 IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1,
p. 17, and information and sources throughout this section.
22 Masson, op. cit. note 1, 9 March 2021. In 2020, perhaps 20-30%
of the market was installed without direct government incentives,
although this does include some tenders that do not provide
direct subsidies, from idem. Overall, about 5% of the market
volume in 2019 was independent of government support schemes
or “adequate regulatory framework”, from IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1, p. 28.
23 Eighth consecutive year based on data from IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1, and from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1; Asia’s share of
additions and share without China, based on data from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1.
24 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
25 Market and manufacturing from SolarPower Europe, Global
Market Outlook for Solar Power, 2019-2023, op. cit. note 7, p.
89; share of additions in 2020 based on data from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1; share of additions in 2019
based on data from IEA PVPS, Trends in Photovoltaic Applications
2020, op. cit. note 1, p. 85. China’s share was 44% in 2018 (and
52% in 2017) from SolarPower Europe, Global Market Outlook
for Solar Power, 2019-2023, op. cit. note 7, p. 89; China’s share of
total demand was 27% in 2014, 30% in 2015, 49% in 2016, 56% in
2017, 42% in 2018 and projected 29% in 2019, from P. Mints, SPV
Market Research, The Solar Flare, no. 5 (31 October 2019), p. 5.
26 Top 10 countries, share of top 5 in 2020 and less concentrated
based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note
1; share in 2019 based on data from IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1, pp. 12, 85. The share
represented by the top 5 in 2018 was about 75%, from Becquerel
Institute, op. cit. note 1, 10 May 2019, and from IEA PVPS, 2019
Snapshot of Global PV Markets (Paris: April 2019), p. 8, http://
www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA-
PVPS_T1_35_Snapshot2019-Report . The share represented
by the top 5 in 2017 was 84%, based on global additions of at
least 98 GWDC, and on additions of the top five countries (China,
the United States, India, Japan and Turkey), from IEA PVPS,
Snapshot of Global Photovoltaic Markets 2018 (Paris: 2018), p. 4,
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/
IEA_PVPS-A_Snapshot_of_Global_PV-1992-2017 .
27 Figure for 2020 based on data of top 10 countries provided
throughout this section. The figure for 2019 was 3.1 GW, based on
data from IEA PVPS, Trends in Photovoltaic Applications 2020, op.
cit. note 1, p. 85. This was up from 1.3 GW in 2018, from Becquerel
Institute, op. cit. note 1, 10 May 2019, and from IEA PVPS, 2019
Snapshot of Global PV Markets, op. cit. note 26, p. 7, and from
954 MW in 2017, 683 MW in 2016, and 675 MW in 2015, all based
on data from IEA PVPS, Trends in Photovoltaic Applications 2018,
op. cit. note 9, p. 13.
28 Leading countries for total capacity based on data from IEA
PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, and
from Becquerel Institute, op. cit. note 1; leaders for capacity per
inhabitant from IEA PVPS, Snapshot of Global PV Markets 2021,
op. cit. note 1, p. 7. Figure 26 based on global and country-
specific historical data from IEA PVPS, Trends in Photovoltaic
Applications 2020, op. cit. note 1, from IEA PVPS, Snapshot of
Global PV Markets 2021, op. cit. note 1, from Becquerel Institute,
op. cit. note 1, and based on country-specific 2020 data and
sources provided throughout this section for China, India, Japan
and the United States. EU data for all years from Becquerel
Institute, op. cit. note 1, 26 May 2021. India data from the following:
data for 2010 and 2011 from European Photovoltaic Industry
Association (EPIA), Global Market Outlook for Photovoltaics Until
2016 (Brussels: May 2012), p. 14, https://www.helapco.gr/pdf/
Global_Market_Outlook_2015_-2019_lr_v23 ; data for 2012
from IEA PVPS, PVPS Report, A Snapshot of Global PV 1992-2012
(Paris: 2013), http://www.iea-pvps.org/fileadmin/dam/public/
report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-
_1992-2012_-_FINAL_4 ; data for 2013 from IEA-PVPS,
PVPS Report – Snapshot of Global PV 1992-2013: Preliminary
Trends Information from the IEA PVPS Programme (Paris: March
2014), http://www.iea-pvps.org/fileadmin/dam/public/report/
statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-
2013_-_final_3 ; data for 2014 from Bridge to India, May 2015,
provided by S. Orlandi, Becquerel Institute, Brussels, personal
communication with REN21, 11 May 2015; data for 2015 from IEA
PVPS, Trends in Photovoltaic Applications, 2016: Survey Report
of Selected IEA Countries Between 1992 and 2015 (Paris: 2016),
http://www.iea-pvps.org/fileadmin/dam/public/report/national/
Trends_2016_-_mr ; data for 2016 from Government of India,
Ministry of New and Renewable Energy (MNRE), “Physical
progress (achievements)”, data as on 31 December 2016,
http://www.mnre.gov.in/mission-and-vision-2/achievements,
301
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972790/Energy_Trends_March_2021
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972790/Energy_Trends_March_2021
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972790/Energy_Trends_March_2021
https://www.greentechmedia.com/articles/read/wildfires-in-california-undercut-solar-production-in-september
https://www.greentechmedia.com/articles/read/wildfires-in-california-undercut-solar-production-in-september
https://www.greentechmedia.com/articles/read/wildfires-in-california-undercut-solar-production-in-september
https://www.eia.gov/todayinenergy/detail.php?id=45336
https://www.eia.gov/todayinenergy/detail.php?id=45336
https://solartrustcentre.com.au/understanding-bushfires-and-their-effect-on-solar-output
https://solartrustcentre.com.au/understanding-bushfires-and-their-effect-on-solar-output
https://iea-pvps.org/wp-content/uploads/2020/01/NSR_Australia_2018
https://iea-pvps.org/wp-content/uploads/2020/01/NSR_Australia_2018
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA-PVPS_T1_35_Snapshot2019-Report
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA-PVPS_T1_35_Snapshot2019-Report
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA-PVPS_T1_35_Snapshot2019-Report
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA_PVPS-A_Snapshot_of_Global_PV-1992-2017
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/IEA_PVPS-A_Snapshot_of_Global_PV-1992-2017
https://www.helapco.gr/pdf/Global_Market_Outlook_2015_-2019_lr_v23
https://www.helapco.gr/pdf/Global_Market_Outlook_2015_-2019_lr_v23
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2012_-_FINAL_4
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2012_-_FINAL_4
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2012_-_FINAL_4
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2013_-_final_3
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2013_-_final_3
http://www.iea-pvps.org/fileadmin/dam/public/report/statistics/PVPS_report_-_A_Snapshot_of_Global_PV_-_1992-2013_-_final_3
http://www.iea-pvps.org/fileadmin/dam/public/report/national/Trends_2016_-_mr
http://www.iea-pvps.org/fileadmin/dam/public/report/national/Trends_2016_-_mr
http://www.mnre.gov.in/mission-and-vision-2/achievements
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viewed 19 January 2017; data for 2017 and 2018 from IEA PVPS
and Becquerel Institute, op. cit. note 1, 3 June 2019 and 4 May
2020; and data for 2019, from IEA PVPS, Trends in Photovoltaic
Applications 2020, op. cit. note 1, p. 10.
29 China added 48.2 GW for a total of 253.4 GW, from China
National Energy Administration (NEA), “National Energy
Administration releases 2020 national power industry
statistics”, 20 January 2021, http://www.nea.gov.cn/2021-
01/20/c_139683739.htm (using Google Translate); added 48.2
GW (including 32.68 GW in centralised power stations and 15.52
GW in distributed systems) in 2020 for a year-end total of 253
GW, from National Energy Board, cited in NEA, “Transcript of the
online press conference of the National Energy Administration in
the first quarter of 2021”, 30 January 2021, http://www.nea.gov.
cn/2021-01/30/c_139708580.htm (using Google Translate); and
added 48.2 GW for a total of 253.4 GW from IEA PVPS, Snapshot
of Global PV Markets 2021, op. cit. note 1, and from Becquerel
Institute, op. cit. note 1. Second only to 2017 based on data from
IEA PVPS, Trends in Photovoltaic Applications 2020, op. cit. note
1, p. 85. Distributed solar PV in China description in footnote
based on the following: F. Haugwitz, Asia Europe Clean Energy
(Solar) Advisory Co. Ltd. (AECEA), personal communication
with REN21, 22 April 2019; AECEA, “Briefing Paper – China
Solar PV Development”, September 2017 (provided by Haugwitz,
AECEA); AECEA, “China 2017 – what a year with 53 GW of added
solar PV! What’s in for 2018!” Briefing Paper – China Solar PV
Development, January 2018 (provided by Haugwitz, AECEA); A.
Rajeshwari, “China’s solar PV installations reach almost 10 GW
in Q1 of 2018”, Mercom India, 26 April 2018, https://mercomindia.
com/china-solar-10gw-q1-2018.
30 Increase of 60% based on 48.2 GW added in 2020 and on
30.1 GW added in 2019, from IEA PVPS, Trends in Photovoltaic
Applications 2020, op. cit. note 1. Two years of contraction based
on additions 52.86 GW in 2017, followed by annual additions of
44.26 GW in 2018 and 30.1 GW in 2019, from IEA PVPS, Trends
in Photovoltaic Applications 2020, op. cit. note 1, p. 85. Delays
and disruptions, from EurObserv’ER, Photovoltaic Barometer
(Paris: April 2020), p. 4, https://www.eurobserv-er.org/category/
all-photovoltaic-barometers. China’s solar PV market contracted
in 2018 and 2019 because the government temporarily halted
subsidy allocations and announced (in 2018) a transition to
auctions. In 2020, projects awarded under competitive auctions
in mid-2019 and mid-2020 (when almost 26 GW was awarded)
were coming online before the phase-out of subsidies for all but
residential applications at end of 2020. Residential systems are to
receive financial support through the end of 2021, from IEA, “Solar
PV”, in Renewables 2020 (Paris: 2020), https://www.iea.org/
reports/renewables-2020/solar-pv.
31 National Energy Board, op. cit. note 29.
32 “Multi-pictures: Overview of the details of photovoltaic and wind
power installed capacity and power generation in various provinces
across the country”, 360doc.com, 17 February 2021, http://www.
360doc.com/content/21/0217/07/73752269_962367138.shtml
(using Google Translate).
33 Year-end total of 253.4 GW, from China NEA, op. cit. note 29,
from IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note
1, and from Becquerel Institute, op. cit. note 1; total of 253 GW,
from National Energy Board, op. cit. note 29. Total grid-connected
capacity increased from 204,180 MW in 2019 to 253,430 MW at
end-2020, a net increase of 49,250 MW, from official data and
based on 204,180 MW of grid-connected capacity in operation
at end of 2019 and 253,430 MW in operation at end of 2020,
from China Electricity Council (CEC), cited in China Energy
Portal, “2020 electricity & other energy statistics (preliminary)”,
22 January 2021, https://chinaenergyportal.org/en/2020-
electricity-other-energy-statistics-preliminary. Note that data are
preliminary and based on grid-connected capacity; in addition,
“Due to differences in statistical standards, confirmation of
moment of grid connection, and other reasons, there are certain
discrepancies in data on total and newly installed generation
capacity”, from CEC, cited in idem. Target for 2020 from
Haugwitz, op. cit. note 29, 4 January 2021.
34 IEA, op. cit. note 30.
35 Deficit and backlog from Everchem, “Chinese wind subsidies to
end in December China’s renewable power price and subsidy:
‘new’ design in 2020?” 28 October 2020/29 January 2020, https://
everchem.com/chinese-wind-subsidies-to-end-in-december;
worsened by pandemic and subsidy free from G. Baiyu, “Despite
coronavirus, China aims for renewables grid parity”, China
Dialogue, 2 June 2020, https://chinadialogue.net/en/energy/
despite-coronavirus-china-aims-for-renewables-grid-parity.
The cumulative deficit for all renewables amounted to the
equivalent of USD 50 billion at the end of 2020, from Credit
Suisse, cited in J. Wong, “China’s green-power funding is blowing
in the wind”, Wall Street Journal, 21 April 2021, https://www.
wsj.com/articles/chinas-green-power-funding-is-blowing-in-
the-wind-11619003815. One source notes that wind and solar
power projects benefit from lower technology costs, but other
costs – such as curtailment, taxes on land, financing and initial
development – remain high (accounting for 20% or more of wind
and solar power project costs) and are barriers to grid parity, from
Baiyu, op. cit. this note.
36 Based on additions of 32.7 GW in 2020, from China NEA,
provided by Haugwitz, op. cit. note 29, 25 February 2021, and
on additions of 17.9 GW in 2019, from China NEA, “PV grid-
connected operation in 2019”, 28 February 2020, http://www.nea.
gov.cn/2020-02/28/c_138827923.htm (using Google Translate).
37 “China’s great energy shift sets mega hybrid plants
in motion”, Bloomberg, 12 May 2020, https://
www.bloomberg.com/news/articles/2020-05-12/
china-s-great-energy-shift-sets-mega-hybrid-projects-in-motion.
38 Z. Shahan, “China’s largest solar-plus-storage project goes
online”, CleanTechnica, 1 October 2020, https://cleantechnica.
com/2020/10/01/chinas-largest-solar-plus-storage-project-
goes-online; E. Bellini, “World’s largest solar plant goes online
in China — 2.2 GW”, pv magazine, 2 October 2020, https://
pv-magazine-usa.com/2020/10/02/worlds-largest-solar-plant-
goes-online-in-china; G. Wilson, “Sungrow connects China’s
largest solar-plus-storage project”, Business Chief, 30 September
2020, https://medium.com/business-chief/sungrow-connects-
chinas-largest-solar-plus-storage-project-565f73faf3bc.
39 Based on additions of 15.5 GW in 2020 (10.1 GW residential and
5.4 GW commercial and industrial), from China NEA, provided
by Haugwitz, op. cit. note 29, 25 February 2021, and on additions
of 12.2 GW in 2019 (5.3 GW residential and 6.9 GW commercial
and industrial), from China NEA, “PV grid-connected operation in
2019”, op. cit. note 36.
40 Haugwitz, op. cit. note 29, 4 January 2021.
41 Figure of 2% national average curtailment in 2020, from China
NEA, provided by Haugwitz, op. cit. note 29; unchanged from
2019 from China NEA, “PV grid-connected operation in 2019”,
op. cit. note 36; national electricity consumption was down 6.5%
in the first quarter of 2020, with curtailment reaching 2.8% in
January and 5.6% in February, from Haugwitz, op. cit. note 29, 14
June 2020.
42 National Energy Board, op. cit. note 29. Curtailment in Xinjiang fell
4.6% relative to 2019, down 2.8 percentage points, and in Gansu
it fell 2.2%, down 2.0 percentage points, and across the entire
region it declined to 4.8%, a year-on-year decrease of 1.1%, from
idem.
43 Haugwitz, op. cit. note 29, 14 June 2020.
44 Based on total power production of 7,623,600 GWh and total solar
production of 261,100 GWh (grid-connected capacity) in 2020,
for a share of 3.4%, from CEC, cited in China Energy Portal, op.
cit. note 33. This was up from just over 3% in 2019, based on total
annual generation of 7,326,900 GWh and solar PV generation
of 224,000 GWh, from idem. Note that, “Due to differences in
statistical standards, confirmation of moment of grid connection,
and other reasons, there are certain discrepancies in data on total
and newly installed generation capacity”, from CEC, cited in idem.
Generation from solar PV was 260.5 TWh in 2020, from National
Energy Board, op. cit. note 29. Also, note that China’s solar data
likely includes some generation from concentrating solar thermal
power projects, but that is relatively small compared to solar PV.
See CSP section in this chapter.
45 Central government from China NEA guidance, provided by
Haugwitz, op. cit. note 29, 25 February 2021. Governments at
all levels from Haugwitz, op. cit. note 29, 7 September 2020. For
example, Shaanxi province was offering subsidies for solar PV
combined with electrical energy storage, from Haugwitz, op. cit.
note 29, 25 February 2021.
46 Haugwitz, op. cit. note 29, 14 November 2020. Provincial and local
governments also strengthened existing policies and introduced
new ones to support solar PV, particularly distributed systems. In
January 2020 alone, 18 solar PV support policies were released
302
http://www.nea.gov.cn/2021-01/20/c_139683739.htm
http://www.nea.gov.cn/2021-01/20/c_139683739.htm
http://www.nea.gov.cn/2021-01/30/c_139708580.htm
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https://chinadialogue.net/en/energy/despite-coronavirus-china-aims-for-renewables-grid-parity
https://chinadialogue.net/en/energy/despite-coronavirus-china-aims-for-renewables-grid-parity
https://www.wsj.com/articles/chinas-green-power-funding-is-blowing-in-the-wind-11619003815
https://www.wsj.com/articles/chinas-green-power-funding-is-blowing-in-the-wind-11619003815
https://www.wsj.com/articles/chinas-green-power-funding-is-blowing-in-the-wind-11619003815
http://www.nea.gov.cn/2020-02/28/c_138827923.htm
http://www.nea.gov.cn/2020-02/28/c_138827923.htm
https://www.bloomberg.com/news/articles/2020-05-12/china-s-great-energy-shift-sets-mega-hybrid-projects-in-motion
https://www.bloomberg.com/news/articles/2020-05-12/china-s-great-energy-shift-sets-mega-hybrid-projects-in-motion
https://www.bloomberg.com/news/articles/2020-05-12/china-s-great-energy-shift-sets-mega-hybrid-projects-in-motion
https://cleantechnica.com/2020/10/01/chinas-largest-solar-plus-storage-project-goes-online
https://cleantechnica.com/2020/10/01/chinas-largest-solar-plus-storage-project-goes-online
https://cleantechnica.com/2020/10/01/chinas-largest-solar-plus-storage-project-goes-online
https://pv-magazine-usa.com/2020/10/02/worlds-largest-solar-plant-goes-online-in-china
https://pv-magazine-usa.com/2020/10/02/worlds-largest-solar-plant-goes-online-in-china
https://pv-magazine-usa.com/2020/10/02/worlds-largest-solar-plant-goes-online-in-china
https://medium.com/business-chief/sungrow-connects-chinas-largest-solar-plus-storage-project-565f73faf3bc
https://medium.com/business-chief/sungrow-connects-chinas-largest-solar-plus-storage-project-565f73faf3bc
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across 14 provinces, with most of these related to distributed
solar; in March, several provincial governments released solar
PV policies and targets, all from Haugwitz, op. cit. note 29, 1 April
2020. In late 2020, several Chinese cities – including Beijing,
Shanghai, Guangzhou and Xian – enacted policies to support
solar PV; all of these except Beijing adopted feed-in tariffs, and
Beijing began offering investment subsidies, from Haugwitz, op.
cit. note 29, 25 February 2021.
47 Vietnam added 4.8 GW in 2019, from IEA PVPS, Trends in
Photovoltaic Applications 2020, op. cit. note 1; Vietnam’s
additions in 2018 and 2017 from M. Maisch, “Vietnam overtakes
Australia for commissioned utility scale solar following June
FIT rush”, pv magazine, 5 July 2019, https://www.pv-magazine.
com/2019/07/05/vietnam-overtakes-australia-for-commissioned-
utility-scale-solar-following-june-fit-rush; estimated total
additions in 2020 of 11.1 GW for a total of 16.4 GW, from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1; third and eighth place based
on data and sources provided throughout this section. Vietnam
installed 4,898 MW in 2019 and 11.5 GW in 2020, with rooftop
solar PV accounting for about 9 GW, from T. Ha, “Renewables
are booming in Vietnam. Will the upswing last?” Eco-Business,
13 April 2021, https://www.eco-business.com/news/renewables-
are-booming-in-vietnam-will-the-upswing-last; and Vietnam
had 4,898 MW in operation at the end of 2019 and an estimated
16,504 MW at the end of 2020, from IRENA, op. cit. note 1. Figure
27 based on historical global and country-specific data from IEA
PVPS, Trends in Photovoltaic Applications 2020, op. cit. note 1,
from IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note
1, and from Becquerel Institute, op. cit. note 1; and on country-
specific data and sources provided throughout this section.
48 Information for 2019 from, for example: E. A. Gunther, “Vietnam
rooftop solar records major boom as more than 9GW installed
in 2020”, PV-Tech, 6 January 2021, https://www.pv-tech.org/
vietnam-rooftop-solar-records-major-boom-as-more-than-9gw-
installed-in-2020; GlobalData Energy, “Vietnam’s solar drive”,
Power Technology, 30 July 2019, https://www.power-technology.
com/comment/vietnam-solar-drive; S. Djunisic, “B. Grimm brings
online 677 MW of solar in Vietnam”, Renewables Now, 17 June
2019, https://renewablesnow.com/news/bgrimm-brings-online-
677-mw-of-solar-in-vietnam-658285; Maisch, op. cit. note 47; T.
Kenning, “Close to 90 solar projects ‘sprinting’ for Vietnam’s June
FiT deadline”, PV-Tech, 20 May 2019, https://www.pv-tech.org/
news/close-to-90-solar-projects-sprinting-for-vietnams-june-fit-
deadline; developments in 2020 from Vietnam Electricity (EVN)
and the Viet Nam Energy Partnership Group, cited in Gunther, op.
cit. this note. The rooftop market accelerated throughout 2020
and saw a sharp rise in December to qualify for the FIT2 tariff
(USD 0.0838/kWh over 20 years for rooftop systems) before it
expired at year’s end, from idem.
49 Number of rooftop systems added in 2020 (82,900) and year-end
rooftop solar PV capacity of 9.7 GW, from EVN / National Load
Dispatch Centre of Vietnam (NLDC), provided by H. T. Tran,
Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ)
GmbH, Hanoi, personal communication with REN21, 11 April
2021; rooftop installations increased from a base of 378 MWDC
at the end of 2019 to 9,583 MW at end of 2020, with 6,708 GW
connected in December alone; at year’s end, total operating
capacity was 16,449 GWDC (13,160 GWAC), all from Vietnam
Ministry of Industry and Trade, notice dated 31 December 2020,
cited in Gunther, op. cit. note 48. Vietnam had installed a total of
more than 101,939 rooftop systems with capacity of 9.3 GW as of
4 January 2021, from Electricity of Vietnam, “Vietnam to be the
world’s top 3 PV market with installed capacity exceeding 10GW”,
Nangluon Vietnam, 18 March 2021, http://nangluongvietnam.vn/
news/en/nuclear-renewable/vietnam-to-be-the-worlds-top-3-pv-
market-with-installed-capacity-exceeding-10gw.html. Note that
total capacity at end-2020 was 19,400 MWDC, from EVN, “Rooftop
solar power boom is underway with a total installed capacity
reaching nearly 9,300 MWp”, press release (Hanoi: 1 January
2021), https://en.evn.com.vn/d6/news/Rooftop-solar-power-
boom-is-underway-with-a-total-installed-capacity-reaching-
nearly-9300-MWp-66-142-2169.aspx; was 18.5 GW at the end of
2020, from EVN/NLDC and provided by Tran, op. cit. this note,
and increased from 106 MWDC in 2018 to 19.4 GWDC at the end of
2020, from L. Stoker, “Unravelling the past, present and future of
solar policy in Vietnam”, PV-Tech, 17 March 2021, https://www.
pv-tech.org/unravelling-the-past-present-and-future-of-solar-
policy-in-vietnam.
50 To meet rising demand and figure of 10% from E. Bellini, “Vietnam
introduces auction scheme for large-scale PV”, pv magazine, 5
December 2019, https://www.pv-magazine.com/2019/12/05/
vietnam-introduces-auction-scheme-for-large-scale-pv;
population growth and economic expansion from GlobalData
Energy, op. cit. note 48; ensure energy security and reduce
carbon emissions from Ha, op. cit. note 47.
51 Ha, op. cit. note 47.
52 Rankings based on data from IEA PVPS, Snapshot of Global PV
Markets 2021, op. cit. note 1, and from Becquerel Institute, op.
cit. note 1. Japan had its best year since 2015, when the country
added 10,811 MW, based on data from IEA PVPS, Trends in
Photovoltaic Applications 2021, p. 85.
53 Four years of contraction based on data from IEA PVPS,
Trends in Photovoltaic Applications 2021, p. 85, and from
data of feed-in tariff scheme, Japanese Ministry of Economy,
Trade and Industry (METI), provided by H. Matsubara, ISEP,
Tokyo, personal communication with REN21, 14 April 2020;
additions in 2020 and year-end total from IEA PVPS, Snapshot
of Global PV Markets 2021, op. cit. note 1, and from Becquerel
Institute, op. cit. note 1; increase based on 2019 additions
from IEA PVPS, Trends in Photovoltaic Applications 2020, op.
cit.note 1, p. 85. Figure of 8.2 GWDC (6.3 GWAC) also from
RTS Corporation, cited in A. Bhambhani, “RTS Corporation
says in 2020, Japan grew annual solar PV capacity by 17%
to around 8.2 GWDC reaching cumulative of 71.7 GWDC”,
TaiyangNews, 20 January 2021, http://taiyangnews.info/markets/
japan-installed-8-gw-dc-new-solar-capacity-in-2020.
54 M. Hall, “Japan’s struggle to drive down renewables costs”,
pv magazine, 20 August 2020, https://www.pv-magazine.
com/2020/08/20/japans-struggle-to-drive-down-renewables-
costs; SolarPower Europe, op. cit. note 9, p. 80.
55 I. Kaizuka, “Agricultural PV emerges as Japan’s
next opportunity”, pv magazine, 2 June 2020,
https://www.pv-magazine.com/2020/06/02/
agricultural-pv-emerges-as-japans-next-opportunity.
56 ISEP, op. cit. note 12. Shares include self-consumption.
57 Half of 2019 additions based on 10 GW added in 2019 from IEA
PVPS, Trends in Photovoltaic Applications 2020, op. cit. note
1; lowest in five years from U. Gupta, “Tracking rooftop solar
trends in India”, pv magazine, 5 January 2021, https://www.
pv-magazine.com/2021/01/05/tracking-rooftop-solar-trends-
in-india. Investments fell 66% relative to 2019, to USD 2.8 billion
(nearly USD 1.19 billion for utility-scale and USD 356 million for
rooftop), from R. Ranjan, “Investments in the Indian solar sector
declined by 66% in 2020”, Mercom India, 1 March 2021, https://
mercomindia.com/investments-indian-solar-declined-2020.
58 IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, p. 10.
59 Based on preliminary data from IEA PVPS, Snapshot of Global PV
Markets 2021, op. cit. note 1, and from Becquerel Institute, op. cit.
note 1. IEA PVPS and Becquerel Institute use official estimates
(in AC) for ground-mounted capacity with a multiplier of 1.3 for
conversion of centralised capacity to DC; rooftop and off-grid
capacity are assumed to be in DC, from IEA PVPS and Becquerel
Institute, op. cit. note 1, 23 April 2020. India added 3,865.48 MW
in 2020 based on end-2019 capacity of 34,675.75MW and end-
2020 capacity of 38,541.23 MW (all a mix of AC and DC), from
Government of India, MNRE, “Physical progress – programme/
scheme wise physical progress in 2019-20 & cumulative upto
Dec, 2019”, https://mnre.gov.in/physical-progress-achievements,
viewed 9 January 2020, and data at end 2020 from Government
of India, MNRE, “Physical progress – programme/scheme
wise physical progress in 2020-21 & cumulative upto Dec,
2020”, https://mnre.gov.in/physical-progress-achievements,
viewed 3 February 2021. India’s year-end solar power capacity
was 37,464.6 MW (probably all in AC, although this is not
specified), from Government of India, Ministry of Power, Central
Electricity Authority (CEA), “All India installed capacity (in MW)
of power stations (as on 31.12.2020) (utilities)”, https://cea.nic.
in/wp-content/uploads/installed/2020/12/installed_capacity.
pdf. Totals from MNRE and CEA are for all solar power, including
off-grid solar PV, and also include some concentrating solar
thermal power (CSP) capacity; India’s CSP capacity is an
estimated 225 MW (see Concentrating Solar Thermal Power
section in this chapter for more details and sources). The top
states for total capacity at end-2020 were Karnataka (7.3 GW),
Rajasthan (5.4 GW) and Tamil Nadu (4.3 GW) (probably all in AC),
303
https://www.pv-magazine.com/2019/07/05/vietnam-overtakes-australia-for-commissioned-utility-scale-solar-following-june-fit-rush
https://www.pv-magazine.com/2019/07/05/vietnam-overtakes-australia-for-commissioned-utility-scale-solar-following-june-fit-rush
https://www.pv-magazine.com/2019/07/05/vietnam-overtakes-australia-for-commissioned-utility-scale-solar-following-june-fit-rush
https://www.eco-business.com/news/renewables-are-booming-in-vietnam-will-the-upswing-last
https://www.eco-business.com/news/renewables-are-booming-in-vietnam-will-the-upswing-last
https://www.pv-tech.org/vietnam-rooftop-solar-records-major-boom-as-more-than-9gw-installed-in-2020
https://www.pv-tech.org/vietnam-rooftop-solar-records-major-boom-as-more-than-9gw-installed-in-2020
https://www.pv-tech.org/vietnam-rooftop-solar-records-major-boom-as-more-than-9gw-installed-in-2020
https://www.power-technology.com/comment/vietnam-solar-drive
https://www.power-technology.com/comment/vietnam-solar-drive
https://renewablesnow.com/news/bgrimm-brings-online-677-mw-of-solar-in-vietnam-658285
https://renewablesnow.com/news/bgrimm-brings-online-677-mw-of-solar-in-vietnam-658285
https://www.pv-tech.org/news/close-to-90-solar-projects-sprinting-for-vietnams-june-fit-deadline
https://www.pv-tech.org/news/close-to-90-solar-projects-sprinting-for-vietnams-june-fit-deadline
https://www.pv-tech.org/news/close-to-90-solar-projects-sprinting-for-vietnams-june-fit-deadline
http://nangluongvietnam.vn/news/en/nuclear-renewable/vietnam-to-be-the-worlds-top-3-pv-market-with-installed-capacity-exceeding-10gw.html
http://nangluongvietnam.vn/news/en/nuclear-renewable/vietnam-to-be-the-worlds-top-3-pv-market-with-installed-capacity-exceeding-10gw.html
http://nangluongvietnam.vn/news/en/nuclear-renewable/vietnam-to-be-the-worlds-top-3-pv-market-with-installed-capacity-exceeding-10gw.html
https://en.evn.com.vn/d6/news/Rooftop-solar-power-boom-is-underway-with-a-total-installed-capacity-reaching-nearly-9300-MWp-66-142-2169.aspx
https://en.evn.com.vn/d6/news/Rooftop-solar-power-boom-is-underway-with-a-total-installed-capacity-reaching-nearly-9300-MWp-66-142-2169.aspx
https://en.evn.com.vn/d6/news/Rooftop-solar-power-boom-is-underway-with-a-total-installed-capacity-reaching-nearly-9300-MWp-66-142-2169.aspx
https://www.pv-tech.org/unravelling-the-past-present-and-future-of-solar-policy-in-vietnam
https://www.pv-tech.org/unravelling-the-past-present-and-future-of-solar-policy-in-vietnam
https://www.pv-tech.org/unravelling-the-past-present-and-future-of-solar-policy-in-vietnam
https://www.pv-magazine.com/2019/12/05/vietnam-introduces-auction-scheme-for-large-scale-pv
https://www.pv-magazine.com/2019/12/05/vietnam-introduces-auction-scheme-for-large-scale-pv
http://taiyangnews.info/markets/japan-installed-8-gw-dc-new-solar-capacity-in-2020
http://taiyangnews.info/markets/japan-installed-8-gw-dc-new-solar-capacity-in-2020
https://www.pv-magazine.com/2020/08/20/japans-struggle-to-drive-down-renewables-costs
https://www.pv-magazine.com/2020/08/20/japans-struggle-to-drive-down-renewables-costs
https://www.pv-magazine.com/2020/08/20/japans-struggle-to-drive-down-renewables-costs
https://www.pv-magazine.com/2020/06/02/agricultural-pv-emerges-as-japans-next-opportunity
https://www.pv-magazine.com/2020/06/02/agricultural-pv-emerges-as-japans-next-opportunity
https://www.pv-magazine.com/2021/01/05/tracking-rooftop-solar-trends-in-india
https://www.pv-magazine.com/2021/01/05/tracking-rooftop-solar-trends-in-india
https://www.pv-magazine.com/2021/01/05/tracking-rooftop-solar-trends-in-india
https://mercomindia.com/investments-indian-solar-declined-2020
https://mercomindia.com/investments-indian-solar-declined-2020
https://mnre.gov.in/physical-progress-achievements
https://mnre.gov.in/physical-progress-achievements
https://cea.nic.in/wp-content/uploads/installed/2020/12/installed_capacity .
https://cea.nic.in/wp-content/uploads/installed/2020/12/installed_capacity .
https://cea.nic.in/wp-content/uploads/installed/2020/12/installed_capacity .
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from Government of India, MNRE, “State-wise installed capacity
of grid interactive renewable power as on 31.12.2020”, https://
mnre.gov.in/img/documents/uploads/file_s-1612163907504.xlsx,
viewed 3 February 2021. India added 3.2 GW of solar PV capacity
in 2020, from N. T. Prasad, “Solar generation in Q4 2020 9%
higher from previous quarter, up 26% annually”, Mercom India, 8
February 2021, https://mercomindia.com/solar-generation-up-
26-percent-annually. (Mercom India data were confirmed to be
provided in AC by S. Prateek, Mercom India, New Delhi, personal
communication with REN21, May 2019.)
60 For example, see R. Ranjan, “India adds 3.2 GW of solar in 2020, a
56% decline as COVID takes a toll”, Mercom India, 23 February 2021,
https://mercomindia.com/india-adds-3-2-gw-of-solar-in-2020.
61 From, for example, MNRE cited in R. Ranjan, “Committee on
Energy skeptical about India’s chances of meeting its 2022 solar
target”, Mercom India, 24 March 2020, https://mercomindia.
com/committee-energy-india-chances-solar-target; R. Ranjan,
“Transmission infrastructure crucial to support growing solar
capacity”, Mercom India, 12 April 2021, https://mercomindia.
com/transmission-infrastructure-crucial-solar-capacity; U.
Gupta, “Solar industry in 2020”, pv magazine, https://www.
pv-magazine-india.com/2020/12/28/solar-industry-in-2020;
“750 MW of solar projects in Andhra Pradesh face serious
delays”, Mercom India, 27 August 2020, https://mercomindia.
com/solar-projects-andhra-pradesh-delays; A. Parikh, “MNRE
addresses transmission infrastructure delays facing solar & wind
developers”, Mercom India, 11 March 2020, https://mercomindia.
com/mnre-transmission-delays-solar-wind-developers; N. T.
Prasad, “1.4 GW of ISTS solar projects awarded by NTPC stand
canceled”, Mercom India, 30 January 2020, https://mercomindia.
com/ists-solar-projects-ntpc-canceled; P. Mints, SPV Market
Research, The Solar Flare, 4 September 2020, p. 10.
62 Rooftop market based on 3,505.61 MW of rooftop capacity and
1,076.63 MW equivalent (assumed to be all in DC) of off-grid
capacity at the end of 2020, from Government of India, MNRE,
“Physical progress – programme/scheme wise physical progress
in 2020-21 & cumulative upto Dec, 2020”, op. cit. note 59, viewed
3 February 2021, and on 2,333.23 MW of rooftop capacity
and 945.22 MW of off-grid capacity at the end of 2019, from
Government of India, MNRE, “Physical progress – programme/
scheme wise physical progress in 2019-20 & cumulative upto
Dec, 2019”, op. cit. note 59, viewed 9 January 2020. Inconsistent
policy and restrictions from R. Ranjan, “Rooftop solar cannot
thrive in a restrictive policy environment”, Mercom India, 14 April
2021, https://mercomindia.com/rooftop-solar-cannot-thrive-
restrictive-environment; pandemic from N. T. Prasad, “Cost of
large-scale and rooftop solar projects rose slightly in Q3 2020”,
Mercom India, 24 November 2020, https://mercomindia.com/
cost-large-scale-rooftop-solar; N. T. Prasad, “Top developments
that influenced the rooftop solar segment in 2020”, Mercom India,
31 December 2020, https://mercomindia.com/top-developments-
influenced-rooftop-solar; H. Shukla, “Where does India’s rooftop
solar market stand since COVID-19 lockdown?” Mercom India,
14 December 2020, https://mercomindia.com/where-does-
india-rooftop-solar; grid usage charges and net metering from
Bridge to India, op. cit. note 17. For more on the rooftop sector
and influences in 2020, see Prasad, “Top developments that
influenced the rooftop solar segment in 2020”, op. cit. this note.
63 Prasad, “Cost of large-scale and rooftop solar projects rose
slightly in Q3 2020”, op. cit. note 62; Prasad, “Top developments
that influenced the rooftop solar segment in 2020”, op. cit. note
62; Shukla, op. cit. note 62; Ranjan, op. cit. note 61. See also
Ranjan, “Committee on Energy skeptical about India’s chances of
meeting its 2022 solar target”, op. cit. note 60.
64 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, provided by A.
Detollenaere, Brussels, personal communication with REN21, 22
March and 20 April 2021. As of September 2020, several projects
ranging in size from 5 MW to 61 MW had secured licences in the
Philippines, from E. Bellini, “Three 1.2 GW solar projects under
development in the Philippines”, pv magazine, 4 September 2020,
https://www.pv-magazine.com/2020/09/04/three-1-2-gw-solar-
projects-under-development-in-the-philippines; by end-2020,
more than 1 GW of solar projects under PPAs were planned
for installation in 2021 by a single developer, from E. Bellini,
“Philippines to host 1 GW of solar under PPAs”, pv magazine,
9 December 2020, https://www.pv-magazine.com/2020/12/09/
philippines-to-host-1-gw-of-solar-under-ppas.
65 Based on data for 2020 from IEA PVPS, Snapshot of Global PV
Markets 2021, op. cit. note 1, and from Becquerel Institute, op. cit.
note 1; rankings for 2019 from IEA PVPS, Snapshot of Global PV
Markets 2020, op. cit. note 9, and from Becquerel Institute, op. cit.
note 1, 10 April 2020.
66 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note
1. Turkey connected an estimated 672 MWAC to the grid in
2020 for total of 6,667.4 MWAC,from Turkish grid operator
TEIAS, cited in E. Bellini, “Turkey added 672 MW (AC) of PV
capacity in 2020”, pv magazine, 14 January 2021, https://www.
pv-magazine.com/2021/01/14/turkey-added-672-mw-ac-of-pv-
capacity-in-2020; but industry leaders believe the actual figure is
10-20% higher, from discrepancy with industry estimates from H.
Karacaoglan, KRC Consulting (Germany), cited in idem.
67 Bellini, op. cit. note 66.
68 R. Nair, “Solar auction in Kazakhstan sees tariff dip to $0.034/
kWh”, Mercom India, 15 December 2020, https://mercomindia.
com/solar-auction-in-kazakhstan. Pakistan completed a 75 MW
and a 20 MW project, from idem.
69 America’s share based on data from IEA PVPS, Snapshot of
Global PV Markets 2021, op. cit. note 1, from Becquerel Institute,
op. cit. note 1, from National Renewable Energy Laboratory
(NREL), provided by Masson, op. cit. note 1, 25 May 2021, and
from Solar Energy Industries Association (SEIA) and Wood
Mackenzie, U.S. Solar Market Insight – 2020 Year in Review –
Executive Summary (Washington, DC: 2021), p. 5, https://www.
seia.org/research-resources/solar-market-insight-report-2020-
year-review. Figure 28 based on IEA PVPS, Snapshot of Global
PV Markets 2021, op. cit. note 1, on Becquerel Institute, op. cit. note
1, and on country-specific data and sources provided throughout
this section.
70 The United States added 19.2 GW for a total of 95.5 GW (all
in DC), from NREL, op. cit. note 69. The United States added
19,221.11 MW in 2020, and increase over previous record year
based on 15,103 MW installed in 2016, all from SEIA, “Solar
industry research data”, https://www.seia.org/solar-industry-
research-data, viewed 16 March 2021; up over 2019 from SEIA and
Wood Mackenzie, op. cit. note 69, p. 5; total year-end capacity
was 97.7 GW, from SEIA, “U.S. solar market insight”, https://
www.seia.org/us-solar-market-insight, updated 16 March 2021,
and was 97.2 GW, from SEIA, “Solar data cheat sheet”, https://
www.seia.org/research-resources/solar-data-cheat-sheet,
updated 16 March 2021. Note that these data are all provided in
DC. The United States added an estimated 14,889.9 MW (4,510
MW of small-scale plus 10,379.9 MW of utility-scale facilities) of
solar PV capacity in 2020, for a year-end total of 73,813.7 MW
at end-2020, from US EIA, Electric Power Monthly with Data for
December 2020 (Washington, DC: February 2021), Table 6.1,
https://www.eia.gov/electricity/monthly/archive/february2021.
pdf. These data omit capacity from facilities with a total generator
nameplate capacity less than 1 MW, from idem. In addition, the
US EIA reports solar PV capacity in AC because US electricity
operations and sales generally are conducted on an AC basis,
from Marcy, op. cit. note 1. Finally, note that total US solar PV
capacity exceeded 76 GW at the end of 2019, from SEIA and
Wood Mackenzie, U.S. Solar Market Insight, 2019 Year in Review –
Executive Summary (Washington, DC: March 2020), p. 5, https://
www.woodmac.com/research/products/power-and-renewables/
us-solar-market-insight.
71 SEIA and Wood Mackenzie, op. cit. note 69, pp. 5, 6.If counting
only capacity additions, solar PV accounted for 42.2% based on
total solar PV capacity additions of 14,889.9, followed by wind
power (14,172.9 MW), natural gas (6,022.6 MW), hydropower
(173.3 MW), geothermal (31.8 MW) and biopower (8.8 MW), all
from US EIA, op. cit. note 70, Table 6.1. Note that these figures do
not account for more than 13 GW of capacity taken offline in 2020,
most of which was conventional steam coal, from idem.
72 SEIA and Wood Mackenzie, op. cit. note 69, pp. 6, 8. California
added 3,904 MW, followed by Texas (3,425 MW) and Florida
(2,822 MW); Virginia was fourth, adding 1,406 MW, and all of
these states saw increases relative to 2019, from idem, p. 8.
73 Calculated based on solar PV net generation in 2020 from
utility-scale systems (87,743 GWh) and from small-scale systems
(41,740 GWh), both from US EIA, op. cit. note 70, Table 1.1.A, and
on total utility-scale facility net generation of 4,009,085 GWh
(plus previously noted small-scale solar PV generation), from
idem, Table 1.3.B.
304
https://mnre.gov.in/img/documents/uploads/file_s-1612163907504.xlsx
https://mnre.gov.in/img/documents/uploads/file_s-1612163907504.xlsx
https://mercomindia.com/solar-generation-up-26-percent-annually
https://mercomindia.com/solar-generation-up-26-percent-annually
https://mercomindia.com/india-adds-3-2-gw-of-solar-in-2020
https://mercomindia.com/committee-energy-india-chances-solar-target
https://mercomindia.com/committee-energy-india-chances-solar-target
https://mercomindia.com/transmission-infrastructure-crucial-solar-capacity
https://mercomindia.com/transmission-infrastructure-crucial-solar-capacity
https://www.pv-magazine-india.com/2020/12/28/solar-industry-in-2020
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https://mercomindia.com/solar-projects-andhra-pradesh-delays
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https://mercomindia.com/mnre-transmission-delays-solar-wind-developers
https://mercomindia.com/mnre-transmission-delays-solar-wind-developers
https://mercomindia.com/ists-solar-projects-ntpc-canceled
https://mercomindia.com/ists-solar-projects-ntpc-canceled
https://mercomindia.com/rooftop-solar-cannot-thrive-restrictive-environment
https://mercomindia.com/rooftop-solar-cannot-thrive-restrictive-environment
https://mercomindia.com/cost-large-scale-rooftop-solar
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https://mercomindia.com/top-developments-influenced-rooftop-solar
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https://mercomindia.com/where-does-india-rooftop-solar
https://mercomindia.com/where-does-india-rooftop-solar
https://www.pv-magazine.com/2020/09/04/three-1-2-gw-solar-projects-under-development-in-the-philippines
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https://www.pv-magazine.com/2020/12/09/philippines-to-host-1-gw-of-solar-under-ppas
https://www.pv-magazine.com/2020/12/09/philippines-to-host-1-gw-of-solar-under-ppas
https://www.pv-magazine.com/2021/01/14/turkey-added-672-mw-ac-of-pv-capacity-in-2020
https://www.pv-magazine.com/2021/01/14/turkey-added-672-mw-ac-of-pv-capacity-in-2020
https://www.pv-magazine.com/2021/01/14/turkey-added-672-mw-ac-of-pv-capacity-in-2020
https://mercomindia.com/solar-auction-in-kazakhstan
https://mercomindia.com/solar-auction-in-kazakhstan
https://www.seia.org/research-resources/solar-market-insight-report-2020-year-review
https://www.seia.org/research-resources/solar-market-insight-report-2020-year-review
https://www.seia.org/research-resources/solar-market-insight-report-2020-year-review
https://www.seia.org/solar-industry-research-data
https://www.seia.org/solar-industry-research-data
https://www.seia.org/us-solar-market-insight
https://www.seia.org/us-solar-market-insight
https://www.seia.org/research-resources/solar-data-cheat-sheet
https://www.seia.org/research-resources/solar-data-cheat-sheet
https://www.eia.gov/electricity/monthly/archive/february2021
https://www.eia.gov/electricity/monthly/archive/february2021
https://www.woodmac.com/research/products/power-and-renewables/us-solar-market-insight
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74 Based on 8.4 GW of utility-scale capacity added in 2019, from
SEIA and Wood Mackenzie, op. cit. note 70, p. 9, and 14 GW
added in 2020, from SEIA and Wood Mackenzie, op. cit. note 69,
p. 5; total of 59,772 MW, from SEIA, “Solar Industry Research
Data”, op. cit. note 70.
75 SEIA and Wood Mackenzie, op. cit. note 69, p. 5. The solar
investment tax credit was extended and will remain at 26%
for projects that begin construction in 2021 and 2022; it will
fall to 22% in 2023 and 10% in 2024 for commercial projects
(and the residential credit will end), from D. Wagman, “ US to
extend Investment Tax Credit for solar to 2024”, pv magazine, 22
December 2020, https://www.pv-magazine.com/2020/12/22/
us-to-extend-investment-tax-credit-for-solar-to-2024. As of early
2021, another 11.2 GW was already under construction, from
SEIA and Wood Mackenzie, op. cit. note 69, p. 14. Investment
tax credit details, from SEIA, “Solar Investment Tax Credit (ITC)”,
https://seia.org/initiatives/solar-investment-tax-credit-itc, viewed
28 April 2021. The ITC, established in 2005, provided a 30%
investment tax credit for projects that began construction by the
end of 2019. The credit stepped down to 26% in 2020, and it was
scheduled to drop to 22% in 2021 and 10% from 2022 onwards for
commercial and utility projects, and residential systems owned
by companies. However, at the end of 2020, the 26% credit was
extended for two years. It will decline to 22% in 2023, and, in
2024, will fall to 10% for commercial and utility-scale systems and
to zero for residential installations owned by homeowners.
76 SEIA and Wood Mackenzie, op. cit. note 69, p. 5.
77 Ibid., p. 14.
78 Third consecutive year, 4% decline relative to 2019, and
non-residential installations of 2.1 GW (2,074 MW) in 2020, all
from SEIA and Wood Mackenzie, op. cit. note 69, pp. 5, 13. Total
non-residential capacity at end-2020, from SEIA, “Solar industry
research data”, op. cit. note 70. The non-residential market
faced the worst pandemic-related delays of any US segment
and struggled with development timelines, interconnections,
permitting and approval processes at the local level, from SEIA
and Wood Mackenzie, op. cit. note 69, pp, 5, 12.
79 The US residential sector installed 3,194 MW of capacity in 2020,
from SEIA and Wood Mackenzie, op. cit. note 69, p. 5; year-end
total of 19,078.5 MW, from SEIA, “Solar industry research data”,
op. cit. note 7.
80 E. F. Merchant, “The highs and lows for solar in 2020”, Greentech
Media, 30 December 2020, https://www.greentechmedia.com/
articles/read/the-highs-and-lows-for-solar-in-2020. The SEIA
said 65,000 jobs had been lost as of May, or the equivalent
of five years of growth, and in June roofer and solar installer
PetersenDean filed for Chapter 11 bankruptcy, from idem.
Layoffs and bankruptcies were due largely to the inability to
find customers through traditional door-to-door sales, from
E. F. Merchant, “A new response to coronavirus: Giving solar
away for free”, Greentech Media, 23 April 2020, https://www.
greentechmedia.com/articles/read/one-response-to-the-
coronavirus-giving-solar-away-for-free. Shifting to online and
price cuts also from idem; E. F. Merchant, “How the coronavirus
pandemic has impacted US solar so far”, Greentech Media, 28
September 2020, https://www.greentechmedia.com/articles/
read/how-the-coronavirus-pandemic-has-already-reshaped-u.s-
solar; E. F. Merchant, “SunPower halts all global manufacturing,
cuts employee workweek”, Greentech Media, 20 April 2020,
https://www.greentechmedia.com/articles/read/sunpower-
halts-production-cuts-employee-workweek. Sunrun, the leading
US installer, had a limited-time lease contract offer of no money
upfront and USD 1 per month for the first six months, from
Merchant, “A new response to coronavirus”, op. cit. this note. New
customer acquisition models required additional investment but
also enabled companies to reach a broader, larger audience, from
SEIA and Wood Mackenzie, op. cit. note 69, p. 17.
81 See, for example, A. Proudlove, North Carolina State University’s
Clean Energy Technology Center, cited in E. F. Merchant, “New
year, same solar net metering battles”, Greentech Media, 12
January 2021, https://www.greentechmedia.com/squared/
the-lead/new-year-same-solar-net-metering-battles; H. K.
Trabish, “Amid rising rooftop solar battles, emerging net metering
alternatives could shake up the sector”, Utility Dive, 18 March
2021, https://www.utilitydive.com/news/rooftop-solar-battles-
emerging-net-metering-alternatives-duke-energy/596676.
82 SEIA and Wood Mackenzie, op. cit. note 69, pp. 5, 6.
83 P. Mints, SPV Research, The Solar Flare, 22 December 2020, p. 6;
S. Kim, “Why is California having rolling blackouts?” Newsweek,
19 August 2020, https://www.newsweek.com/california-heat-wave-
rolling-blackouts-power-outage-electricity-shortage-1526144.
84 SEIA, “Solar industry research data”, op. cit. note 70. Behind-the-
meter systems were up from under 5% in 2019, from idem. See
also E. Zindler, BCSE Sustainable Energy in America Factbook
(Washington, DC: Bloomberg Finance L. P., February 2021),
https://bcse.org/wp-content/uploads/2021-Sustainable-Energy-
in-America-Factbook-Executive-Summary . One in five US
residential solar PV installations included battery storage in 2020,
from “New survey shows solar installer confidence increased
60% in 2020”, Renewable Energy World, 29 March 2021, https://
www.renewableenergyworld.com/solar/new-survey-shows-solar-
installer-confidence-increased-60-in-2020.
85 For example, Nevada had three large solar-plus-storage projects
under development in 2020, from “Nevada goes big on solar-plus-
storage”, Windpower Monthly, September 2020, p. 31, https://
www.windpowermonthly.com/article/1692957/read-windpower-
monthly-online. Utilities brought plants into operation, from Saur
News Bureau, “Duke Energy brings online its largest solar project
in Texas”, Saur Energy International, 8 July 2020, https://www.
saurenergy.com/solar-energy-news/duke-energy-brings-online-
its-largest-solar-project-in-texas; solicitations from T. Sylvia,
“Solar-plus-storage replaces coal plant in New Mexico, makes
carbon-capture retrofit moot”, pv magazine, 12 October 2020,
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-
replaces-coal-plant-in-new-mexico-makes-carbon-capture-
retrofit-moot, and from T. Sylvia, “US utility issues tender for 1
GW of renewables”, pv magazine, 5 May 2020, https://www.
pv-magazine.com/2020/05/05/us-utility-issues-tender-for-1-gw-
of-pv. In New Mexico, a utility was in the process of replacing a
large coal-fired generator (and plans for carbon capture) with
solar PV-plus-storage capacity, from T. Sylvia, “Solar-plus-storage
replaces coal plant in New Mexico, makes carbon-capture retrofit
moot”, pv magazine, 12 October 2020, https://pv-magazine-usa.
com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-
mexico-makes-carbon-capture-retrofit-moot.
86 “US solar-storage builders thrive as risks recede”, Reuters Events,
2 December 2020, https://www.reutersevents.com/renewables/
solar-pv/us-solar-storage-builders-thrive-risks-recede.
87 See, for example, “US hybrid wind rush highlights
tax credit impact”, Reuters Events, 13 January 2021,
https://www.reutersevents.com/renewables/wind/
us-hybrid-wind-rush-highlights-tax-credit-impact.
88 ABSOLAR, “Energia solar fotovoltaica no Brasil – Infográfico
ABSOLAR”, no. 31 (4 May 2021), https://www.absolar.org.br/
mercado/infografico. Challenging economic conditions (among
top solar installers) in Argentina and Brazil, in particular, from
I. Sagardoy, Fundacion Bariloche, personal communication
with REN21, April 2020; F. Sabadini, RWTH – Aachen, personal
communication with REN21, 1 April 2020; abundance of solar
resources from M. Dorothal, “Top 30 Latin American solar PV
plants (2018 update)”, Unlocking Solar Capital, 22 May 2018,
https://lac.unlockingsolarcapital.com/news-english/2018/5/22/
top-30-latin-american-solar-pv-plants-2018-update; cost/price
reductions are driving decisions, from E. Cruz, Climate Finance
Solutions, personal communication with REN21, 13 April 2020.
Note that in 2019, Mexico cancelled its fourth long-term auction,
which had already been announced, as well as tenders to two
transmission lines; 2019 medium-term auctions were cancelled as
well, from IRENA, Renewable Energy Auctions: Status and Trends
Beyond Price (Abu Dhabi: 2019), p. 17, https://www.irena.org/-/
media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_
RE-Auctions_Status-and-trends_2019 . The priority of taking
actions related to the pandemic led to delays in the discussion
in Brazil of a legal framework for distributed generation in 2020,
from Baitelo, op. cit. note 17, 31 March 2021.
89 Brazil added 3,145 MW in 2020, based on 7,740 MW at end-2020
and 4,595 MW at end-2019, from ABSOLAR, op. cit. note 87; Mexico
added 1.5 GW, Chile added 790 MW and Argentina added around
320 MW, from IEA PVPS, Snapshot of Global PV Markets 2021, op. cit.
note 1, p. 14. Chile also from ACERA, op. cit. note 12, pp. 3, 5.
90 Mexico ended 2020 with an estimated 5,001 MW, from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1. Figure of 7.7 GW in Brazil, from
ABSOLAR, op. cit. note 87.
91 Figure of 68.6% from ABSOLAR, op. cit. note 87.
305
https://www.pv-magazine.com/2020/12/22/us-to-extend-investment-tax-credit-for-solar-to-2024
https://www.pv-magazine.com/2020/12/22/us-to-extend-investment-tax-credit-for-solar-to-2024
https://seia.org/initiatives/solar-investment-tax-credit-itc
https://www.greentechmedia.com/articles/read/the-highs-and-lows-for-solar-in-2020
https://www.greentechmedia.com/articles/read/the-highs-and-lows-for-solar-in-2020
https://www.greentechmedia.com/articles/read/one-response-to-the-coronavirus-giving-solar-away-for-free
https://www.greentechmedia.com/articles/read/one-response-to-the-coronavirus-giving-solar-away-for-free
https://www.greentechmedia.com/articles/read/one-response-to-the-coronavirus-giving-solar-away-for-free
https://www.greentechmedia.com/articles/read/how-the-coronavirus-pandemic-has-already-reshaped-u.s-solar
https://www.greentechmedia.com/articles/read/how-the-coronavirus-pandemic-has-already-reshaped-u.s-solar
https://www.greentechmedia.com/articles/read/how-the-coronavirus-pandemic-has-already-reshaped-u.s-solar
https://www.greentechmedia.com/articles/read/sunpower-halts-production-cuts-employee-workweek
https://www.greentechmedia.com/articles/read/sunpower-halts-production-cuts-employee-workweek
https://www.greentechmedia.com/squared/the-lead/new-year-same-solar-net-metering-battles
https://www.greentechmedia.com/squared/the-lead/new-year-same-solar-net-metering-battles
https://www.utilitydive.com/news/rooftop-solar-battles-emerging-net-metering-alternatives-duke-energy/596676
https://www.utilitydive.com/news/rooftop-solar-battles-emerging-net-metering-alternatives-duke-energy/596676
https://www.newsweek.com/california-heat-wave-rolling-blackouts-power-outage-electricity-shortage-1526144
https://www.newsweek.com/california-heat-wave-rolling-blackouts-power-outage-electricity-shortage-1526144
https://bcse.org/wp-content/uploads/2021-Sustainable-Energy-in-America-Factbook-Executive-Summary
https://bcse.org/wp-content/uploads/2021-Sustainable-Energy-in-America-Factbook-Executive-Summary
https://www.renewableenergyworld.com/solar/new-survey-shows-solar-installer-confidence-increased-60-in-2020
https://www.renewableenergyworld.com/solar/new-survey-shows-solar-installer-confidence-increased-60-in-2020
https://www.renewableenergyworld.com/solar/new-survey-shows-solar-installer-confidence-increased-60-in-2020
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.saurenergy.com/solar-energy-news/duke-energy-brings-online-its-largest-solar-project-in-texas
https://www.saurenergy.com/solar-energy-news/duke-energy-brings-online-its-largest-solar-project-in-texas
https://www.saurenergy.com/solar-energy-news/duke-energy-brings-online-its-largest-solar-project-in-texas
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://www.pv-magazine.com/2020/05/05/us-utility-issues-tender-for-1-gw-of-pv
https://www.pv-magazine.com/2020/05/05/us-utility-issues-tender-for-1-gw-of-pv
https://www.pv-magazine.com/2020/05/05/us-utility-issues-tender-for-1-gw-of-pv
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://pv-magazine-usa.com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-mexico-makes-carbon-capture-retrofit-moot
https://www.reutersevents.com/renewables/solar-pv/us-solar-storage-builders-thrive-risks-recede
https://www.reutersevents.com/renewables/solar-pv/us-solar-storage-builders-thrive-risks-recede
https://www.reutersevents.com/renewables/wind/us-hybrid-wind-rush-highlights-tax-credit-impact
https://www.reutersevents.com/renewables/wind/us-hybrid-wind-rush-highlights-tax-credit-impact
https://www.absolar.org.br/mercado/infografico
https://www.absolar.org.br/mercado/infografico
https://lac.unlockingsolarcapital.com/news-english/2018/5/22/top-30-latin-american-solar-pv-plants-2018-update
https://lac.unlockingsolarcapital.com/news-english/2018/5/22/top-30-latin-american-solar-pv-plants-2018-update
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
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92 Ibid.
93 Ibid.
94 Ibid.
95 BNAmericas, “Brazil due to hold 8 power generation
tenders in 2021”, Renewables Now, 9 December
2020, https://www.bnamericas.com/en/news/
brazil-due-to-hold-8-power-generation-tenders-in-2021.
96 J. R. Martín, “COVID-19 brings ‘indefinite’ delays for Brazil’s
solar-friendly auctions”, PV-Tech, 31 March 2020, https://www.
pv-tech.org/indefinite-delays-for-brazils-solar-friendly-auctions-
amid-covid-19-row.
97 Sonnedix, “Sonnedix and Collahuasi sign a 100%-renewable
PPA”, press release (Iquique, Chile: 29 July 2020), https://
www.sonnedix.com/news/sonnedix-and-collahuasi-sign-a-
100-renewable-ppa; A. Bhambhani, “Sonnedix to supply 150
GWh solar power annually to Chilean copper miner Collahuasi
from 170 MW Sonnedix Atacama solar project In Chile”,
TaiyangNews, 4 August 2020, http://taiyangnews.info/business/
chilean-copper-miner-to-procure-solar-power.
98 First Solar, “First Solar power plant in Chile is world’s first to
deliver grid services”, press release (Tempe, AZ: 20 August 2020),
https://investor.firstsolar.com/news/press-release-details/2020/
First-Solar-Power-Plant-in-Chile-is-Worlds-First-to-Deliver-Grid-
Services/default.aspx.
99 Chile’s year-end capacity was 3,484 MW, with another 3,695 MW
under construction and 15,520 MW approved, from ACERA, op.
cit. note 12, pp. 3, 5.
100 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
101 Installations were up 11% over 2019, based on additions of 18.2
GW in 2020, from SolarPower Europe, op. cit. note 4, p. 3; and
were up 23.7% in 2020 based on additions of 19.3 GW in 2020,
from IEA PVPS and Becquerel Institute, op. cit. note 1, 6 May
2021, and additions of 15.9 GW in EU-27 and the United Kingdom
in 2019, from IEA PVPS, Trends in Photovoltaic Applications
2020, op. cit. note 1, p. 23, less the 0.3 GW installed in the United
Kingdom in 2019, from UK BEIS, “Solar photovoltaics deployment
in the UK”, https://www.gov.uk/government/statistics/solar-
photovoltaics-deployment, updated 30 January 2020.
102 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
103 Figure of 0.5 GW (545 MW) added and year-end total of 13.9 GW
(13,873 MW), based on data from IEA PVPS, Snapshot of Global
PV Markets 2021, op. cit. note 1, and from Becquerel Institute, op.
cit. note 1. Figure of 4.1 GW in 2015, based on cumulative installed
capacity of 5,528 MW at end-2014 and 9,601 MW at end-2015,
from UK BEIS, “Renewable electricity capacity and generation”,
Table 6.1. Renewable electricity capacity and generation, https://
www.gov.uk/government/statistics/energy-trends-section-6-
renewables, viewed 16 April 2021. The country added 545 MW
for a total of 13.9 GW in 2020, from Solar Energy UK, cited in
M. Hall, “UK added 545 MW of solar last year to hit 13.9 GW”,
pv magazine, 21 January 2021, https://www.pv-magazine.
com/2021/01/21/uk-added-545-mw-of-solar-last-year-to-hit-13-
9-gw; added 217 MW in 2020 (down from 273 MW in 2019), from
UK BEIS, op. cit. note 13, p. 16; and added 166 MW for a year-end
total of 13,516 MW, from UK BEIS, op. cit. note 101, Table 1, viewed
16 April 2021. Note that the official statistics in the BEIS table are
based on incomplete datasets that do not include unsubsidised
systems with capacity below 1 MW that are not registered on the
UK Microgeneration Certification Scheme database, from idem.
About 60% of new capacity in 2020 was in large-scale ground-
mounted projects, and the remainder was in rooftop (mostly
commercial) systems, from Solar Energy UK, cited in Hall, op. cit.
this note.
104 Additional large-scale projects from J. Parnell, “UK lifts block
on new onshore wind and solar”, Greentech Media, 2 March
2020, https://www.greentechmedia.com/articles/read/uk-lifts-
block-on-new-onshore-wind-and-solar; “UK solar developers
deploy storage to capture peak returns”, Reuters Events, 5 May
2020, https://analysis.newenergyupdate.com/solar/uk-solar-
developers-deploy-storage-capture-peak-returns; “UK urged
to set 2035 net zero target; Enel to install 15 GW renewables
by 2023”, Reuters Events, 2 December 2020, https://www.
reutersevents.com/renewables/solar-pv/uk-urged-set-2035-net-
zero-target-enel-install-15-gw-renewables-2023.
105 Parnell, op. cit. note 104.
106 Below expectations and second-best from SolarPower Europe,
op. cit. note 4, p. 3. Additions in 2019 were 16.2 GW and the best
year yet was 2011, when 21.4 GW was added, from idem, p. 5.
Note that the 21.4 GW added in 2011 included installations in
the United Kingdom, but the country added only an estimated
0.9 GW in 2011, based on data from REN21, Renewables Global
Status Report 2012 (Paris: 2012). More new power capacity,
from M. Schmela, SolarPower Europe, interview with Z. Brustik,
“Spirit of optimism in European PV markets”, The Smarter E
Podcast, 28 January 2021, https://www.intersolar.de/podcast/en/
spirit-of-optimism-in-european-pv-markets.
107 Around 19.3 GW added for a total of 140.5 GW and total capacity
up more than 15%, based on data from IEA PVPS and Becquerel
Institute, op. cit. note 1, 6 May 2021. An estimated 19.6 GW was
added in 2020, from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, p. 6; an estimated 18.2 GW was brought
online, raising cumulative capacity by 15% to 137.2 GW, from
SolarPower Europe, op. cit. note 4, pp. 3, 5.
108 EurObserv’ER, op. cit. note 30, p. 15. The year 2019 saw the first
major projects commissioned in Europe that were without direct
subsidies and outside of volumes allocated for auctions (under
PPAs), from idem, p. 11.
109 See, for example, SolarPower Europe, op. cit. note 4; SolarPower
Europe, EU Market Outlook for Solar Power, 2019-2023 (Brussels:
2019), pp. 6, 12, 82-83, https://www.solarpowereurope.org/
eu-market-outlook-for-solar-power-2019-2023; C. Gilligan,
“A new era of sustained growth”, pv magazine, 16 January 2020,
https://www.pv-magazine.com/2020/01/16/a-new-era-of-
sustained-growth; Schmela, op. cit. note 106.
110 All challenges except land availability from Gilligan, op. cit. note
109; land availability from, for example, “Your guide to solar market
growth in the global ‘gigawatt club’”, pv magazine, 18 January
2020 https://pv-magazine-usa.com/2020/01/18/your-guide-to-
solar-market-growth-in-the-global-gigawatt-club; land availability
and grid constraints from SolarPower Europe, op. cit. note 109, pp.
50, 76; Solarplaza, Dutch Solar Energy Market Seeking Space to
Grow Further, prepared for The Solar Future NL, Utrecht, 8-9 July
2020, https://thesolarfuture.nl/nieuws-source/2020/3/2/dutch-
solar-energy-market-seeking-space-to-grow-further; Mints, The
Solar Flare, no. 5, op. cit. note 25, p. 28.
111 SolarPower Europe, op. cit. note 4, p. 5. However, this share was
down from 79% installed in the top five countries in 2019, from idem.
112 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, p. 6. France added 0.9 GW, from idem.
Additions were the Netherlands (2.8 GW), Spain (2.6 GW), Poland
(2.2 GW) and France (0.9 GW), from SolarPower Europe, op. cit.
note 4, p. 5. Belgium became a gigawatt market for the first time
in 2020, from R. Rossi, SolarPower Europe, Brussels, personal
communication with REN21, 25 May 2021.
113 SolarPower Europe, op. cit. note 4, p. 20, and based on data from
IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, and
from Becquerel Institute, op. cit. note 1. Italy added 0.8 GW for a
year-end total of 21.7 GW, from Becquerel Institute, op. cit. note 1.
114 Increase relative to 2019 based on Germany added 3,835 MW in
2019, from IEA PVPS, Trends in Photovoltaic Applications 2019,
op. cit. note 5, p. 85; added 4,885 MW for a total of 53,932 MW
in 2020, from IEA PVPS, Snapshot of Global PV Markets 2021, op.
cit. note 1, and from Becquerel Institute, op. cit. note 1. Germany
added 4.8 GW in 2020 for total of 54.6 GW, from SolarPower
Europe, op. cit. note 4, pp. 5, 20. In 2020, Germany added 4.88
GW for total of 53.6 GW; by comparison, annual additions were
3.94 GW in 2019, 2.96 GW in 2018 and 1.75 GW in 2017, from
German federal network agency, the Bundesnetzagentur, cited
in S. Enkhardt, “Germany installed 4.88 GW of solar in 2020”,
pv magazine, 1 February 2021, https://www.pv-magazine.
com/2021/02/01/germany-installed-4-88-gw-of-solar-in-2020,
and Germany added 4,801 MW for a year-end total of 53,848 MW,
based on 49,047 MW at the end of 2019 and 53,848 MW at the
end of 2020, from BMWi and AGEE-Stat, op. cit. note 12, p. 7.
115 Commercial share based on 2020 additions of 2,887 MW (up
6% over 2019 additions), from Bundesverband Solarwirtschaft
e. V. (BSW-Solar), “Solar boom on private rooftops”, 2 February
2021, https://www.solarwirtschaft.de/en/2021/02/02/
solar-boom-on-private-rooftops.
116 Ibid. Share of annual market based on additions of 867 MW,
from idem. Note that solar PV won nearly all auctioned capacity
306
https://www.bnamericas.com/en/news/brazil-due-to-hold-8-power-generation-tenders-in-2021
https://www.bnamericas.com/en/news/brazil-due-to-hold-8-power-generation-tenders-in-2021
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https://www.pv-tech.org/indefinite-delays-for-brazils-solar-friendly-auctions-amid-covid-19-row
https://www.pv-tech.org/indefinite-delays-for-brazils-solar-friendly-auctions-amid-covid-19-row
https://www.sonnedix.com/news/sonnedix-and-collahuasi-sign-a-100-renewable-ppa
https://www.sonnedix.com/news/sonnedix-and-collahuasi-sign-a-100-renewable-ppa
https://www.sonnedix.com/news/sonnedix-and-collahuasi-sign-a-100-renewable-ppa
http://taiyangnews.info/business/chilean-copper-miner-to-procure-solar-power
http://taiyangnews.info/business/chilean-copper-miner-to-procure-solar-power
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https://www.gov.uk/government/statistics/solar-photovoltaics-deployment
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https://www.gov.uk/government/statistics/energy-trends-section-6-renewables
https://www.pv-magazine.com/2021/01/21/uk-added-545-mw-of-solar-last-year-to-hit-13-9-gw
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https://www.pv-magazine.com/2021/01/21/uk-added-545-mw-of-solar-last-year-to-hit-13-9-gw
https://www.greentechmedia.com/articles/read/uk-lifts-block-on-new-onshore-wind-and-solar
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https://www.solarwirtschaft.de/en/2021/02/02/solar-boom-on-private-rooftops
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in technology-neutral tenders during the year, from SolarPower
Europe, “Spotlight on GW EU solar markets: Germany comes
out on top despite new EEG revision changing support policy
framework”, 2 February 2021, https://www.solarpowereurope.org/
spotlight-on-gw-eu-solar-markets-germany-on-top-despite-new-
eeg-revision-changing-the-support-policy-framework.
117 BSW-Solar, op. cit. note 115. Homeowners added 1,131 MW of
capacity in systems up to 10 kW, from idem.
118 Roughly half from BSW-Solar, “Statistical Figures of the German
Solar Power Industry (Storage / Mobility)” (Berlin: 2021),
https://www.solarwirtschaft.de/datawall/uploads/2021/02/
BSW_Faktenblatt_Stromspeicher_Update_2020 , and more
than 90% of residential rooftop systems were installed with
battery storage in 2020, from SolarPower Europe, European
Market Outlook for Residential Battery Storage 2020-2024
(Brussels: October 2020), p. 3, https://www.solarpowereurope.
org/european-market-outlook-for-residential-battery-storage.
The storage market was up 50% for third consecutive year, from
BSW-Solar, “Solar battery boom”, 18 February 2021, https://
www.solarwirtschaft.de/en/2021/02/18/solar-battery-boom.
Estimated total solar battery storage capacity of 1.9 GWh,
based on data from EUPD Research (2020), Energiewende im
Kontext von Atom- und Kohleausstieg – Update 2020, Berlin,
cited in BSW-Solar, “Statistical Figures of the German Solar
Power Industry (Storage/Mobility)”, op. cit. this note; about
88,000 systems installed in 2020 for a total of 272,000 units,
from idem; estimated total battery storage capacity at year’s
end was around 2.4 GWh, from BSW-Solar, “Solar battery
boom”, op. cit. this note. Residential storage linked to solar
PV is supported in Germany with rebates, from P. Hannen,
“Germany has 270,000 residential batteries linked to PV”, 19
February 2021, https://www.pv-magazine.com/2021/02/19/
germany-has-270000-residential-batteries-linked-to-pv.
119 Removed in July and Germany’s capacity passed the 52 GW
level in August 2020, from S. Enkhardt, “Germany breaches 52
GW mark with 409 MW of new solar in August”, pv magazine,
1 October 2020, https://www.pv-magazine.com/2020/10/01/
germany-breaches-52-gw-mark-with-409-mw-of-new-solar-in-
august. The government pledged in September 2019 to lift the
cap, but its removal was not official until July 2020. This delay is
believed to have slowed installations of smaller rooftop systems in
August (as Germany approached the 52 GW mark), the weakest
month of 2020 (at least as of end-September), from idem. The
revised feed-in law, which was enacted in December, maintains
the feed-in payment for systems up to 300 kW and owners of
systems 300-750 kW have two options: to receive the payment
(at half the level of smaller systems) with permission to self-
consume the electricity generation, or to build the project under
the tender scheme for utility-scale solar PV and without the ability
to self-consume, from Enkhardt, op. cit. note 114; S. Enkhardt,
“Germany introduces new renewable energy law”, pv magazine,
17 December 2020, https://www.pv-magazine.com/2020/12/17/
germany-introduces-new-renewable-energy-law.
120 H. Shukla, “Germany’s new Climate Action Plan focuses
on augmenting solar and wind capacities”, Mercom India,
24 September 2020, https://mercomindia.com/germany-
new-climate-action-plan; N. T. Prasad, “Germany’s solar
tender oversubscribed, lowest tariff dips to €0.049/kWh”,
Mercom India, 29 October 2020, https://mercomindia.com/
germany-solar-tender-oversubscribed.
121 C. Menke, “Photovoltaics – the key to the energy transition”, BSW-
Solar, https://www.solarwirtschaft.de/en/topics-of-interest/
photovoltaics, viewed 24 March 2021.
122 Figure of 50.6 TWh (gross generation) in 2020 (up from 46.4
TWh in 2019), from BMWI and AGEE-Stat, op. cit. note 12, p.
6; share of generation from Fraunhofer ISE, op. cit. note 12.
Solar PV share of net generation for public electricity supply
was 10%, from Bundesnetzagentur, cited in BSW-Solar (2021),
“Statistical Figures of the German Solar Power Industry
(Photovoltaics)”, Berlin, https://www.solarwirtschaft.de/
datawall/uploads/2021/02/BSW_Faktenblatt_Photovoltaik_
Update_2020-1 . Solar PV generation was up from 45.8 TWh
in 2018 and 46.4 TWh in 2019, from idem.
123 Steady growth from Dutch New Energy, Nationaal Solar
Trendrapport 2021, cited in E. Bellini, “Netherlands deployed 2.93
GW of solar in 2020”, pv magazine, 21 January 2021, https://www.
pv-magazine.com/2021/01/21/netherlands-deployed-2-93-gw-of-
solar-in-2020. In 2020, 2.93 GW added, up from 2.57 GW in 2019,
1.69 GW in 2018, 853 GW in 2017, for total of more than 10.1 GW,
from idem. Drivers from SolarPower Europe, op. cit. note 4, p. 11.
124 The Netherlands added 3,036 MW for a total of 10,213 MW, from
IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1,
and from Becquerel Institute, op. cit. note 1; nearly half from
SolarPower Europe, op. cit. note 4, p. 11. The year-end total was
9.2 GW, from idem, p. 20, and it was more than 10.1 GW, from
Dutch New Energy, op. cit. note 123. Residential installations
totalled 1.09 GW at end-2020, up from 873 GW in 2019, from idem.
About 16 GW of additional capacity was under construction in the
Netherlands at year’s end, from idem.
125 SolarPower Europe, op. cit. note 4, p. 11.
126 Dutch New Energy, op. cit. note 123.
127 Spain added 2,806 MW in 2020 for a total of 12,716 MW, from
IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1,
and from Becquerel Institute, op. cit. note 1. This was down 40%
based on additions of 4,751 MW in 2019, from IEA PVPS, Trends
in Photovoltaic Applications 2019, op. cit. note 5, p. 85, and down
18% based on 3,256 MW added in 2020 and 3.97 GW added in
2019, from APPA Renovables, cited in P. Sanchez Molina, “Spain
installed 3.2 GW of solar last year”, pv magazine, 15 February
2021, https://www.pv-magazine.com/2021/02/15/spain-installed-
3-2-gw-of-solar-last-year. Spain had 8,914 MWAC at end of 2019
and 11,547 MWAC at the end of 2020, for a net increase of 2,633AC,
from Red Eléctrica de España (REE), “Potencia instalada nacional
(MW)”, as of 31 December 2020, https://www.ree.es/es/datos/
publicaciones/series-estadisticas-nacionales. Added 3,256
MW, including 623 MW distributed and 2,633 MW utility-scale
projects, for a year-end total of about 11 GW (it is not known if
these data are in AC or DC), from APPA Renovables, cited in
Sanchez Molina, op. cit. this note.
128 SolarPower Europe, op. cit. note 4, p. 13. Private PPAs lacked
direct government support, from Sanchez Molina, op. cit. note 127.
129 SolarPower Europe, “Spotlight on GW EU solar markets: Spain
leads PPA subsidy-free market growth”, 29 January 2021, https://
www.solarpowereurope.org/spotlight-on-gw-eu-solar-markets-
spain-leads-ppa-subsidy-free-market-growth.
130 The residential sector experienced unprecedented growth in
2020, and figure of 30% growth in self-consumption market,
based on data from Unión Española Fotovoltaica, cited in P.
Sanchez Molina, “Solar for self-consumption keeps growing in
Spain”, pv magazine, 29 January 2021, https://www.pv-magazine.
com/2021/01/29/solar-for-self-consumption-keeps-growing-in-
spain. The self-consumption market in 2020 was 596 MW, up
from 459 MW in 2019; the industrial sector had the largest portion
(56%), followed by commercial (23%) and residential (19%), from
idem. The market grew less than expected because the small
to medium enterprise sector was significantly affected by the
pandemic, from SolarPower Europe, op. cit. note 4, pp. 13, 84.
131 REE, “The Spanish Electricity System – End of Year
Forecast 2020” (Madrid: December 2020), with
estimated data as of 11 December 2020, https://www.
ree.es/en/datos/publications/annual-system-report/
spanish-electricity-system-preliminary-report-2020.
132 Poland added 2,636 MW for a total of 3,936 MW, from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1. Added 1,850 MW in 2020 for
year-end total of 3,150 MW (or 3.6 GW), from SolarPower Europe,
op. cit. note 4, pp. 20, 54. Drivers from idem, p. 13; SolarPower
Europe, “Spotlight on GW EU solar markets: Poland sees growing
micro-installations and positive policy developments”, 22 January
2021, https://www.solarpowereurope.org/spotlight-on-gw-eu-
solar-markets-poland-sees-growing-micro-installations-and-
positive-policy-developments. Favourable policies included net
metering and feed-in tariffs, from idem.
133 For example, see M. Willuhn, “Statkraft greens Polish steel
with 10-year PPA”, pv magazine, 21 January 2021, https://www.
pv-magazine.com/2020/01/21/statkraft-greens-polish-steel-
with-10-year-ppa; J. R. Martín, “Polish coal giant doubles down
on 2.5GW solar push despite business retrenchment”, PV-Tech,
15 April 2020, https://www.pv-tech.org/news/polish-coal-giant-
doubles-down-on-2.5gw-solar-push-despite-business-retrenc.
134 Switzerland from D. Stickelberger, “Rekordzubau bei der
Schweizer Photovoltaik 2020”, Swissolar, 3 March 2021,
https://www.swissolar.ch/services/medien/news/detail/n-n/
rekordzubau-bei-der-schweizer-photovoltaik-2020. Switzerland’s
market grew at least 30% relative to 2019, to record levels with
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https://www.solarpowereurope.org/spotlight-on-gw-eu-solar-markets-poland-sees-growing-micro-installations-and-positive-policy-developments
https://www.solarpowereurope.org/spotlight-on-gw-eu-solar-markets-poland-sees-growing-micro-installations-and-positive-policy-developments
https://www.solarpowereurope.org/spotlight-on-gw-eu-solar-markets-poland-sees-growing-micro-installations-and-positive-policy-developments
https://www.pv-magazine.com/2020/01/21/statkraft-greens-polish-steel-with-10-year-ppa
https://www.pv-magazine.com/2020/01/21/statkraft-greens-polish-steel-with-10-year-ppa
https://www.pv-magazine.com/2020/01/21/statkraft-greens-polish-steel-with-10-year-ppa
https://www.pv-tech.org/news/polish-coal-giant-doubles-down-on-2.5gw-solar-push-despite-business-retrenc
https://www.pv-tech.org/news/polish-coal-giant-doubles-down-on-2.5gw-solar-push-despite-business-retrenc
https://www.swissolar.ch/services/medien/news/detail/n-n/rekordzubau-bei-der-schweizer-photovoltaik-2020
https://www.swissolar.ch/services/medien/news/detail/n-n/rekordzubau-bei-der-schweizer-photovoltaik-2020
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estimated additions of at least 430-460 MW, from idem. Denmark
from Z. Shahan, “400,000+ solar co-owners in giant community
solar park initiative In Denmark & Poland”, CleanTechnica, 5
December 2020, https://cleantechnica.com/2020/12/05/400000-
solar-co-owners-in-giant-community-solar-park-initiative-in-
denmark-poland. Five parks were in operation by the end of 2020
and the rest were expected in 2021 and 2022; the initiative is a
partnership of Danish pension fund Industriens Pension and
Better Energy (Denmark), from idem. R. Withlock, “Lithuania
welcomes world’s first online consumer platform for purchasing
remote solar panels”, Renewable Energy Magazine, 25 March
2020, https://www.renewableenergymagazine.com/pv_solar/
lithuania-welcomes-worlda-s-first-online-consumer-20200325.
In addition, what is believed to be Europe’s largest rooftop system
(12 MW) went online in October at an Audi factory in Győr,
Hungary, from Z. Shahan, “Largest rooftop solar system in Europe
goes online… on Audi factory”, CleanTechnica, 9 October 2020,
https://cleantechnica.com/2020/10/09/largest-rooftop-solar-
system-in-europe-goes-online-on-audi-factory.
135 Clean Energy Regulator, cited in Australian Energy Council, Solar
Report (Melbourne: January 2021), p. 3, https://www.energycouncil.
com.au/media/jv4blk2l/final-pdf-australian-energy-council-
solar-report_-jan-2021 ; B. Church, “End of year forecast for
the Australian PV solar market (2020)”, Sunwiz, https://www.
sunwiz.com.au/end-of-year-forecast-for-the-australian-pv-solar-
market-2020, viewed 16 March 2021. Additions in the Northern
Territory were down 17%, but by small amounts in terms of actual
capacity, with 28.88 MW added in 2019 and 24 MW installed in
2020, from Australian Energy Council, op. cit. this note, p. 5. Rank
based on data from IEA PVPS, Snapshot of Global PV Markets 2021,
op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
136 M. Maisch, “Australia’s renewables pipeline continues to grow at
record speed led by solar PV”, pv magazine, 23 July 2020, https://
www.pv-magazine-australia.com/2020/07/23/australias-renewables-
pipeline-continues-to-grow-at-record-speed-led-by-solar-pv.
137 P. Crossley, University of Sydney, Sydney, Australia, personal
communication with REN21, 9 April 2021; M. Lewis, “Bushfire
recovery – more than just new poles”, Energy Networks
Australia, 30 January 2020, https://www.energynetworks.
com.au/news/energy-insider/2020-energy-insider/
bushfire-recovery-more-than-just-new-poles.
138 Based on data from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
Australia added somewhere in the range of 4,105 MW (reported)
and 4,376 MW (estimated) based on end-2019 reported capacity
of 16,094 MW and end-2020 reported capacity of 20,199 MW
and end-2020 estimated capacity of 20,469 MW, from APVI,
APVI Solar Map, funded by ARENA, https://pv-map.apvi.org.au/
analyses, viewed 8 March 2021.
139 Increase over 2019 based on generation data in 2019 (solar total
of 18,126 GWh) from Clean Energy Council, Clean Energy Australia
Report 2020 (Melbourne, March 2020), p. 9, https://assets.
cleanenergycouncil.org.au/documents/resources/reports/clean-
energy-australia/clean-energy-australia-report-2021 ; 2020
data (solar total of 22,510 GWh) from Clean Energy Council, op.
cit. note 12, p. 9; shares of Australia’s total electricity generation
from idem, p. 9; generation from small-scale solar PV overtook
hydropower as Australia’s second largest generator of renewable
electricity (after hydropower), from idem, pp. 9, 70.
140 D. Carroll, “Australia deployed 2.6 GW of rooftop
PV in 2020”, pv magazine, 8 February 2021,
https://www.pv-magazine.com/2021/02/08/
australia-deployed-2-6-gw-of-rooftop-pv-in-2020.
141 Based on the following: Australia’s rooftops saw 2,642 MW added
in 2020 (up from 2,355 MW added in 2019) for a year-end total
of 12,895 MW, from IEA PVPS, op. cit. note 1, and from Becquerel
Institute, op. cit. note 1. If we assume that all off-grid capacity
is also under 100 kW, then 2,662 MW was added in 2020 (up
from 2,380 MW in 2019), for a year-end total of 13,199 MW,
from idem (both sources). About 2.6 GW was added (in 333,978
installations) in 2020, up from 2.2 GW (in 284,000 installations)
in 2019, from Clean Energy Regulator, cited in Australian Energy
Council, op. cit. note 135, p. 3; note that final installations could
be higher because consumers have up to a year to register their
new systems, from idem. Just under 3 GW was added in 2020,
up from 2.1 GW in 2019, from Sunwiz Annual Report, cited in
J. Sykes, “What is driving record rooftop solar volumes in
Australia?” Renewable Energy World, 3 February 2021,
https://www.renewableenergyworld.com/solar/what-is-driving-
record-rooftop-solar-volumes-in-australia. Australia added
3,043 MW of rooftop solar PV capacity (in 378,451 systems) in
2020 (up from 2.2 GW in 2019) for a year-end total of 13,415 MW,
from Clean Energy Council, op. cit. note 12, pp. 7, 17.
142 Clean Energy Council, op. cit. note 12, pp. 8, 62. Batteries were
installed at 22,661 households in 2019, from idem, p. 62.
143 J. Deign, “What other countries can learn from Australia’s roaring
rooftop solar market”, Greentech Media, 3 August 2020, https://
www.greentechmedia.com/articles/read/what-the-us-can-
learn-from-australias-roaring-rooftop-solar-market; Australian
Energy Council, op. cit. note 135, p. 3; B. Matich, “Forget toilet
paper, Australians are panic-buying PV”, pv magazine, 19 March
2020, https://www.pv-magazine.com/2020/03/19/forget-toilet-
paper-australians-are-panic-buying-pv; Sykes, op. cit. note 141.
Residential solar prices continued a decade-long downwards
trend in Australia during 2020, down 13.2%, from Solar Choice
Price Index, cited in idem.
144 Figure of 2.7 million from Clean Energy Council, op. cit. note 12, p.
74; more than 2.66 million from Clean Energy Regulator, cited in
Australian Energy Council, op. cit. note 135, p. 3.
145 APVI, op. cit. note 138.
146 First to face zero operational demand from G. Parkinson, “South
Australia fast-tracks energy plan to dodge blackouts and meet
100% renewables goal”, RenewEconomy, 19 June 2020, https://
reneweconomy.com.au/south-australia-fast-tracks-energy-plan-
to-dodge-blackouts-and-meet-100-renewables-goal-43196;
other information from J. Deign, “How South Australia is dealing
with rampant solar growth”, Greentech Media, 21 September
2020, https://www.greentechmedia.com/articles/read/how-
south-australia-is-dealing-with-rampant-solar-growth. See also
Clean Energy Council, op. cit. note 12, pp. 18, 71. Rooftop solar
PV met more than 70% of South Australia’s electricity demand at
times during 2020 and, in October, became the world’s first major
jurisdiction to be powered entirely by solar power for one hour;
77% of this was from rooftop systems, from idem, pp. 18, 71.
147 Clean Energy Council, op. cit. note 12, p. 34; N. Harmsen, “Power
granted to switch off household solar in SA to prevent statewide
blackout”, ABC News (Australia), 18 June 2020, https://www.abc.
net.au/news/2020-06-19/solar-boom-puts-sa-at-risk-of-another-
statewide-blackout/12372558. Energy authorities in South Australia
used their power to switch off residential solar systems remotely
for the first time in March 2021, from D. Keane, N. Harmsen and
S. Tomevska, “Solar panels switched off by energy authorities to
stabilise South Australian electricity grid”, ABC News (Australia),
17 March 2021, https://www.abc.net.au/news/2021-03-17/solar-
panels-switched-off-in-sa-to-stabilise-grid/13256572. Several
states (including Victoria, Western Australia and New South Wales)
also announced a number of large battery storage projects in 2020,
from Clean Energy Council, op. cit. note 12, p. 56.
148 See, for example, B. Matich, “Small-scale utility solar thriving
on path of least resistance”, pv magazine, 28 February 2020,
https://www.pv-magazine-australia.com/2020/02/28/
small-scale-utility-solar-thriving-on-path-of-least-resistance.
149 Grid challenges from, for example, J. Scully, “1GW of Australian
solar at risk of curtailment following system strength warning”,
PV-Tech, 28 July 2020, https://www.pv-tech.org/system-
strength-issues-in-north-queensland-could-result-in-1gw-of-
solar-cur; S. Vorrath, “Grid problems now the biggest turnoff
for renewable energy investment in Australia”, RenewEconomy,
29 July 2020, https://reneweconomy.com.au/grid-problems-
now-the-biggest-turnoff-for-renewable-energy-investment-in-
australia-73144; lack of policy and target clarity, and regulatory
risks, from T. Gunaratna, Clean Energy Council, Australia,
personal communication with REN21, 11 April 2021, and from M.
Maisch, “Renewables investment collapses due to network woes
and policy uncertainty”, pv magazine, 1 February 2020, https://
www.pv-magazine-australia.com/2020/02/01/renewables-
investment-collapses-due-to-network-woes-and-policy-
uncertainty; barriers to investment, delayed and cancelled projects
from G. Parkinson, “Victoria’s biggest solar farm starts sending
power to grid after long delays”, RenewEconomy, 9 September
2020, https://reneweconomy.com.au/victorias-biggest-solar-farm-
starts-sending-power-to-grid-after-long-delays-80694. See also
P. Hannam, “’Murray Five’ solar farms get approval to resume full
energy output”, Sydney Morning Herald, 24 April 2020, https://
www.smh.com.au/business/markets/murray-five-solar-farms-get-
approval-to-resume-full-energy-output-20200424-p54n2b.html.
308
https://cleantechnica.com/2020/12/05/400000-solar-co-owners-in-giant-community-solar-park-initiative-in-denmark-poland
https://cleantechnica.com/2020/12/05/400000-solar-co-owners-in-giant-community-solar-park-initiative-in-denmark-poland
https://cleantechnica.com/2020/12/05/400000-solar-co-owners-in-giant-community-solar-park-initiative-in-denmark-poland
https://www.renewableenergymagazine.com/pv_solar/lithuania-welcomes-worlda-s-first-online-consumer-20200325
https://www.renewableenergymagazine.com/pv_solar/lithuania-welcomes-worlda-s-first-online-consumer-20200325
https://cleantechnica.com/2020/10/09/largest-rooftop-solar-system-in-europe-goes-online-on-audi-factory
https://cleantechnica.com/2020/10/09/largest-rooftop-solar-system-in-europe-goes-online-on-audi-factory
https://www.energycouncil.com.au/media/jv4blk2l/final-pdf-australian-energy-council-solar-report_-jan-2021
https://www.energycouncil.com.au/media/jv4blk2l/final-pdf-australian-energy-council-solar-report_-jan-2021
https://www.energycouncil.com.au/media/jv4blk2l/final-pdf-australian-energy-council-solar-report_-jan-2021
https://www.sunwiz.com.au/end-of-year-forecast-for-the-australian-pv-solar-market-2020
https://www.sunwiz.com.au/end-of-year-forecast-for-the-australian-pv-solar-market-2020
https://www.sunwiz.com.au/end-of-year-forecast-for-the-australian-pv-solar-market-2020
https://www.pv-magazine-australia.com/2020/07/23/australias-renewables-pipeline-continues-to-grow-at-record-speed-led-by-solar-pv
https://www.pv-magazine-australia.com/2020/07/23/australias-renewables-pipeline-continues-to-grow-at-record-speed-led-by-solar-pv
https://www.pv-magazine-australia.com/2020/07/23/australias-renewables-pipeline-continues-to-grow-at-record-speed-led-by-solar-pv
https://www.energynetworks.com.au/news/energy-insider/2020-energy-insider/bushfire-recovery-more-than-just-new-poles
https://www.energynetworks.com.au/news/energy-insider/2020-energy-insider/bushfire-recovery-more-than-just-new-poles
https://www.energynetworks.com.au/news/energy-insider/2020-energy-insider/bushfire-recovery-more-than-just-new-poles
https://pv-map.apvi.org.au/analyses
https://pv-map.apvi.org.au/analyses
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2021
https://www.pv-magazine.com/2021/02/08/australia-deployed-2-6-gw-of-rooftop-pv-in-2020
https://www.pv-magazine.com/2021/02/08/australia-deployed-2-6-gw-of-rooftop-pv-in-2020
https://www.renewableenergyworld.com/solar/what-is-driving-record-rooftop-solar-volumes-in-australia
https://www.renewableenergyworld.com/solar/what-is-driving-record-rooftop-solar-volumes-in-australia
https://www.greentechmedia.com/articles/read/what-the-us-can-learn-from-australias-roaring-rooftop-solar-market
https://www.greentechmedia.com/articles/read/what-the-us-can-learn-from-australias-roaring-rooftop-solar-market
https://www.greentechmedia.com/articles/read/what-the-us-can-learn-from-australias-roaring-rooftop-solar-market
https://www.pv-magazine.com/2020/03/19/forget-toilet-paper-australians-are-panic-buying-pv
https://www.pv-magazine.com/2020/03/19/forget-toilet-paper-australians-are-panic-buying-pv
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://www.greentechmedia.com/articles/read/how-south-australia-is-dealing-with-rampant-solar-growth
https://www.greentechmedia.com/articles/read/how-south-australia-is-dealing-with-rampant-solar-growth
https://www.abc.net.au/news/2020-06-19/solar-boom-puts-sa-at-risk-of-another-statewide-blackout/12372558
https://www.abc.net.au/news/2020-06-19/solar-boom-puts-sa-at-risk-of-another-statewide-blackout/12372558
https://www.abc.net.au/news/2020-06-19/solar-boom-puts-sa-at-risk-of-another-statewide-blackout/12372558
https://www.abc.net.au/news/2021-03-17/solar-panels-switched-off-in-sa-to-stabilise-grid/13256572
https://www.abc.net.au/news/2021-03-17/solar-panels-switched-off-in-sa-to-stabilise-grid/13256572
https://www.pv-magazine-australia.com/2020/02/28/small-scale-utility-solar-thriving-on-path-of-least-resistance
https://www.pv-magazine-australia.com/2020/02/28/small-scale-utility-solar-thriving-on-path-of-least-resistance
https://www.pv-tech.org/system-strength-issues-in-north-queensland-could-result-in-1gw-of-solar-cur
https://www.pv-tech.org/system-strength-issues-in-north-queensland-could-result-in-1gw-of-solar-cur
https://www.pv-tech.org/system-strength-issues-in-north-queensland-could-result-in-1gw-of-solar-cur
https://reneweconomy.com.au/grid-problems-now-the-biggest-turnoff-for-renewable-energy-investment-in-australia-73144
https://reneweconomy.com.au/grid-problems-now-the-biggest-turnoff-for-renewable-energy-investment-in-australia-73144
https://reneweconomy.com.au/grid-problems-now-the-biggest-turnoff-for-renewable-energy-investment-in-australia-73144
https://www.pv-magazine-australia.com/2020/02/01/renewables-investment-collapses-due-to-network-woes-and-policy-uncertainty
https://www.pv-magazine-australia.com/2020/02/01/renewables-investment-collapses-due-to-network-woes-and-policy-uncertainty
https://www.pv-magazine-australia.com/2020/02/01/renewables-investment-collapses-due-to-network-woes-and-policy-uncertainty
https://www.pv-magazine-australia.com/2020/02/01/renewables-investment-collapses-due-to-network-woes-and-policy-uncertainty
https://reneweconomy.com.au/victorias-biggest-solar-farm-starts-sending-power-to-grid-after-long-delays-80694
https://reneweconomy.com.au/victorias-biggest-solar-farm-starts-sending-power-to-grid-after-long-delays-80694
https://www.smh.com.au/business/markets/murray-five-solar-farms-get-approval-to-resume-full-energy-output-20200424-p54n2b.html
https://www.smh.com.au/business/markets/murray-five-solar-farms-get-approval-to-resume-full-energy-output-20200424-p54n2b.html
https://www.smh.com.au/business/markets/murray-five-solar-farms-get-approval-to-resume-full-energy-output-20200424-p54n2b.html
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150 Matich, op. cit. note 148; M. Maisch, “Victoria decides to go it
alone on transmission to unlock more large-scale renewables
and batteries”, pv magazine, 19 February 2020, https://www.
pv-magazine-australia.com/2020/02/19/victoria-decides-to-
go-it-alone-on-transmission-to-unlock-more-large-scale-
renewables-and-batteries.
151 N. Filatoff, “The weekend read: The plan to REZurrect Australia’s
large-scale segment”, pv magazine, 17 October 2020, https://
www.pv-magazine-australia.com/2020/10/17/the-weekend-
read-the-plan-to-rezurrect-australias-large-scale-segment. The
government of New South Wales was the first to call for interest
in a proposed 3 GW REZ; after receiving 27 GW of bids, the state
announced an additional 8 GW REZ, from idem. See also Clean
Energy Council, op. cit. note 12, p. 7.
152 Matich, op. cit. note 148.
153 New Zealand from T. Niall, “Biggest solar farm in country installed
on Auckland wastewater lake”, stuff, 2 October 2020, https://
www.stuff.co.nz/environment/climate-news/122936916/biggest-
solar-farm-in-country-installed-on-auckland-wastewater-lake.
Solar PV and electricity storage are advancing on the Cook
Islands, from E. Bellini, “Solar-plus-storage for the Cook Islands”,
pv magazine, 7 September 2020, https://www.pv-magazine.
com/2020/09/07/solar-plus-storage-for-the-cook-islands; the
Fijian government-owned utility signed an agreement with the
International Finance Corporation (IFC) for a 15 MW solar PV
project to reduce reliance on imported fuels, from J. S. Hill, “Fiji set
to build biggest solar project in Pacific Islands”, RenewEconomy,
28 October 2020, https://reneweconomy.com.au/fiji-set-to-
build-biggest-solar-project-in-pacific-islands-37084, and has
seen rapid growth in behind-the-meter commercial rooftop
systems since 2015, with about 4 MW installed by early 2020
and many more systems planned, from R. D. Prasad and
A. Raturi, Solar Energy for Power Generation in Fiji: History,
Barriers and Potentials, in A. Singh, ed., Translating the Paris
Agreement into Action in the Pacific. Advances in Global Change
Research, vol. 68 (January 2020), https://link.springer.com/
chapter/10.1007/978-3-030-30211-5_8. Micronesia launched
a tender for utility-scale solar-plus-storage capacity, from E.
Bellini, “Micronesia launches tender for utility scale solar-plus-
storage”, pv magazine, 12 May 2020, https://www.pv-magazine.
com/2020/05/12/micronesia-launches-tender-for-utility-scale-
solar-plus-storage. New Caledonia aims for 100% renewable
electricity by 2030 and was developing an agricultural-solar
PV project in 2020, from P. Zubrinich, “Agrivoltaics in New
Caledonia”, pv magazine, 28 February 2020, https://www.
pv-magazine-australia.com/2020/02/28/agrivoltaics-in-new-
caledonia; the country also saw the completion of a 16 MW solar
PV plant with 10 MW of storage in late 2019, to which another
solar-plus-storage facility will be added, from idem. Papua New
Guinea launched a pilot scheme allowing businesses to install
and operate grid-connected rooftop systems as part of the
country’s effort to achieve 100% renewable energy by 2050, from
“PNG’s first rooftop solar trial officially begins in Port Moresby”,
PNG Power, Ltd., 4 December 2019, https://www power.
com.pg/index.php/news/view/pngs-first-rooftop-solar-trial-
officially-begins-in-port-moresby. Tonga aims for 70% renewable
electricity by 2030 and signed contracts in 2020 for more
solar-plus-storage projects to provide 24-hour-a-day electricity
access, from J. S. Hill, “Tonga signs more solar/storage projects
as it aims for 70 pct renewables”, RenewEconomy, 21 April 2020,
https://reneweconomy.com.au/tonga-signs-more-solar-storage-
projects-as-it-aims-for-70-pct-renewables-49782.
154 Commercial rooftop systems from Prasad and Raturi, op. cit. note
153; in 2020 from IFC, “EFL and IFC sign agreement for Pacific’s
largest solar project”, press release (Suva, Fiji: 21 October 2020),
https://pressroom.ifc.org/all/pages/PressDetail.aspx?ID=17784,
and from Hill, op. cit. note 153.
155 Bellini, op. cit. note 153.
156 Based on 4.1 GW added for a total of around 24 GW, from
Becquerel Institute, op. cit. note 1, 26 May 2021; and on 4.3
GW of solar additions across the Middle East and North Africa
region in 2020, from BloombergNEF, cited in MESIA, “MESIA
Solar Outlook Report 2021 – Did a challenging year open up
future opportunities for solar?” 19 January 2021, https://mesia.
com/2021/01/19/mesia-solar-outlook-report-2021-did-a-
challenging-year-open-up-future-opportunities-for-solar. In 2019,
additions were an estimated 6.8 GW (up from 3.1 GW in 2018),
from SolarPower Europe, op. cit. note 9, p. 18; and 2019 additions
were an estimated 6.7 GW in 2019, for a year-end total of 15.1 GW,
from IEA PVPS, Snapshot of Global PV Markets 2020, op. cit. note
9, and from Becquerel Institute, op. cit. note 9, 10 April 2020. In
2018, the regions added an estimated 2,556 MW in 2018 for a
total of 6,716 MW, from Becquerel Institute, op. cit. note 1, April
2019. Another source estimates that about 3.6 GW was added
in 2018, up from less than 1 GW in 2017, from IHS Markit, cited in
J. Berg, “MENA PV additions quadrupled in 2018”, pv magazine,
17 January 2019, https://www.pv-magazine.com/2019/01/17/
mena-pv-additions-quadrupled-in-2018.
157 T. Smith, “Net-metering gaining favour throughout Middle East
and Africa”, ESI Africa, 12 August 2020, https://www.esi-africa.
com/industry-sectors/generation/solar/net-metering-gaining-
favour-throughout-middle-east-and-africa; Egypt from MESIA,
op. cit. note 13, p. 5.
158 MESIA, op. cit. note 13, p. 5; E. Bellini, “Israel launches 300 MW
solar-plus-storage tender”, pv magazine, 24 January 2020, https://
www.pv-magazine.com/2020/01/24/israeal-launches-tender-for-
300-mw-of-solar-plus-storage; E. Bellini, “Israel’s plan to recover
from Covid-19 crisis includes 2 GW of new solar”, pv magazine, 29
April 2020, https://www.pv-magazine.com/2020/04/29/israels-
plan-to-recover-from-covid-19-crisis-includes-2-gw-of-new-solar;
T. Smith, “Malawi gets new solar power plant to fill critical energy
gap”, ESI Africa, 6 November 2020, https://www.esi-africa.com/
industry-sectors/generation/solar/malawi-gets-new-solar-power-
plant-to-fill-critical-energy-gap; B. Groenendaal, “Malawi: 46MW
Nkhotakota Solar Power Plant reaches financial close”, GBA, 3
January 2020, https://www.greenbuildingafrica.co.za/malawi-
46mw-nkhotakota-solar-power-plant-reaches-financial-close;
Projects Today, “Nkhotakota Solar Power Plant receives USD 67
million subsidy”, 11 November 2020, https://projectstoday.com/
News/Nkhotakota-Solar-Power-Plant-receives-USD-67-million-
subsidy; R. Ranjan, “Syria to develop 63 MW of solar projects”,
Mercom India, 27 May 2020; Tunisia and United Arab Emirates
from MESIA, op. cit. note 13, p. 5; N. Pombo-van Zyl, “Zimbabwe
opens tender for solar power plants”, ESI Africa, 21 May 2020,
https://www.esi-africa.com/industry-sectors/generation/solar/
zimbabwe-opens-tender-for-solar-power-plants; Egypt cancelled
a 200 MW tender for solar plants along the Nile basin because
the pandemic reduced electricity demand, creating a surplus,
from “Egypt cancels tenders for setting up solar plants along Nile
basin”, TRENDSNAFRICA, 7 August 2020, http://trendsnafrica.
com/2020/08/07/egypt-cancels-tenders-for-setting-up-solar-
plants-along-nile-basin; N. Pombo-van Zyl, “Egypt scraps
West Nile solar tender as new PV assembly line is launched”,
PEI, 11 August 2020, https://www.powerengineeringint.com/
renewables/solar/egypt-scraps-west-nile-solar-tender-as-new-
pv-assembly-line-is-launched.
159 MESIA, op. cit. note 13, pp. 4, 9.
160 Ibid., pp. 4, 14.
161 Israel and Oman from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1; United Arab Emirates from “Mohammed bin
Rashid Al Maktoum Solar Park launches third phase in Dubai”,
Gulf News, 12 December 2020, https://gulfnews.com/uae/
mohammed-bin-rashid-al-maktoum-solar-park-launches-third-
phase-in-dubai-1.75855508, from R. Ranjan, “Third phase of
Dubai Solar Park with 800 MW of projects commissioned”, 25
November 2020, https://mercomindia.com/dubai-solar-park-
projects-commissioned, and from Dubai Electricity and Water
Authority (DEWA), “Mohammed bin Rashid inaugurates DEWA
Innovation Centre and 800MW 3rd phase of the Mohammed
bin Rashid Al Maktoum Solar Park”, 24 November 2020,
https://www.dewa.gov.ae/en/about-us/media-publications/
latest-news/2020/11/mohammed-bin-rashid-inaugurates-dewa-
innovation-centre. The total operational capacity of the solar park
by late 2020 was 1,013 MW, from DEWA, op. cit. this note.
162 UAE from Ibid., all sources; BELECTRIC, “BELECTRIC delivers
utility-scale PV plant on mountainous site in Jordan”, 7 April 2020,
https://belectric.com/belectric-delivers-utility-scale-pv-plant-
on-mountainous-site-in-jordan; U. Gupta, “Sterling and Wilson
commissions 125 MW (DC) solar plant in Oman”, pv magazine,
2 June 2020, https://www.pv-magazine-india.com/2020/06/02/
sterling-and-wilson-commissions-125-mw-dc-solar-project-in-
oman; Dubai and Oman also from MESIA, op. cit. note 13, pp. 5,
67.
163 Plans for solar and hydrogen project from E. Bellini, “Solar-
powered hydrogen generation hub in Oman”, pv magazine, 4
November 2020, https://www.pv-magazine.com/2020/11/04/
309
https://www.pv-magazine-australia.com/2020/02/19/victoria-decides-to-go-it-alone-on-transmission-to-unlock-more-large-scale-renewables-and-batteries
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https://www.pv-magazine-australia.com/2020/02/19/victoria-decides-to-go-it-alone-on-transmission-to-unlock-more-large-scale-renewables-and-batteries
https://www.pv-magazine-australia.com/2020/02/19/victoria-decides-to-go-it-alone-on-transmission-to-unlock-more-large-scale-renewables-and-batteries
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https://pressroom.ifc.org/all/pages/PressDetail.aspx?ID=17784
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https://mesia.com/2021/01/19/mesia-solar-outlook-report-2021-did-a-challenging-year-open-up-future-opportunities-for-solar
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https://projectstoday.com/News/Nkhotakota-Solar-Power-Plant-receives-USD-67-million-subsidy
https://projectstoday.com/News/Nkhotakota-Solar-Power-Plant-receives-USD-67-million-subsidy
https://www.esi-africa.com/industry-sectors/generation/solar/zimbabwe-opens-tender-for-solar-power-plants
https://www.esi-africa.com/industry-sectors/generation/solar/zimbabwe-opens-tender-for-solar-power-plants
http://trendsnafrica.com/2020/08/07/egypt-cancels-tenders-for-setting-up-solar-plants-along-nile-basin
http://trendsnafrica.com/2020/08/07/egypt-cancels-tenders-for-setting-up-solar-plants-along-nile-basin
http://trendsnafrica.com/2020/08/07/egypt-cancels-tenders-for-setting-up-solar-plants-along-nile-basin
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https://www.powerengineeringint.com/renewables/solar/egypt-scraps-west-nile-solar-tender-as-new-pv-assembly-line-is-launched
https://www.powerengineeringint.com/renewables/solar/egypt-scraps-west-nile-solar-tender-as-new-pv-assembly-line-is-launched
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https://gulfnews.com/uae/mohammed-bin-rashid-al-maktoum-solar-park-launches-third-phase-in-dubai-1.75855508
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https://www.dewa.gov.ae/en/about-us/media-publications/latest-news/2020/11/mohammed-bin-rashid-inaugurates-dewa-innovation-centre
https://www.dewa.gov.ae/en/about-us/media-publications/latest-news/2020/11/mohammed-bin-rashid-inaugurates-dewa-innovation-centre
https://www.dewa.gov.ae/en/about-us/media-publications/latest-news/2020/11/mohammed-bin-rashid-inaugurates-dewa-innovation-centre
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https://www.pv-magazine-india.com/2020/06/02/sterling-and-wilson-commissions-125-mw-dc-solar-project-in-oman
https://www.pv-magazine-india.com/2020/06/02/sterling-and-wilson-commissions-125-mw-dc-solar-project-in-oman
https://www.pv-magazine-india.com/2020/06/02/sterling-and-wilson-commissions-125-mw-dc-solar-project-in-oman
https://www.pv-magazine.com/2020/11/04/solar-powered-hydrogen-generation-hub-in-oman
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR PV
solar-powered-hydrogen-generation-hub-in-oman; M. Willuhn,
“Shell to develop PV at Oman’s Sohar Port and Freezone
area”, pv magazine, 26 April 2019, https://www.pv-magazine.
com/2019/04/26/shell-to-develop-pv-at-omans-sohar-port-and-
freezone-area; rooftop solar PV from MESIA, op. cit. note 13, p.
18, and from C. Prabhu, “Solar PV for first 1000 homes in Oman”,
Oman Observer, 24 April 2020, https://www.omanobserver.om/
solar-pv-for-first-1000-homes-in-oman.
164 MESIA, op. cit. note 13, p. 18.
165 Ibid. Other countries in the region include Bahrain, Iraq, Jordan
and Kuwait, from idem.
166 United Arab Emirates and Israel based on data from IEA PVPS,
Snapshot of Global PV Markets 2021, op. cit. note 1, and from
Becquerel Institute, op. cit. note 1. Note that data are uncertain,
particularly for the United Arab Emirates. Jordan ended 2020
with 1,545 MW, from Jordanian Ministry of Energy and Mineral
Resources, provided by M. Mahmoud, Regional Center for
Renewable Energy and Energy Efficiency (RCREEE), Cairo,
personal communication with REN21, 28 May 2021.
167 For example, Algeria aims to become self-reliant for energy and
to save petrochemical researched for local activities, from the
Democratic Republic of Algeria, Governorate for Renewable
energy and Energy Efficiency (CEREFE), “Transition énergétique
en Algérie – Le mot du Premier Ministre sur le Premier Rapport du
Commissariat sur la Transition Energétique”, http://www.cerefe.
gov.dz/fr/2020/11/29/transition-energetique-en-algerie, viewed
31 May 2021. Malawi aims to shift reliance away from hydropower
(now more than 90% of the country’s energy mix), which leaves
the country vulnerable to frequent power supply cuts during
droughts, from Smith, “Malawi gets new solar power plant to fill
critical energy gap”, op. cit. note 158; Groenendaal, op. cit. note 158;
Projects Today, op. cit. note 158. Mali has similar concerns, from
T. Smith, “Mali: New solar plant just the beginning”, ESI Africa, 23
November 2020, https://www.esi-africa.com/industry-sectors/
generation/solar/mali-new-solar-plant-just-the-beginning; B.
Bungane, “Mali to host West Africa’s largest solar farm with 50MW
capacity”, ESI Africa, 20 January 2020, https://www.esi-africa.com/
industry-sectors/generation/mali-to-host-west-africas-largest-
solar-farm-with-50mw-capacity. As does Zimbabwe from N.
Pombo-van Zyl, “Zimbabwe opens tender for solar power plants”,
op. cit. note 158. In South Africa, several mining companies have
installed or are planning their own solar PV plants to ensure a
reliable supply of electricity, from E. Bellini, “South African mining
sector wants solar”, pv magazine, 31 January 2020, https://www.
pv-magazine-australia.com/2020/01/31/south-african-mining-
sector-wants-solar. The Algerian government aims to preserve
domestic oil and gas resources while meeting rising domestic
demand for energy and becoming a net exporter of competitively-
priced electricity, from I. Magoum, “ALGERIA: 4000 MW Tafouk1
solar mega-project soon to be on track”, Afrik21, 26 May 2020,
https://www.afrik21.africa/en/algeria-4000-mw-tafouk1-solar-
mega-project-soon-to-be-on-track; P. Largue, “Algeria announces
4GW plan to grow solar capacity ten-fold by 2025”, ESI Africa,
25 May 2020, https://www.esi-africa.com/industry-sectors/
generation/solar/algeria-announces-4gw-plan-to-grow-solar-
capacity-ten-fold-by-2025. Batteries from, for example, SolarPower
Europe, Global Market Outlook for Solar Power 2020-2024, op. cit.
note 9, p. 18; T. Smith, “Mali: Solar forecasting for energy stability
at mine”, ESI Africa, 29 July 2020, https://www.esi-africa.com/
industry-sectors/generation/solar/mali-solar-forecasting-for-
energy-stability-at-mine. See also Africa Solar Industry Association
(AFSIA), Africa Solar Outlook 2021 – A Country-by-Country Review
of the Status of Solar in Africa (Kigali, Rwanda: 2021), http://
afsiasolar.com/wp-content/uploads/2021/02/AFSIA-Africa-Solar-
Outlook-2021-final-2 .
168 J. R. Martín, “African leaders enlist renewables to build future of
energy resilience”, PV-Tech, 20 April 2020, https://www.pv-tech.
org/african-leaders-enlist-renewables-to-build-future-of-energy-
resilience.
169 SolarPower Europe, Global Market Outlook for Solar Power
2020-2024, op. cit. note 9, p. 39. Financing tools and tenders from
Institut Montaigne, cited in E. Bellini, “Unrealistic price signals
and an explosion of tenders hinder African PV”, pv magazine,
13 January 2020, https://www.pv-magazine.com/2020/01/13/
unrealistic-price-signals-and-an-explosion-of-tenders-hinder-
african-pv; financing and bankability in sub-Saharan Africa from
Nyokabi, op. cit. note 15; fossil fuel subsidies from, for example, B.
Publicover, “Solar is gaining traction in MENA region – but plenty
of obstacles remain”, pv magazine, 17 January 2020, https://www.
pv-magazine.com/2020/01/17/mesia-outlines-past-progress-
future-promise-in-sweeping-look-at-solar-across-middle-
east-and-north-africa; subsidies as well as social and political
unrest from Mints, op. cit. note 25,p. 12. See also G. Schwerhoff
and M. Sy, “Where the sun shines: Renewable energy sources,
especially solar, are ideal for meeting Africa’s electrical power
needs”, International Monetary Fund, Finance & Development,
vol. 57, no. 1 (March 2020), https://www.imf.org/external/pubs/ft/
fandd/2020/03/powering-Africa-with-solar-energy-sy.htm.
170 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 18; AFSIA, op. cit. note 167, p. 27.
171 Smith, “Mali: New solar plant just the beginning”, op. cit. note 167;
Bungane, op. cit. note 167.
172 Egypt from IEA PVPS, Snapshot of Global PV Markets 2021, op.
cit. note 1, and from Becquerel Institute, op. cit. note 1; Ethiopia
from IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note
1, p. 15; B. Bungane, “Two solar plants to bring power to Ghana’s
Upper West Region”, ESI Africa, 6 February 2020, https://www.
esi-africa.com/industry-sectors/generation/two-solar-plants-to-
bring-power-to-ghanas-upper-west-region; B. Bungane, “Ghana’s
president commissions 6.5MW Lawra solar power plant”, ESI Africa,
12 October 2020, https://www.esi-africa.com/industry-sectors/
renewable-energy/ghanas-president-commissions-6-5mw-lawra-
solar-power-plant; Somalia commissioned an 8 MW ground-
mounted plant in Mogadishu, from Nextier Power, “New photovoltaic
solar power plants in Mogadishu, Somalia”, Nigeria Electricity Hub,
9 June 2020, https://www.nigeriaelectricityhub.com/2020/06/09/
new-photovoltaic-solar-power-plant-in-mogadishu-somalia; Scatec,
“Another 86 MW of Scatec Solar’s 258 MW solar power complex in
South Africa in commercial operation”, 25 February 2020, https://
scatec.com/2020/02/25/another-86-mw-of-scatec-solars-258-
mw-solar-power-complex-in-south-africa-in-commercial-operation;
Scatec, “Scatec Solar’s 258 MW Upington project in South
Africa completed”, 6 April 2020, https://scatec.com/2020/04/06/
scatec-solars-258-mw-upington-project-in-south-africa-completed.
173 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 110; MESIA, op. cit. note 13, pp. 18, 51.
174 Israel and Algeria from IEA PVPS, Snapshot of Global PV Markets
2021, op. cit. note 1, and from Becquerel Institute, op. cit. note 1.
Egypt based on the following: 1.5 GW added for a total of 3.1 GW
(and assumption that official data for the Benban complex are
in AC), from idem, both sources, and from Masson, op. cit. note
1; 1,673 MW based on unofficial sources and cited in IRENA, op.
cit. note 1; 1,623 MW, of which 1,465 MW is the Benban solar
complex, from Egypt’s New & Renewable Energy Authority
(NREA), NREAmeter, January 2021, http://nrea.gov.eg/Media/
New/1280, viewed 26 May 2021; and 1,720 MWp large-scale
capacity plus 43.5 MW other, from AFSIA, op. cit. note 167, p. 32.
175 IEA PVPS, Snapshot of Global PV Markets 2021, op. cit. note 1, p. 12;
Becquerel Institute, op. cit. note 1. The utility-scale share declined
from 64.6% in 2019 to 59.6% in 2020, from idem, both sources.
176 Increase in new utility-scale capacity from IEA PVPS, Snapshot of
Global PV Markets 2021, op. cit. note 1, p. 12.
177 See, for example, Clean Energy Council, op. cit. note 12, p. 77; G.
Barbose and N. Darghouth, Tracking the Sun, Pricing and Design
Trends for Distributed Photovoltaic Systems in the United States
2019 Edition (Berkeley, CA: LBNL, October 2019), p. 1, https://emp.
lbl.gov/sites/default/files/tracking_the_sun_2019_report ;
E. Bellini, “Italy deployed 737 MW of solar in 2019”, pv magazine,
21 April 2020, https://www.pv-magazine.com/2020/04/21/italy-
deployed-737-mw-of-solar-in-2019. In Australia, for example, the
average size of small-scale (up to 100 kW) rooftop systems was
8.04 kW in 2020, up from 1.97 kW in 2010, 4.99 kW in 2015, and
7.72 kW in 2019, from Clean Energy Council, op. cit. note 12.
178 Tendering from IEA PVPS, Snapshot of Global PV Markets 2020,
op. cit. note 9, p. 11; tendering and PPAs from SolarPower Europe,
Global Market Outlook for Solar Power, 2019-2023, op. cit. note 7, p.
25. It is easier to deploy large amounts of capacity when in utility-
scale projects rather than distributed rooftop, which is why many
countries with emerging markets start with tenders for large
projects, from SolarPower Europe, Global Market Outlook for Solar
Power 2020-2024, op. cit. note 9, p. 33; PPAs also from Wiki-Solar,
“Utility-scale solar surges to yet another record year”, 12 January
2021, https://wiki-solar.org/library/public/210112_Utility-scale_
notches_up_another_record_year ; reduce price through
economies of scale from J. Petri, “Solar has finally gone off the
310
https://www.pv-magazine.com/2020/11/04/solar-powered-hydrogen-generation-hub-in-oman
https://www.pv-magazine.com/2019/04/26/shell-to-develop-pv-at-omans-sohar-port-and-freezone-area
https://www.pv-magazine.com/2019/04/26/shell-to-develop-pv-at-omans-sohar-port-and-freezone-area
https://www.pv-magazine.com/2019/04/26/shell-to-develop-pv-at-omans-sohar-port-and-freezone-area
https://www.omanobserver.om/solar-pv-for-first-1000-homes-in-oman
https://www.omanobserver.om/solar-pv-for-first-1000-homes-in-oman
http://www.cerefe.gov.dz/fr/2020/11/29/transition-energetique-en-algerie
http://www.cerefe.gov.dz/fr/2020/11/29/transition-energetique-en-algerie
https://www.esi-africa.com/industry-sectors/generation/solar/mali-new-solar-plant-just-the-beginning
https://www.esi-africa.com/industry-sectors/generation/solar/mali-new-solar-plant-just-the-beginning
https://www.esi-africa.com/industry-sectors/generation/mali-to-host-west-africas-largest-solar-farm-with-50mw-capacity
https://www.esi-africa.com/industry-sectors/generation/mali-to-host-west-africas-largest-solar-farm-with-50mw-capacity
https://www.esi-africa.com/industry-sectors/generation/mali-to-host-west-africas-largest-solar-farm-with-50mw-capacity
https://www.pv-magazine-australia.com/2020/01/31/south-african-mining-sector-wants-solar
https://www.pv-magazine-australia.com/2020/01/31/south-african-mining-sector-wants-solar
https://www.pv-magazine-australia.com/2020/01/31/south-african-mining-sector-wants-solar
https://www.afrik21.africa/en/algeria-4000-mw-tafouk1-solar-mega-project-soon-to-be-on-track
https://www.afrik21.africa/en/algeria-4000-mw-tafouk1-solar-mega-project-soon-to-be-on-track
https://www.esi-africa.com/industry-sectors/generation/solar/algeria-announces-4gw-plan-to-grow-solar-capacity-ten-fold-by-2025
https://www.esi-africa.com/industry-sectors/generation/solar/algeria-announces-4gw-plan-to-grow-solar-capacity-ten-fold-by-2025
https://www.esi-africa.com/industry-sectors/generation/solar/algeria-announces-4gw-plan-to-grow-solar-capacity-ten-fold-by-2025
https://www.esi-africa.com/industry-sectors/generation/solar/mali-solar-forecasting-for-energy-stability-at-mine
https://www.esi-africa.com/industry-sectors/generation/solar/mali-solar-forecasting-for-energy-stability-at-mine
https://www.esi-africa.com/industry-sectors/generation/solar/mali-solar-forecasting-for-energy-stability-at-mine
http://afsiasolar.com/wp-content/uploads/2021/02/AFSIA-Africa-Solar-Outlook-2021-final-2
http://afsiasolar.com/wp-content/uploads/2021/02/AFSIA-Africa-Solar-Outlook-2021-final-2
http://afsiasolar.com/wp-content/uploads/2021/02/AFSIA-Africa-Solar-Outlook-2021-final-2
https://www.pv-tech.org/african-leaders-enlist-renewables-to-build-future-of-energy-resilience
https://www.pv-tech.org/african-leaders-enlist-renewables-to-build-future-of-energy-resilience
https://www.pv-tech.org/african-leaders-enlist-renewables-to-build-future-of-energy-resilience
https://www.pv-magazine.com/2020/01/13/unrealistic-price-signals-and-an-explosion-of-tenders-hinder-african-pv
https://www.pv-magazine.com/2020/01/13/unrealistic-price-signals-and-an-explosion-of-tenders-hinder-african-pv
https://www.pv-magazine.com/2020/01/13/unrealistic-price-signals-and-an-explosion-of-tenders-hinder-african-pv
https://www.pv-magazine.com/2020/01/17/mesia-outlines-past-progress-future-promise-in-sweeping-look-at-solar-across-middle-east-and-north-africa
https://www.pv-magazine.com/2020/01/17/mesia-outlines-past-progress-future-promise-in-sweeping-look-at-solar-across-middle-east-and-north-africa
https://www.pv-magazine.com/2020/01/17/mesia-outlines-past-progress-future-promise-in-sweeping-look-at-solar-across-middle-east-and-north-africa
https://www.pv-magazine.com/2020/01/17/mesia-outlines-past-progress-future-promise-in-sweeping-look-at-solar-across-middle-east-and-north-africa
https://www.imf.org/external/pubs/ft/fandd/2020/03/powering-Africa-with-solar-energy-sy.htm
https://www.imf.org/external/pubs/ft/fandd/2020/03/powering-Africa-with-solar-energy-sy.htm
https://www.esi-africa.com/industry-sectors/generation/two-solar-plants-to-bring-power-to-ghanas-upper-west-region
https://www.esi-africa.com/industry-sectors/generation/two-solar-plants-to-bring-power-to-ghanas-upper-west-region
https://www.esi-africa.com/industry-sectors/generation/two-solar-plants-to-bring-power-to-ghanas-upper-west-region
https://www.esi-africa.com/industry-sectors/renewable-energy/ghanas-president-commissions-6-5mw-lawra-solar-power-plant
https://www.esi-africa.com/industry-sectors/renewable-energy/ghanas-president-commissions-6-5mw-lawra-solar-power-plant
https://www.esi-africa.com/industry-sectors/renewable-energy/ghanas-president-commissions-6-5mw-lawra-solar-power-plant
https://www.nigeriaelectricityhub.com/2020/06/09/new-photovoltaic-solar-power-plant-in-mogadishu-somalia
https://www.nigeriaelectricityhub.com/2020/06/09/new-photovoltaic-solar-power-plant-in-mogadishu-somalia
https://scatec.com/2020/02/25/another-86-mw-of-scatec-solars-258-mw-solar-power-complex-in-south-africa-in-commercial-operation
https://scatec.com/2020/02/25/another-86-mw-of-scatec-solars-258-mw-solar-power-complex-in-south-africa-in-commercial-operation
https://scatec.com/2020/02/25/another-86-mw-of-scatec-solars-258-mw-solar-power-complex-in-south-africa-in-commercial-operation
https://scatec.com/2020/04/06/scatec-solars-258-mw-upington-project-in-south-africa-completed
https://scatec.com/2020/04/06/scatec-solars-258-mw-upington-project-in-south-africa-completed
http://nrea.gov.eg/Media/New/1280
http://nrea.gov.eg/Media/New/1280
https://emp.lbl.gov/sites/default/files/tracking_the_sun_2019_report
https://emp.lbl.gov/sites/default/files/tracking_the_sun_2019_report
https://www.pv-magazine.com/2020/04/21/italy-deployed-737-mw-of-solar-in-2019
https://www.pv-magazine.com/2020/04/21/italy-deployed-737-mw-of-solar-in-2019
https://wiki-solar.org/library/public/210112_Utility-scale_notches_up_another_record_year
https://wiki-solar.org/library/public/210112_Utility-scale_notches_up_another_record_year
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scale”, Bloomberg, 28 February 2020, https://www.bloomberg.
com/news/articles/2020-02-28/solar-power-has-finally-gone-
off-the-scale-green-insight; “Iberdrola jumps from giant PV
project to new build blitz”, Reuters Events, 27 February 2020,
https://analysis.newenergyupdate.com/pv-insider/iberdrola-
jumps-giant-pv-project-new-build-blitz; “Texas solar owners
face price risks after building boom”, 17 February 2020, Reuters
Events, https://www.reutersevents.com/renewables/solar-pv/
texas-solar-owners-face-price-risks-after-building-boom.
179 Figures of about 80 plants, exceeding 21 GW, figure of 49
countries (and Mali and Oman), based on database provided
by D. Lenardič, pvresources, Jesenice, Slovenia, personal
communication with REN21, 31 March 2021. The total is at least 78
plants, not including three in Spain that were between 49 and 50
MW, from idem.
180 Based on data from Ibid., 31 March 2021 and 12 April 2021. Note
that this includes some projects for which a portion of capacity
was commissioned in previous years. This is down from an
estimate of 35 in 2019, from Petri, op. cit. note 178.
181 Spain from “Iberdrola jumps from giant PV project to new build
blitz”, op. cit. note 178; Iberdrola, “Núñez de Balboa, operational:
Iberdrola commissions Europe’s largest photovoltaic plant”, 6
April 2020, https://www.iberdrola.com/press-room/news/detail/
nunez-balboa-operational-iberdrola-commissions-europe-
s-largest-photovoltaic-plant; P. Sanjay, “With 2,245 MW of
commissioned solar projects, world’s largest solar park is now at
Bhadla”, Mercom India, 19 March 2020, https://mercomindia.com/
world-largest-solar-park-bhadla; Saurabh, “2.2 gigawatt solar park
in India’s Rajasthan State now fully operational”, CleanTechnica, 30
March 2020, https://cleantechnica.com/2020/03/30/2-2-gigawatt-
solar-park-in-indias-rajasthan-state-now-fully-operational. Bhadla
was still the world’s largest at the end of 2020, as confirmed by
Lenardič, op. cit. note 179, 31 March 2021. In late 2020, work began
on India’s Kutch hybrid renewable energy park in Gujarat, which
is planned to have 41.5 GW of solar and wind power capacity
when completed, from PSU Watch Bureau, “Work begins on
world’s largest hybrid RE park in Gujarat’s Kutch. Know all about
it here”, PSU Watch, 15 December 2020, https://psuwatch.com/
work-begins-world-largest-hybrid-re-park-gujarat-kutch.
182 See, for example: Hungary from E. Bellini, “100 MW solar park
comes online in eastern central Europe”, pv magazine, 14
December 2020, https://www.pv-magazine.com/2020/12/14/100-
mw-solar-park-comes-online-in-eastern-central-europe;
“Largest solar plant in Italy plugs into the grid”, reNEWS, 25 June
2020, https://www.renews.biz/61222/largest-solar-plant-in-
italy-plugs-into-the-grid; P. Sanchez Molina, “Large-scale solar
deployment picks up in Spain”, pv magazine, 11 September 2020,
https://www.pv-magazine.com/2020/09/11/large-scale-solar-
deployment-picks-up-in-spain; J. Parnell, “UK’s largest solar
project approved, will snub government subsidies”, Greentech
Media, 29 May 2020, https://www.greentechmedia.com/articles/
read/uks-largest-solar-plus-storage-project-gets-greenlight-
now-the-hard-work-starts; United States from Saur News Bureau,
op. cit. note 85; “Invenergy fires up 160MW Southern Oak”,
reNEWS, 30 April 2020, https://renews.biz/60011/invenergy-
starts-up-160mw-solar-plant; “Colorado Springs Utilities brings
60 MW of solar energy online”, Renewable Energy World, 20 April
2020, https://www.renewableenergyworld.com/2020/04/20/
colorado-springs-utilities-brings-60-mw-of-solar-energy-online;
“Texas solar owners face price risks after building boom”, op. cit.
note 178; L. Morais, “Argentina’s 300MW Cauchari solar farm
begins commercial operation”, Institute for Energy Economics
and Financial Analysis (IEEFA), 28 September 2020, https://
ieefa.org/argentinas-300mw-cauchari-solar-farm-begins-
commercial-operation; “Chile’s 123-MW Granja solar plant now
operational”, Renewable Energy World, 9 March 2020, https://
www.renewableenergyworld.com/2020/03/09/chiles-123-mw-
granja-solar-plant-now-operational; P. Sanchez Molina, “Neoen
energizes 140 MW solar park linked to 3.2 MW/2.2 MWh of
storage in El Salvador”, pv magazine, 8 December 2020, https://
www.pv-magazine.com/2020/12/08/neoen-energizes-140-mw-
solar-park-linked-to-3-2-mw-2-2-mwh-of-storage-in-el-salvador;
G. Parkinson, “Australia’s biggest solar farm sends first output
to the grid”, RenewEconomy, 15 September 2020, https://
reneweconomy.com.au/australias-biggest-solar-farm-sends-
first-output-to-the-grid-95988; Mali from Smith, op. cit. note
167; South Africa from Bellini, op. cit. note 167; A. Parikh, “Scatec
Solar’s 86 MW solar project in South Africa begins operation”,
Mercom India, 4 March 2020, https://mercomindia.com/
scatec-solar-86-mw-solar-project-south-africa; B. Bungane,
“South Africa: 75MW Waterloo Solar begins commercial
operations”, ESI Africa, 27 November 2020, https://www.esi-africa.
com/industry-sectors/renewable-energy/south-africa-75mw-
waterloo-solar-begins-commercial-operations; B. Bungane,
“Two new solar plants now feeding 132MW into South Africa’s
grid”, ESI Africa, 1 October 2020, https://www.esi-africa.com/
industry-sectors/renewable-energy/two-new-solar-plants-now-
feeding-132mw-into-south-africas-grid; B. Bungane, “South Africa:
Bokamoso Solar plant commences commercial operations”,
ESI Africa, 18 September 2020, https://www.esi-africa.com/
industry-sectors/renewable-energy/south-africa-bokamoso-
solar-plant-commences-commercial-operations; NS Energy,
“Sterling and Wilson commissions 125MW DC solar PV project in
Oman”, 3 June 2020, https://www.nsenergybusiness.com/news/
sterling-wilson-solar-pv-oman; Power Technology, “Indian prime
minister inaugurates 750MW solar project”, 10 July 2020, https://
www.power-technology.com/news/narendra-modi-inaugurates-
750mw-solar-project-india; “Japanese consortium tees up 100MW
Kanoya Osaki”, reNEWS, 29 May 2020, https://renews.biz/60641/
japanese-consortium-tees-up-100mw-kanoya-osaki; NS Energy,
“Risen Energy connects 50MW solar plant to grid in Kazakhstan”,
22 January 2020, https://www.nsenergybusiness.com/news/
risen-energy-solar-plant; Bellini, “Three 1.2 GW solar projects
under development in the Philippines”, op. cit. note 64; Retail
Asia, “Largest solar plant in Southeast Asia begins operating in
Vietnam”, 14 October 2020, https://www.retailnews.asia/largest-
solar-plant-in-southeast-asia-begins-operating-in-vietnam; E.
Bellini, “Albania launches 140 MW solar tender”, pv magazine,
22 January 2020, https://www.pv-magazine.com/2020/01/22/
albania-launches-tender-for-140-mw-of-solar.
183 Well-designed and -built from Rossi, op. cit. note 112, 25 May
2021, from SolarPower Europe, Solar Sustainability: Best Practices
Benchmark (Brussels: May 2021), https://www.solarpowereurope.
org/solar-sustainability-best-practices-benchmark, and from
Bundesverband Neue Energiewirtschaft (bne) e.V., Solarparks
- Gewinne für die Biodiversität (Berlin: November 2019), https://
www.bne-online.de/fileadmin/bne/Dokumente/20191119_bne_
Studie_Solarparks_Gewinne_fuer_die_Biodiversitaet_online .
Concerns from, for example, P. Fairley, “The pros and cons of the
world’s biggest solar park”, IEEE Spectrum, 22 January 2020, https://
spectrum.ieee.org/energy/renewables/the-pros-and-cons-of-the-
worlds-biggest-solar-park; S. M. Nir, “He set up a big solar farm. His
neighbors hated it”, New York Times, 18 March 2020, https://www.
nytimes.com/2020/03/18/nyregion/solar-energy-farms-ny.html; J.
McCurry, “Japan’s renewable energy puzzle: Solar push threatens
environment”, The Guardian (UK), 19 April 2018, https://www.
theguardian.com/world/2018/apr/19/japans-renewable-energy-
puzzle-solar-push-threatens-environment; IEA PVPS, Trends in
Photovoltaic Applications 2018, op. cit. note 9, p. 16. Land constraints
already are becoming a problem in China, for example, particularly in
the eastern part of the country along the coastline, from F. Haugwitz,
AECEA, presentation for “PV Market Insights 2021”, Daegu, Republic
of Korea, 28-29 April, pvmi.co.kr/eng.
184 D. Renné, International Solar Energy Society, Boulder, CO,
personal communication with REN21, April 2020.
185 BIPV progressing but slowly, and auto manufacturers, from
Masson, op. cit. note 1, 20 February 2020 and 9 March 2021.
186 India from A. Upadhyay, “India’s largest building integrated vertical
solar system & the road ahead”, CleanTechnica, 11 July 2020, https://
cleantechnica.com/2020/07/11/indias-largest-building-integrated-
vertical-solar-system-the-road-ahead; United States from for
example, B. Ludt, “Philadelphia architecture firm installs wild solar
project to maximize onsite power production”, Solar Power World,
10 November 2020, https://www.solarpowerworldonline.com/
2020/11/philadelphia-architecture-firm-installs-wild-solar-project-
to-maximize-onsite-power-production; K. Misbrener, “All Energy
Solar completes unusual Minnesota solar project meant to double
as art installation”, Solar Power World, 14 September 2020, https://
www.solarpowerworldonline.com/2020/09/all-energy-solar-installs-
solar-art-installation-minnesota; B. Ludt, “Wall-mounted solar
mural depicts history of Texas school”, 20 February 2020, https://
www.solarpowerworldonline.com/2020/02/wall-mounted-solar-
mural-depicts-history-of-texas-school. Europe from Swiss BIPV
Competence Centre and Becquerel Institute, Building Integrated
Photovoltaics: A Practical Handbook for Solar Buildings’ Stakeholders
(Canobbio, Switzerland: October 2020), https://solarchitecture.ch/
wp-content/uploads/2020/11/201022_BIPV_web_V01 .
311
https://www.bloomberg.com/news/articles/2020-02-28/solar-power-has-finally-gone-off-the-scale-green-insight
https://www.bloomberg.com/news/articles/2020-02-28/solar-power-has-finally-gone-off-the-scale-green-insight
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https://www.power-technology.com/news/narendra-modi-inaugurates-750mw-solar-project-india
https://renews.biz/60641/japanese-consortium-tees-up-100mw-kanoya-osaki
https://renews.biz/60641/japanese-consortium-tees-up-100mw-kanoya-osaki
https://www.nsenergybusiness.com/news/risen-energy-solar-plant
https://www.nsenergybusiness.com/news/risen-energy-solar-plant
https://www.retailnews.asia/largest-solar-plant-in-southeast-asia-begins-operating-in-vietnam
https://www.retailnews.asia/largest-solar-plant-in-southeast-asia-begins-operating-in-vietnam
https://www.pv-magazine.com/2020/01/22/albania-launches-tender-for-140-mw-of-solar
https://www.pv-magazine.com/2020/01/22/albania-launches-tender-for-140-mw-of-solar
https://www.solarpowereurope.org/solar-sustainability-best-practices-benchmark
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https://www.bne-online.de/fileadmin/bne/Dokumente/20191119_bne_Studie_Solarparks_Gewinne_fuer_die_Biodiversitaet_online
https://spectrum.ieee.org/energy/renewables/the-pros-and-cons-of-the-worlds-biggest-solar-park
https://spectrum.ieee.org/energy/renewables/the-pros-and-cons-of-the-worlds-biggest-solar-park
https://spectrum.ieee.org/energy/renewables/the-pros-and-cons-of-the-worlds-biggest-solar-park
https://www.nytimes.com/2020/03/18/nyregion/solar-energy-farms-ny.html
https://www.nytimes.com/2020/03/18/nyregion/solar-energy-farms-ny.html
https://www.theguardian.com/world/2018/apr/19/japans-renewable-energy-puzzle-solar-push-threatens-environment
https://www.theguardian.com/world/2018/apr/19/japans-renewable-energy-puzzle-solar-push-threatens-environment
https://www.theguardian.com/world/2018/apr/19/japans-renewable-energy-puzzle-solar-push-threatens-environment
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https://cleantechnica.com/2020/07/11/indias-largest-building-integrated-vertical-solar-system-the-road-ahead
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https://cleantechnica.com/2020/07/11/indias-largest-building-integrated-vertical-solar-system-the-road-ahead
https://www.solarpowerworldonline.com/2020/11/philadelphia-architecture-firm-installs-wild-solar-project-to-maximize-onsite-power-production
https://www.solarpowerworldonline.com/2020/11/philadelphia-architecture-firm-installs-wild-solar-project-to-maximize-onsite-power-production
https://www.solarpowerworldonline.com/2020/11/philadelphia-architecture-firm-installs-wild-solar-project-to-maximize-onsite-power-production
https://www.solarpowerworldonline.com/2020/09/all-energy-solar-installs-solar-art-installation-minnesota
https://www.solarpowerworldonline.com/2020/09/all-energy-solar-installs-solar-art-installation-minnesota
https://www.solarpowerworldonline.com/2020/09/all-energy-solar-installs-solar-art-installation-minnesota
https://www.solarpowerworldonline.com/2020/02/wall-mounted-solar-mural-depicts-history-of-texas-school
https://www.solarpowerworldonline.com/2020/02/wall-mounted-solar-mural-depicts-history-of-texas-school
https://www.solarpowerworldonline.com/2020/02/wall-mounted-solar-mural-depicts-history-of-texas-school
https://solarchitecture.ch/wp-content/uploads/2020/11/201022_BIPV_web_V01
https://solarchitecture.ch/wp-content/uploads/2020/11/201022_BIPV_web_V01
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187 Land and design innovations from N. Ford, “Floating solar design
gains drive strong growth prospects”, New Energy Update, 22 July
2020, https://analysis.newenergyupdate.com/pv-insider/floating-
solar-design-gains-drive-strong-growth-prospects. See also World
Bank, Energy Sector Management Assistance Program (ESMAP)
and Solar Energy Research Institute of Singapore (SERIS), Where
Sun Meets Water: Floating Solar Handbook for Practitioners
(Washington, DC: World Bank, 2019),http://documents.worldbank.
org/curated/en/418961572293438109/Where-Sun-Meets-Water-
Floating-Solar-Handbook-for-Practitioners; IEA PVPS, Trends in
Photovoltaic Applications 2019, op. cit. note 5, pp. 16-17.
188 New risks and higher costs from SolarPower Europe, Global
Market Outlook for Solar Power 2020-2024, op. cit. note 9, p.
61, and from Wood Mackenzie Power & Renewables, cited in
M. Cox, “The state of floating solar: Bigger projects, climbing
capacity, new markets”, Greentech Media, 19 September 2019,
https://www.greentechmedia.com/articles/read/the-state-of-
floating-solar-bigger-projects-and-climbing-capacity; benefits
from SolarPower Europe, op. cit. this note, and from World Bank,
ESMAP and SERIS, op. cit. note 187. In 2020, a new Dutch study
showed no significant benefit to solar panels from sunlight
reflected off water or from reduced panel temperatures, and it
found that bird droppings can affect the panels’ performance;
in addition, the study found no significant benefits to water-
quality and temperatures, from Delft University of Technology,
“Innovative floating bifacial photovoltaic solutions for inland
water areas”, Progress in Photovoltaics, cited in E. Bellini, “New
study debunks several myths about floating PV”, pv magazine,
15 December 2020, https://www.pv-magazine.com/2020/12/15/
new-study-debunks-several-myths-about-floating-pv.
189 Wood Mackenzie Power & Renewables, op. cit. note 188.
190 Countries with projects in Asia include China, the Republic of
Korea, Malaysia, the Philippines, Singapore, Thailand, Vietnam
and others, from the following sources: CEC, “World’s largest
floating solar plant connected in China”, press release, http://
english.cec.org.cn/No.106.1755.htm, viewed 25 March 2020;
T. Kenning, “World’s largest floating solar plant connected in
China”, PV-Tech, 20 March 2019, https://www.pv-tech.org/news/
worlds-largest-floating-solar-plant-connected-in-china; GCL
System, “Floating solar: Philippines switches on its first hybrid
floating photovoltaic hydro power project”, pv magazine, 16 July
2019, https://www.pv-magazine-australia.com/press-releases/
floating-solar-philippines-switches-on-its-first-hybrid-floating-
photovoltaic-hydro-power-project; M. Patel, “Floating solar
power plants: An idea whose time has come”, Economic Times,
22 May 2019, https://energy.economictimes.indiatimes.com/
energy-speak/floating-solar-power-plants-an-idea-whose-
time-has-come/3582; E. Bellini, “New alliance to expand floating
PV in Southeast Asia”, pv magazine, 8 August 2019, https://
www.pv-magazine.com/2019/08/08/new-alliance-to-expand-
floating-pv-in-southeast-asia; A. A. Hadi, “World’s largest
floating solar energy systems installed in Maldives”, Sun, 26
August 2019, https://en.sun.mv/55072. African countries include
Malawi and the Seychelles, from J. Martín, “France powers up
Europe’s self-styled largest floating PV project”, PV-Tech, 21
October 2019, https://www.pv-tech.org/news/france-powers-
up-europes-self-styled-largest-floating-pv-project, and from
BizCommunity, “Seychelles floating solar energy project moves
into next phase”, 13 June 2019, https://www.bizcommunity.com/
Article/189/640/191942.html. Countries in Europe include France,
Portugal and the Netherlands, from the following sources: J.
Martín, “World Bank, SERIS take aim at floating PV hurdles with
standardisation push”, PV-Tech, 4 November 2019, https://www.
pv-tech.org/news/world-bank-seris-take-aim-at-floating-pv-
hurdles-with-standardisation-push; Martín, “France powers up
Europe’s self-styled largest floating PV project”, op. cit. this note;
E. Barbiroglio, “A new floating solar farm shows that renewables
can be easy”, Forbes, 7 November 2019, https://www.forbes.
com/sites/emanuelabarbiroglio/2019/11/07/a-new-floating-solar-
farm-shows-that-renewables-can-be-easy; M. Osborne, “BayWa
r.e planning over 100MW of floating solar projects in Europe for
2020”, PV-Tech, 5 November 2019, https://www.pv-tech.org/
news/baywa-r.e-planning-over-100mw-of-floating-solar-projects-
in-europe-for-2020. Countries in the Americas include Brazil, from
Martín, “France powers up Europe’s self-styled largest floating PV
project”, op. cit. this note; P. Sanchez Molina, “Chile connects first
floating PV plant to grid under net billing scheme”, pv magazine,
16 September 2020, https://www.pv-magazine.com/2020/09/16/
chile-connects-first-floating-pv-plant-to-grid-under-net-billing-
scheme; T. Sylvia, “America’s largest floating solar project
completed”, pv magazine, 23 October 2019, https://pv-magazine-
usa.com/2019/10/23/americas-largest-floating-solar-project-
completed. Most of the largest floating solar plants are in Asia
(outside of Asia, most floating solar PV plants are on the scale of
several megawatts), from “Floating solar design gains drive strong
growth prospects”, Reuters Events, 22 July 2020, https://analysis.
newenergyupdate.com/pv-insider/floating-solar-design-gains-
drive-strong-growth-prospects, C. Gilligan and C. Beadle, “Asian
buoyancy floats solar”, pv magazine, 4 June 2020, https://www.
pv-magazine.com/2020/06/04/asian-buoyancy-floats-solar.
191 MESIA, op. cit. note 13, p. 26.
192 Z. Shahan, “Largest floating solar park in Europe connected
to grid in Netherlands”, CleanTechnica, 1 August 2020, https://
cleantechnica.com/2020/08/01/largest-floating-solar-park-in-
europe-connected-to-grid-in-netherlands; Blauwvinger Energie,
“Zonnepark Bomhofsplas gekocht, https://blauwvingerenergie.
nl/zonnepark-bomhofsplas-gekocht, viewed 31 March 2021;
G. Deboutte, “First unit of 250 MW floating PV project comes
online in Ghana”, pv magazine, 15 December 2020, https://www.
pv-magazine.com/2020/12/15/first-unit-of-250-mw-floating-pv-
project-comes-online-in-ghana; Chile from Sanchez Molina, op.
cit. note 190. Other examples include: “Sembcorp signs 25-year
power purchase deal to build floating solar system”, Reuters,
11 May 2020, https://www.reuters.com/article/singapore-oil-
sembcorp-inds/sembcorp-signs-25-year-power-purchase-
deal-to-build-floating-solar-system-idUSL4N2CT3NE; E. Bellini,
“Vietnam sees 70 MW of floating PV come online”, pv magazine,
6 January 2021, https://www.pv-magazine.com/2021/01/06/
vietnam-sees-70-mw-of-floating-pv-come-online; N. Pombo-van
Zyl, “Brazil to host floating solar PV at its Batalha hydropower
dam”, ESI Africa, 17 February 2020, https://www.esi-africa.com/
industry-sectors/future-energy/brazil-to-host-floating-solar-pv-
at-its-batalha-hydropower-dam; Sanchez Molina, op. cit. note 190;
Acciona, “ACCIONA begins installing the first grid-connected
floating photovoltaic plant in Spain, in Extremadura”, 3 March
2020, https://www.acciona.com/pressroom/news/2020/march/
acciona-begins-installing-the-first-grid-connected-floating-
photovoltaic-plant-in-spain-in-extremadura; “EDP floating
PV-hydro project shows market viability”, Reuters Event, 28
October 2020, https://www.reutersevents.com/renewables/
solar/edp-floating-pv-hydro-project-shows-market-viability; S. J.
Ahmed and E. Hamdi, “IEEFA report: Volts from the blue – floating
solar to generate 900% more electricity across Asia-Pacific”,
IEEFA, 30 June 2020, https://ieefa.org/ieefa-volts-from-the-blue-
floating-solar-energy-to-generate-900-more-clean-electricity-
across-asia-pacific-since-2019.
193 J. Scully, “Chenya Energy eyes floating PV growth after
completing 181MWp offshore project”, PV-Tech, 5 February 2021,
https://www.pv-tech.org/chenya-energy-eyes-floating-pv-
growth-after-completing-181mwp-offshore-project. The largest
water-based project (with some arrays floating and some on stilts
over water) was completed in Zhejiang province, China, in 2020,
from “World’s biggest floating solar farms”, Power Technology,
19 February 2021, https://www.power-technology.com/features/
worlds-biggest-floating-solar-farms. The Hangzhou Fengling
Electricity Science Technology’s solar farm was developed in
two phases, with 200 MW completed in 2017 and the remainder
in April 2020; the plant is built on the Changhe and Zhouxiang
reservoirs in Cixi, from idem. See also E. Bellini, “Another 120
MW of solar aquaculture in China”, pv magazine, 14 April 2020,
https://www.pv-magazine.com/2020/04/17/another-120-mw-
of-solar-aquaculture-in-china, and Kstar, “KSTAR 320MW
(120MW+200MW) solar-water power plant”, 18 April 2020,
https://www.kstar.com/newinformation/17387.jhtml.
194 S. Hanley, “Europe puts focus on floating solar & agrivoltaics”,
CleanTechnica, 22 March 2020, https://cleantechnica.
com/2020/03/22/europe-puts-focus-on-floating-solar-
agrivoltaics; J. S. Murray, “Oil giants team up to float coastal
solar vision”, Business Green, 20 March 2020, https://www.
businessgreen.com/news/4012807/oil-giants-team-float-
coastal-solar-vision. In 2020, an 80 kW array was completed
in the waters off the coast of the resort island of Nurai, Abu
Dhabi (UAE), from S. Vorrath, “Open sea floating solar array set
to power Abu Dhabi resort island”, One Step Off The Grid, 13
February 2020, https://onestepoffthegrid.com.au/open-sea-
floating-solar-array-set-to-power-abu-dhabi-resort-island, and
fromMESIA, op. cit. note 13, p. 5. Bidders were selected for a 2.1
GW plant planned for an estuarine tidal flat off the coast of the
312
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https://analysis.newenergyupdate.com/pv-insider/floating-solar-design-gains-drive-strong-growth-prospects
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https://en.sun.mv/55072
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https://www.pv-magazine.com/2020/09/16/chile-connects-first-floating-pv-plant-to-grid-under-net-billing-scheme
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https://www.pv-magazine.com/2020/06/04/asian-buoyancy-floats-solar
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https://cleantechnica.com/2020/08/01/largest-floating-solar-park-in-europe-connected-to-grid-in-netherlands
https://cleantechnica.com/2020/08/01/largest-floating-solar-park-in-europe-connected-to-grid-in-netherlands
https://cleantechnica.com/2020/08/01/largest-floating-solar-park-in-europe-connected-to-grid-in-netherlands
https://blauwvingerenergie.nl/zonnepark-bomhofsplas-gekocht
https://blauwvingerenergie.nl/zonnepark-bomhofsplas-gekocht
https://www.reuters.com/article/singapore-oil-sembcorp-inds/sembcorp-signs-25-year-power-purchase-deal-to-build-floating-solar-system-idUSL4N2CT3NE
https://www.reuters.com/article/singapore-oil-sembcorp-inds/sembcorp-signs-25-year-power-purchase-deal-to-build-floating-solar-system-idUSL4N2CT3NE
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https://www.pv-magazine.com/2021/01/06/vietnam-sees-70-mw-of-floating-pv-come-online
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https://www.businessgreen.com/news/4012807/oil-giants-team-float-coastal-solar-vision
https://www.businessgreen.com/news/4012807/oil-giants-team-float-coastal-solar-vision
https://www.businessgreen.com/news/4012807/oil-giants-team-float-coastal-solar-vision
https://onestepoffthegrid.com.au/open-sea-floating-solar-array-set-to-power-abu-dhabi-resort-island
https://onestepoffthegrid.com.au/open-sea-floating-solar-array-set-to-power-abu-dhabi-resort-island
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Republic of Korea. The plant to be built near Saemangeum is
expected to generate enough electricity to serve the needs of 1
million homes, and is part of a planned renewable energy project
of up to 3 GW, from “World’s biggest floating solar farms”, op.
cit. note 193. Two fossil fuel companies (Norway’s Equinor and
Italy’s Saipem) partnered to develop a technological solution for
near-shore applications, from Hanley, op. cit. this note; Murray,
op. cit. this note.For a further offshore related development
in early 2021, see B. Willis, “The race is on for commercial
deployment of solar in open seas”, Greentech Media, 27
January 2021, https://www.greentechmedia.com/articles/read/
race-on-for-commercial-deployment-of-solar-in-open-seas.
195 See sources provided for this paragraph. Bifacial systems from
Renné, op. cit. note 184, 11 April 2020.
196 “Agri-PV builders trial crop, technology in yield-boosting plants”,
Reuters Events, 19 August 2020, https://analysis.newenergyupdate.
com/solar/agri-pv-builders-trial-crop-technology-yield-boosting-
plants; SolarPower Europe, Agrisolar: Best Practices Guidelines
Version 1.0 (Brussels: May 2021), https://www.solarpowereurope.
org/agrisolar-best-practice-guidelines.
197 Costs are higher due to specialized equipment and more
expensive installation methods, from “Agri-PV builders trial crop,
technology in yield-boosting plants”, op. cit. note 196. Studies
from, for example: SolarPower Europe, Global Market Outlook for
Solar Power 2020-2024, op. cit. note 9, p. 61; SolarPower Europe,
op. cit. note 196; “US agri-PV teams build data for commercial
roll-out”, Reuters Events, 16 December 2020, https://www.
reutersevents.com/renewables/solar-pv/us-agri-pv-teams-build-
data-commercial-roll-out; “Agri-PV builders trial crop, technology
in yield-boosting plants”, op. cit. note 196; L. Freehill-Maye,
“Sheep, ag and sun: Agrivoltaics propel significant reductions
in solar maintenance costs”, Utility Dive, 4 August 2020, https://
www.utilitydive.com/news/sheep-ag-and-sun-agrivoltaics-
propel-significant-reductions-in-solar-main/581879; E. Bellini,
“Food crops do better in the shade of solar panels”, pv magazine,
3 September 2019, https://www.pv-magazine.com/2019/09/03/
food-crops-do-better-in-the-shade-of-solar-panels; P. Lal, “India
prepares to embrace agrivoltaics”, pv magazine, 27 September
2019, https://www.pv-magazine-india.com/2019/09/27/india-
prepares-to-embrace-agrivoltaics; T. Tsanova, “German agro PV
trial shows up to 186% land use efficiency”, Renewables Now,
15 April 2019, https://renewablesnow.com/news/german-agro-
pv-trial-shows-up-to-186-land-use-efficiency-650768. Improved
yields and additional income from SolarPower Europe, Global
Market Outlook for Solar Power, 2019-2023, op. cit. note 7, p. 51,
and from IEA PVPS, Trends in Photovoltaic Applications 2019, op.
cit. note 5, p. 17. Prevention of wind and soil erosion, and shade
for livestock, from Lal, op. cit. this note; reduced evaporation and
rainwater harvesting from Tsanova, op. cit. this note. In Europe,
studies have found that solar PV installations in vineyards
can aid in hail and frost protection and can enable control of
alcohol content in grapes, from Energiezukunft, “Himbeeren
unter Solarmodulen statt unter Folientunneln”, 9 March 2020,
https://www.energiezukunft.eu/erneuerbare-energien/solar/
himbeeren-unter-solarmodulen-statt-unter-folientunneln.
198 Japan from Matsubara, op. cit. note 53; and Japan, Republic
of Korea and India from Haugwitz, op. cit. note 29, 13 April
2021. India active programmes from Renné, op. cit. note 184,
5 April 2020; see also Lal, op. cit. note 197. Elsewhere from,
for example, “Agri-PV builders trial crop, technology in yield-
boosting plants”, op. cit. note 96; “First dual-use agricultural PV
system in Massachusetts now operational”, Renewable Energy
World, 20 October 2020, https://www.renewableenergyworld.
com/2020/10/20/first-dual-use-agricultural-pv-system-in-
massachusetts-now-operational; “US agri-PV teams build
data for commercial roll-out”, op. cit. note 197. Israel from B.
Matich, “Orchardvoltaics – it’s just ripe”, pv magazine, 15 January
2021, https://www.pv-magazine.com/magazine-archive/
orchardvoltaics-its-just-ripe. China from Masson, op. cit. note 1, 9
March 2021.
199 China as dominant producer and supplier from Z. Jianhua,
Director of NEA, speaking at press conference: “The State
Council Information Office held a press conference on China's
renewable energy development”, 30 March 2021, http://www.
nea.gov.cn/2021-03/30/c_139846095.htm (using Google
Translate); P. Mints, Photovoltaic Manufacturer Capacity, op.
cit. note 1, p. 16. Chinese factories comprise at least 73% of
global capacity in every step of the solar PV supply chain, from
BloombergNEF, cited in “China’s solar giants slash prices as
virus curbs demand”, Bloomberg, 31 May 2020, https://www.
bloomberg.com/news/articles/2020-05-31/china-s-solar-giants-
forced-to-cut-prices-as-virus-curbs-demand; Chinese factories
manufacture about 70% of the global supply of solar panels plus
Chinese companies throughout Southeast Asia, from H. Bahar,
“The coronavirus pandemic could derail renewable energy’s
progress. Governments can help.” IEA, 4 April 2020, https://
www.iea.org/commentaries/the-coronavirus-pandemic-could-
derail-renewable-energy-s-progress-governments-can-help.
See also “China solar giants get bigger as glut ignites battle for
share”, Bloomberg, 4 March 2020, https://www.bloomberg.com/
news/articles/2020-03-04/china-solar-giants-get-bigger-as-
glut-ignites-battle-for-share. Closures in the entire industry from
E. F. Merchant, “Solar industry waits to assess ripple effects from
China’s coronavirus outbreak”, Greentech Media, 31 January
2020, https://www.greentechmedia.com/articles/read/solar-
industry-waits-to-assess-ripple-effects-from-coronavirus-impact,
but China rebounded quickly, from “Coronavirus is starting
to slow the solar energy revolution”, Bloomberg, 27 February
2020, https://www.bloomberg.com/news/articles/2020-02-27/
coronavirus-is-starting-to-slow-the-solar-energy-revolution. The
timing of the worst impacts of COVID-19 in China coincided with
the Lunar New Year, so material delays were already incorporated
into supply-management schedules, from E. Crouse and D.
Conner, “Opinion: Distressed supply chains uniquely impact
renewable energy”, Seattle Business News, 20 April 2020, https://
www.bizjournals.com/seattle/news/2020/04/20/distressed-
supply-chains-uniquely-impacts-energy.html.
200 “COVID-19 sends price risk warning to dispatch-only renewables”,
Reuters Events, 20 May 2020, https://newenergyupdate.com/
pv-insider/covid-19-sends-price-risk-warning-dispatch-only-
renewables; “Solar, wind investors adapt PPAs for post-COVID
pickup”, Reuters Events, 6 May 2020, https://www.reutersevents.
com/renewables/pv-insider/solar-wind-investors-adapt-ppas-
post-covid-pickup; P. M. Shea, “Coronavirus spurs 'domino effect'
of wind, solar delays”, Energywire, 10 March 2020, https://www.
eenews.net/energywire/stories/1062562335/; EurObserv’ER, op.
cit. note 30, p. 15.
201 IEA, “Renewables 2020: Covid-19 and the resilience of
renewables”, https://www.iea.org/reports/renewables-2020/
covid-19-and-the-resilience-of-renewables, viewed 15 May
2021. See also, for example, M. Osborne, “SMA Solar’s inverter
shipments rebound in Q3 after COVID-19 hit”, PV-Tech, 12
November 2020, https://www.pv-tech.org/sma-solars-inverter-
shipments-rebound-in-q3-after-covid-19-hit; M. Mercure,
“SEIA: solar rebounds for pandemic in Q3”, Solar Industry, 15
December 2020, https://solarindustrymag.com/seia-solar-
rebounds-from-pandemic-in-q3; E. Bellini, “JinkoSolar posts
significant shipment growth in Q3”, pv magazine, 26 November
2020, https://www.pv-magazine-australia.com/2018/11/26/
jinkosolar-posts-significant-shipment-growth-in-q3.
202 Mints, op. cit. note 83, pp. 6, 25; Becquerel Institute, BI Newsletter
December 2020, received via email 17 December 2020. Accidents
at polysilicon factories included an explosion at GCL Poly’s
facility in Xinjiang (China) and flooding of Tongwei’s facility in
Sichuan (China), which took about 11% of global production
capacity offline, from SEIA, “Solar Market Insight Report 2020
Q4”, https://www.seia.org/research-resources/solar-market-
insight-report-2020-q4, viewed 13 April 2021, and from C. Chen,
“Consolidation continues for polysilicon makers”, pv magazine,
20 July 2020, https://www.pv-magazine.com/2020/08/20/
consolidation-continues-for-polysilicon-makers. China has 90%
of solar glass production capacity, from P. Mints, Photovoltaic
Manufacturer Capacity, op. cit. note 1, p. 13. Between June 2020
and February 2021, prices increased dramatically for glass (up
80% per square metre), polysilicon (up 64%) and silver (up 55%),
from B. S. Nagaraj, “Solar module prices to remain high until
second half of 2021: Chinese manufacturers”, Mercom India, 26
April 2021, https://mercomindia.com/solar-module-prices-high-
second-half-of-2021. Glass pricing and related information in
endnote from the following: Becquerel Institute, op. cit. this note;
Masson, op. cit. note 1, 9 March 2021; Soby Photovoltaic Network,
“The shortage of photovoltaic glass is expected to alleviate the
relevant departments to actively promote three measures”, Polaris
Power Exhibition Network, 4 November 2020, http://ex.bjx.com.
cn/html/20201104/36640.shtml (using Google Translate). Prices
also were up because of increasingly diverse sizes of modules,
which requires stocking a variety of glass sizes and can lead to a
mismatch of resources, from idem. Rising demand due to rapidly
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increasing production of solar modules and also to growth in
demand for bifacial panels, which increase glass requirements,
from “Glass shortage threatens solar panels needed for climate
fix”, Bloomberg, 4 November 2020, https://www.bloomberg.
com/news/articles/2020-11-05/a-glass-shortage-is-threatening-
china-s-solar-power-ambitions. The Chinese government forbade
increases in production capacity in 2018 because the industry is
energy-intensive and highly-polluting and it was facing over-
capacity issues, from idem. Global prices for solar glass saw
steady rise starting in 2018, but jumped up over 70% from July to
November, from idem.
203 See information and sources throughout this section.
204 Germany extended completion deadlines by up to six months for
awarded capacity, from M. Schachinger, “Module Price Index:
2020 – Taking the time to say ‘thanks’…”, pv magazine, 20 January
2021, https://www.pv-magazine.com/2021/01/20/module-price-
index-2020-taking-the-time-to-say-thanks. S. Enkhardt and C.
Rollet, “Germany and France modify solar tenders because of
Covid-19”, pv magazine, 25 March 2020, https://www.pv-magazine.
com/2020/03/25/germany-and-france-modify-solar-tenders-
because-of-covid-19. India announced in March an extension
of commissioning deadlines for projects under construction
and extended a waiver for inter-state transmission charges for
projects commissioned up to mid-2023, from U. Gupta, “Solar
industry in 2020”, pv magazine, 28 December 2020, https://www.
pv-magazine-india.com/2020/12/28/solar-industry-in-2020;
J. Pyper, “How India’s renewable energy sector survived and
thrived in a turbulent 2020”, Greentech Media, 6 January 2021,
https://www.greentechmedia.com/articles/read/india-solar-
energy-transition-pandemic-2020; N. T. Prasad, “COVID-19
lockdown: MNRE extends deadline for all renewable projects
under construction”, Mercom India, 27 March 2020, https://
mercomindia.com/covid-19-lockdown-mnre-deadline-renewable-
under-construction.The United States extended various tax credit
deadlines for acquiring components and completing projects, from
P. Mints, SPV Market Research, The Solar Flare, 30 April 2020, p.
20; but the federal government also ended a two-year rent holiday
for wind and solar power projects on federal lands, sending out
retroactive bills in May, some for millions of dollars, from N. Groom,
“Trump admin slaps solar, wind operators with retroactive rent
bills”, Reuters, 18 May 2020, https://www.reuters.com/article/
us-usa-interior-renewables/trump-admin-slaps-solar-wind-
operators-with-retroactive-rent-bills-idUSKBN22U0FW.
205 Spain from Mints, op. cit. note 204, p. 19, and from B. Willis, “New
laws eye ‘massive’ deployment of renewables in Spain”, PV-Tech,
24 June 2020, https://www.pv-tech.org/new-laws-eye-massive-
deployment-of-renewables-in-spain; M. Agravante, “Italy’s
Relaunch Decree helps homeowners install solar photovoltaic
systems for free”, Inhabitat, 27 May 2020, https://inhabitat.
com/italys-relaunch-decree-helps-homeowners-install-solar-
photovoltaic-systems-for-free; India from Pyper, op. cit. note 204.
India’s national and several state governments also launched
additional tenders and financially supporting power DISCOMs
so they had liquidity to pay producers, from idem. Note, however,
that implementation of India’s “must-run” status was lax during
the year and curtailment continued to threaten both solar PV
and wind power generators, from R. Ranjan, “Curtailment of
solar and wind for commercial reasons continues to be a threat”,
Mercom India, 10 December 2020, https://mercomindia.com/
curtailment-solar-wind-commercial-threat.
206 Disrupted supply chains from sources throughout related text
that follows. See also, for example, E. Bellini, “Covid-19 and
dependence on China’s PV supply chain”, pv magazine, 30
March 2020, https://www.pv-magazine.com/2020/03/30/
covid-19-and-dependence-on-chinas-pv-supply-chain.
207 Existing import tariffs from N. Young, “These are the tariffs still
impacting the U.S. solar industry”, Solar Power World, 24 March
2020, https://www.solarpowerworldonline.com/2020/03/
these-are-the-tariffs-still-impacting-the-u-s-solar-industry; E.
J. Williams, A. D. Schurle and M. A. Lund, “The status of solar
and wind tax credits and tariffs as we enter 2021”, Solar Power
World, 7 December 2020, https://www.solarpowerworldonline.
com/2020/12/the-status-of-solar-and-wind-tax-credits-and-
tariffs-as-we-enter-2021. See also E. F. Merchant, “Trump moves
to increase solar import tariffs, kill bifacial exemption”, Greentech
Media, 12 October 2020, https://www.greentechmedia.com/
articles/read/presidential-proclamation-to-increase-extend-
section-201-tariffs. Bifacial developments from Mints, op. cit.
note 204; Mints, op. cit. note 83, p. 29; E. F. Merchant, “Trump
administration removes tariff exemption for bifacial solar
panels — again”, Greentech Media, 17 April 2020, https://www.
greentechmedia.com/articles/read/trump-admin-removes-
tariff-exemption-for-bifacial-solar-panels-again; X. Sun, “Why
US solar tariffs almost worked, and why they don’t now”,
Greentech Media, 23 July 2020, https://www.greentechmedia.
com/articles/read/why-us-solar-tariffs-almost-worked-and-
why-they-dont-now; B. Pickerel, “Bifacial solar panels lose their
Section 201 tariff exemption”, Solar Power World, 19 November
2020, https://www.solarpowerworldonline.com/2020/11/
bifacial-solar-panels-lose-their-section-201-tariff-exemption.
208 R. Nair, “After Kazakhstan, US imposes 47.54% duty on silicon
from Bosnia-Herzegovina & Iceland”, Mercom India, 10 December
2020, https://mercomindia.com/us-imposes-duty-on-silicon;
“U.S. silicon metal producers welcome duties on imports of silicon
metal from Kazakhstan”, Bloomberg, 1 December 2020, https://
www.bloomberg.com/press-releases/2020-11-30/u-s-silicon-
metal-producers-welcome-duties-on-imports-of-silicon-metal-
from-kazakhstan. Critics say that US import tariffs have raised
costs and hampered domestic deployment, from M. Willson,
“Biden’s ‘Buy America’ plan may hit a solar wall”, E&E News, 1
March 2021, https://www.eenews.net/stories/1063726219/print.
According to Wood Mackenzie, “Tariffs have made solar modules
artificially more expensive in the U.S. The cost is about 79 percent
higher than in major European markets, 75 percent higher than
Japan, and about 85 percent higher than in China. Without the
tariffs, U.S. solar system prices could be nearly 30 percent lower”,
from Sun, op. cit. note 207.
209 Promotion of self-reliance through duties from R. Ranjan,
“Technological upgrades imperative for India’s solar
manufacturing to take-off”, Mercom India, 31 August 2020,
https://mercomindia.com/technological-upgrades-india-
solar-manufacturing, from Ranjan, op. cit. note 60, and from R.
Ranjan, “2020 a look back: Developments that shaped the solar
sector”, Mercom India, 29 December 2020, https://mercomindia.
com/2020-look-back-developments-solar. Safeguard duty
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from Malaysia”, Mercom India, 21 December 2020, https://
mercomindia.com/dgtr-countervailing-duty-solar-glass-malaysia.
India imports more than 80% of its solar cells and modules from
China, domestic manufacturers have struggled to compete, from
A. Upadhyay, “India completes world’s largest solar tender, aims
to reduce Chinese solar imports”, CleanTechnica, 22 June 2020,
https://cleantechnica.com/2020/06/22/india-completes-worlds-
largest-solar-tender-aims-to-reduce-chinese-solar-imports.
210 “Make in India” from Mints, op. cit. note 204, p. 18; launched tenders
for solar projects linked to cell and module manufacturing capacity,
from SolarPower Europe, Global Market Outlook for Solar Power
2020-2024, op. cit. note 9, p. 77; IEA, “Solar PV”, in Renewables
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https://www.iea.org/reports/renewables-2020/solar-pv#abstract;
in late 2020, incentives linked to production were announced to
attract manufacturers to build facilities in India for domestic use
and export, from Mints, op. cit. note 83, p. 16.
211 SolarPower Europe, op. cit. note 4, p. 29, and from Mints, op. cit.
note 83, p. 22. For more information, see SolarPower Europe,
“Solar Manufacturing Accelerator: Accelerating the deployment
of solar PV manufacturing projects in Europe”, https://www.
solarpowereurope.org/campaigns/manufacturing-accelerator,
viewed 25 April 2021; European Solar Manufacturing Council,
https://esmc.solar, viewed 25 April 2021.
212 Masson, op. cit. note 1, 9 March 2021.
213 “Egypt, China discuss cooperation on sand-to-cell manufacturing”,
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en/business/story/Egypt_China_discuss_cooperation_on_
sandtocell_manufacturing-SNG_188840258; “Egypt-based Enara
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story/Egyptbased_Enara_Energy_pens_deal_with_Chint_
Electric_for_solar_project-SNG_196359277; R. Mahmoud, “Egypt
to begin project to convert sand into solar panels” Al-Monitor,
3 February 2021, https://www.al-monitor.com/originals/2021/02/
egypt-china-local-manufacture-sand-solar-panels-energy.html.
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A cooperation agreement was signed between Enara (Egypt) and
Chint (China) to establish the project, and it will be implemented in
coordination with Egypt’s Ministry of Military Production, from idem.
214 IEA PVPS, Trends in Photovoltaic Applications 2020, op. cit.note 1,
p. 30. See, for example, E. Bellini, “Algeria’s first mounting system
manufacturer, pv magazine, 25 June 2020, https://www.pv-magazine.
com/2020/06/25/algerias-first-mounting-system-manufacturer.
215 E. Bellini, “China will extend duties on US and South Korean
polysilicon for another five years”, pv magazine, 21 January 2020,
https://pv-magazine-usa.com/2020/01/21/china-will-extend-
duties-on-us-and-south-korean-polysilicon-for-another-five-
years; Chen, op. cit. note 202.
216 China’s shares in 2010 and 2020 from IHS Markit, cited in A.
Swanson and C. Buckley, “Chinese solar companies tied to
use of forced labor”, New York Times, 8 January 2021, https://
www.nytimes.com/2021/01/08/business/economy/china-solar-
companies-forced-labor-xinjiang.html.
217 Figure of 45% from Mints, personal communication with REN21, op.
cit. note 1. Xinjiang’s share of production was 40%, from J. Chase,
BloombergNEF, cited in https://www.nytimes.com/2021/01/08/
business/economy/china-solar-companies-forced-labor-xinjiang.
html. Producers drawn to region from Mints, Photovoltaic
Manufacturer Capacity, Shipments, op. cit. note 1, p. 14. About 237
million tonnes of polysilicon are produced in Xinjiang, another 215
million tonnes elsewhere in China, and 116 million tonnes in Europe,
the Republic of Korea, the United States and elsewhere, making
the Xinjiang share nearly 42% of the total, from idem.
218 See, for example, Institute for Energy Research, “Chinese solar
panel production issues are mounting”, 18 November 2020,
https://www.instituteforenergyresearch.org/renewable/solar/
chinese-solar-panel-production-issues-are-mounting; M.
Copley, “Human rights allegations in Xinjiang could jeopardize
solar supply chain”, S&P Global, https://www.spglobal.com/
marketintelligence/en/news-insights/latest-news-headlines/
human-rights-allegations-in-xinjiang-could-jeopardize-solar-
supply-chain-60829945; WION, “Chinese solar companies tied
to use of forced labor”, 9 January 2021, https://www.msn.com/
en-in/news/world/chinese-solar-companies-tied-to-use-of-
forced-labor/ar-BB1cBmFq; A. Hernández-Morales et al., “Fears
over China’s Muslim forced labor loom over EU solar power”,
Politico, 10 February 2021, https://www.politico.eu/article/
xinjiang-china-polysilicon-solar-energy-europe; E. F. Merchant,
“Solar industry pushed to examine supply chain after reports of
forced labor in China”, Greentech Media, 19 January 2021, https://
www.greentechmedia.com/articles/read/solar-industry-pushed-
to-examine-supply-chain-after-reports-of-forced-labor-in-china;
Swanson and Buckley, op. cit. note 216.
219 Chinese government and industry from, for example, PVTIME,
“Lu Jinbiao: Leading Chinese photovoltaic enterprises may be
targets of Solar Energy Industry Association’s anti-‘forced labor’
alliance”, 7 February 2021, http://www.pvtime.org/lu-jinbiao-
leading-chinese-photovoltaic-enterprises-may-be-targets-of-
solar-energy-industry-associations-anti-forced-labor-alliance, and
M. Copley, “Chinese solar group blasts US calls to avoid supplies
from Xinjiang”, S&P Global, 8 February 2021, https://www.spglobal.
com/marketintelligence/en/news-insights/latest-news-headlines/
chinese-solar-group-blasts-us-calls-to-avoid-supplies-from-
xinjiang-62496859. Groups in United States and Europe from,
for example, SolarPower Europe, “Abiding by Human Rights
Standards” (Brussels: 2021), https://www.solarpowereurope.org/
wp-content/uploads/2021/04/Statement-on-Human-Rights ;
SEIA, “Solar industry call to action: Forced labor has no place in
the solar supply chain”, 10 December 2020, https://www.seia.org/
news/solar-industry-call-action-forced-labor-has-no-place-solar-
supply-chain; K. Misbrener, “SEIA asks solar companies to sign
pledge against forced labor in supply chain”, Solar Power World, 10
December 2020, https://www.solarpowerworldonline.com/2020/12/
seia-asks-solar-companies-sign-pledge-against-forced-labor-
in-supply-chain; SEIA, “Ensuring an Ethical & Sustainable Solar
Supply Chain” (Washington, DC: November 2020), https://www.seia.
org/sites/default/files/SEIA-Backgrounder-Supply-Chain-Ethics-
Sustainability . Australia and Japan from P. Mints, Photovoltaic
Manufacturer Capacity, op. cit. note 1, p. 13.
220 SEIA, “Solar industry call to action”, op. cit. note 219. As of
early 2021, 175 companies involved in the industry in the
United States, including leading Chinese solar manufacturers,
had signed a pledge demanding increased transparency
efforts, from D. Murtaugh, “Solar firms eye supply tracing as
China forced labor debated”, Bloomberg, 4 February 2021,
https://www.bloomberg.com/news/articles/2021-02-04/
solar-firms-eye-supply-tracing-as-china-forced-labor-in-focus.
221 SolarPower Europe, op. cit. note 219.
222 Masson, op. cit. note 1, 9 March 2021.
223 Prices for large-quantity buyers from P. Mints, SPV March
Research, The Solar Flare, 26 February 2021, p. 11, and from P.
Mints, Photovoltaic Manufacturer Capacity, op. cit. note 1, p.
15. Another source estimates that module prices were USD
0.2 per watt at the end of 2020, from A. McCrone, “Energy,
transport, sustainability – 10 predictions for 2021”, Bloomberg,
19 January 2021, https://about.bnef.com/blog/energy-transport-
sustainability-10-predictions-for-2021. According to the IEA,
module prices rose from July 2020 to April 2021 due to rising
commodity prices (such as glass and polysilicon) and supply
chain complications. The accidents in polysilicon plans in
Xinjiang almost halved China’s output, pushing prices up 60% in
September, from IEA, “Renewable electricity”, op. cit. note 1.
224 Polysilicon prices rose due to shortages in China, pushing up
wafer and cell prices, from Mints, op. cit. note 223, p. 9; solar glass
prices were up more than 20% by late 2020; higher glass and
polysilicon prices could not be passed along to consumers by
module manufacturers, from idem, p. 11.
225 Figure considers fixed-axis utility-scale systems, from
BloombergNEF, “Scale-up of solar and wind puts existing coal,
gas at risk”, 28 April 2020, https://about.bnef.com/blog/scale-
up-of-solar-and-wind-puts-existing-coal-gas-at-risk. Regarding
variations in energy costs, see, for example: IEA PVPS, Trends
in Photovoltaic Applications 2020, op. cit.note 1, pp. 59-60; I.
Kaizuka, IEA PVPS, “Photovoltaic Market and Industry Trends
2020” webinar, 4 February 2021; Barbose and Darghouth, op.
cit. note 177. For example, US solar PV system costs declined
in all sectors from 2019 to the end of 2020, thanks to declining
module prices, from M. Cox, “Key 2020 US solar PV cost trends
and a look ahead”, Greentech Media, 17 December 2020, https://
www.greentechmedia.com/articles/read/key-2020-us-solar-
pv-cost-trends-and-a-look-ahead. See also SEIA and Wood
Mackenzie, op. cit. note 69, p. 17; SEIA, “Solar industry research
data”, op. cit. note 70. See also NREL, “Documenting a decade
of cost declines for PV systems”, 10 February 2021, https://www.
nrel.gov/news/program/2021/documenting-a-decade-of-cost-
declines-for-pv-systems.html, and D. Feldman et al., U.S. Solar
Photovoltaic System and Energy Storage Cost Benchmark: Q1 2020
(Golden, CO: NREL, January 2021), p. vi, https://www.nrel.gov/
docs/fy21osti/77324 . In Brazil, by contrast, system prices for
distributed generation rose 20% due to high logistical costs and
devaluation of the Brazilian real, following several years of steady
decline, from Greener, cited in E. Bellini, “Brazil’s PV module
demand reached almost 5 GW in 2020”, pv magazine, 10 February
2021, https://www.pv-magazine.com/2021/02/10/brazils-pv-
module-demand-reached-almost-5-gw-in-2020. Japan continues
to see module prices well above the global average, from IEA
PVPS, Trends in Photovoltaic Applications 2020, op. cit.note 1,
pp. 57-58. Factors influencing price from Mints, Photovoltaic
Manufacturer Capacity, op. cit. note 1, pp. 21-22.
226 Mints, op. cit. note 61.
227 “PV trends of 2020: Part 2”, pv magazine, 25 December 2020,
https://www.pv-magazine.com/2020/12/25/pv-trends-of-2020-
part-2. Abu Dhabi’s lowest bid, at USD 13.5 per MWh, was for a
1.2 GW project with a 30-year PPA that should come online in
2022, and Qatar’s lowest was just under USD 15.7 per MWh with
a 25-year PPA in an auction for the country’s first utility-scale
project (800 MW), from idem.
228 Capacity and winning bid in USD from Mints, op. cit. note 61, p.
25. The bid was approximately EUR 11.14 per MWh and for second
solar auction, from “PV trends of 2020: Part 2”, op. cit. note 227;
10 MW project from “Portugal sets record-low global solar price;
California probes power mix after heatwave woes”, Reuters
Events, 2 September 2020, https://analysis.newenergyupdate.
com/solar/portugal-sets-record-low-global-solar-price-
california-probes-power-mix-after-heatwave-woes. Power
purchase agreement period of 15 years from A. Bhambhani, “700
MW solar power auction finally launched in Portugal; DGEG to
accept bids till July 31, 2020 for projects in Alentejo & Algarve
regions”, TaiyangNews, 10 June 2020, http://taiyangnews.info/
markets/portugal-launches-countrys-second-solar-auction.
Storage requirement and compensation from “PV trends of 2020:
Part 2”, op. cit. note 227. The auction was for a total of 700 MW
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https://www.spglobal.com/marketintelligence/en/news-insights/latest-news-headlines/chinese-solar-group-blasts-us-calls-to-avoid-supplies-from-xinjiang-62496859
https://www.spglobal.com/marketintelligence/en/news-insights/latest-news-headlines/chinese-solar-group-blasts-us-calls-to-avoid-supplies-from-xinjiang-62496859
https://www.spglobal.com/marketintelligence/en/news-insights/latest-news-headlines/chinese-solar-group-blasts-us-calls-to-avoid-supplies-from-xinjiang-62496859
https://www.spglobal.com/marketintelligence/en/news-insights/latest-news-headlines/chinese-solar-group-blasts-us-calls-to-avoid-supplies-from-xinjiang-62496859
https://www.solarpowereurope.org/wp-content/uploads/2021/04/Statement-on-Human-Rights
https://www.solarpowereurope.org/wp-content/uploads/2021/04/Statement-on-Human-Rights
https://www.seia.org/news/solar-industry-call-action-forced-labor-has-no-place-solar-supply-chain
https://www.seia.org/news/solar-industry-call-action-forced-labor-has-no-place-solar-supply-chain
https://www.seia.org/news/solar-industry-call-action-forced-labor-has-no-place-solar-supply-chain
https://www.solarpowerworldonline.com/2020/12/seia-asks-solar-companies-sign-pledge-against-forced-labor-in-supply-chain
https://www.solarpowerworldonline.com/2020/12/seia-asks-solar-companies-sign-pledge-against-forced-labor-in-supply-chain
https://www.solarpowerworldonline.com/2020/12/seia-asks-solar-companies-sign-pledge-against-forced-labor-in-supply-chain
https://www.seia.org/sites/default/files/SEIA-Backgrounder-Supply-Chain-Ethics-Sustainability
https://www.seia.org/sites/default/files/SEIA-Backgrounder-Supply-Chain-Ethics-Sustainability
https://www.seia.org/sites/default/files/SEIA-Backgrounder-Supply-Chain-Ethics-Sustainability
https://www.bloomberg.com/news/articles/2021-02-04/solar-firms-eye-supply-tracing-as-china-forced-labor-in-focus
https://www.bloomberg.com/news/articles/2021-02-04/solar-firms-eye-supply-tracing-as-china-forced-labor-in-focus
https://about.bnef.com/blog/energy-transport-sustainability-10-predictions-for-2021
https://about.bnef.com/blog/energy-transport-sustainability-10-predictions-for-2021
https://about.bnef.com/blog/scale-up-of-solar-and-wind-puts-existing-coal-gas-at-risk
https://about.bnef.com/blog/scale-up-of-solar-and-wind-puts-existing-coal-gas-at-risk
https://www.greentechmedia.com/articles/read/key-2020-us-solar-pv-cost-trends-and-a-look-ahead
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https://www.greentechmedia.com/articles/read/key-2020-us-solar-pv-cost-trends-and-a-look-ahead
https://www.nrel.gov/news/program/2021/documenting-a-decade-of-cost-declines-for-pv-systems.html
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https://www.nrel.gov/news/program/2021/documenting-a-decade-of-cost-declines-for-pv-systems.html
https://www.nrel.gov/docs/fy21osti/77324
https://www.nrel.gov/docs/fy21osti/77324
https://www.pv-magazine.com/2021/02/10/brazils-pv-module-demand-reached-almost-5-gw-in-2020
https://www.pv-magazine.com/2021/02/10/brazils-pv-module-demand-reached-almost-5-gw-in-2020
https://www.pv-magazine.com/2020/12/25/pv-trends-of-2020-part-2
https://www.pv-magazine.com/2020/12/25/pv-trends-of-2020-part-2
https://analysis.newenergyupdate.com/solar/portugal-sets-record-low-global-solar-price-california-probes-power-mix-after-heatwave-woes
https://analysis.newenergyupdate.com/solar/portugal-sets-record-low-global-solar-price-california-probes-power-mix-after-heatwave-woes
https://analysis.newenergyupdate.com/solar/portugal-sets-record-low-global-solar-price-california-probes-power-mix-after-heatwave-woes
http://taiyangnews.info/markets/portugal-launches-countrys-second-solar-auction
http://taiyangnews.info/markets/portugal-launches-countrys-second-solar-auction
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under three different remuneration modalities that are linked to the
market regime and included a new remuneration modality for solar
PV plus storage, from Portuguese Renewable Energy Association,
Lisbon, personal communication with REN21, May 2021.
229 Mints, op. cit. note 83, p. 18; U. Gupta, “Solar industry in 2020”, pv
magazine, 28 December 2020,https://www.pv-magazine-india.
com/2020/12/28/solar-industry-in-2020.
230 IEA, op. cit. note 210; “India’s stunning solar bid rides on 12
boosters”, Bloomberg, 26 November 2020, https://www.
bloomberg.com/professional/blog/indias-stunning-solar-bid-
rides-on-12-boosters; U. Gupta, “India sets new record-low solar
tariff of Rs2.36/kWh”, pv magazine, 1 July 2020, https://www.
pv-magazine-india.com/2020/07/01/india-sets-new-record-
low-solar-tariff-of-rs-2-36-kwh; U. Gupta, “Clarify basic customs
duty on solar modules as Change in Law, NSEFI writes to SECI”,
pv magazine, 7 February 2020, https://www.pv-magazine-india.
com/2020/02/07/clarify-basic-customs-duty-on-solar-modules-
as-change-in-law-nsefi-writes-to-seci; A. Gupta, “Record low
tariff bidding for new solar projects, due to chance coming
together of many positives”, EQ International, 4 July 2020, https://
www.eqmagpro.com/record-low-tariff-bidding-for-new-solar-
projects-due-to-chance-coming-together-of-many-positives.
Support policies included the waiving of development fees and
protection from future import duties. India’s low bid ceilings have
been a major cause of undersubscription in auctions, leading
the national government to announce in March the removal of
ceilings for future auctions, from IEA, op. cit. note 210.
231 Firstgreen, “Tariff renegotiations of Solar PPAs. Can we really bring
foreign investments with this level of regulatory uncertainty?”
20 August 2020, https://www.firstgreen.co/tariff-renegotiations-
of-solar-ppas-can-we-really-bring-foreign-investments-with-this-
level-of-regulatory-uncertainty; Ranjan, op. cit. note 60. The Indian
states of Andhra Pradesh, Gujarat, Uttar Pradesh and Telangana
all have attempted to renegotiate prices, Jharkhand renegotiated
prices with developers of 1,200 MW of solar projects, and several
other states attempted to do the same, from idem. Such attempts
have discouraged investors due to regulatory uncertainty and
concerns that contracts will not be honored.
232 N. Pombo-van Zyl, “Eskom keen to renegotiate PPA contracts with
IPPs”, ESI Africa, 22 May 2020, https://www.esi-africa.com/industry-
sectors/generation/eskom-keen-to-renegotiate-ppa-contracts-with-
ipps; T. Creamer, “Controversial plan to renegotiate IPP tariffs is
proceeding, De Ruyter confirms”, Engineering News, 21 May 2020,
https://www.engineeringnews.co.za/article/controversial-plan-to-
renegotiate-of-ipp-tariffs-is-proceeding-de-ruyter-confirms-2020-
05-21/rep_id:4136.
233 M. Hall, “Saudi Arabia commissioned no solar projects last
year”, pv magazine, 11 January 2021, https://www.pv-magazine.
com/2021/01/11/saudi-arabia-commissioned-no-solar-projects-
last-year. Saudi Arabia increased its renewable energy target for
2023 from 9.5 GW to 27.3 GW, with solar providing most of this,
up from 5.9 GW to 20 GW, from Global Data, cited in idem.
234 Masson, op. cit. note 1, 9 March 2021; Y. Rack, “Developers
risk ‘eating their own margin’ in solar’s race to the bottom”,
S&P Global, 1 October 2020, https://www.spglobal.com/
marketintelligence/en/news-insights/latest-news-headlines/
developers-risk-eating-their-own-margin-in-solar-s-race-to-the-
bottom-60543744.
235 Masson, op. cit. note 1, 9 March 2021; J. Deign, “Key to
those record-low solar bids? Rosy merchant income
assumptions”, Greentech Media, 9 August 2019,
https://www.greentechmedia.com/articles/read/
merchant-income-is-key-in-latest-record-solar-bids.
236 Masson, op. cit. note 1, 9 March 2021.
237 Rose in 2020 after falling continuously from T. Sylvia, “Average
PPA prices rose in US market in 2020”, pv magazine, 14 January
2021, https://www.pv-magazine.com/2021/01/14/average-
ppa-prices-rose-in-us-market-in-2020. Average fourth quarter
prices were up 11.5% (to USD 30.56 per MWh) relative to the
same period in 2019, from idem. Reasons for increase from E.
Holbrook, “New report shows power purchase agreement prices
rising across North America”, Environment + Energy Leader, 21
October 2020, https://www.environmentalleader.com/2020/10/
new-report-shows-power-purchase-agreement-prices-rising-
across-north-america; E. Holbrook, “Report: North American PPA
prices rose throughout 2020”, Environment + Energy Leader, 20
January 2021, https://www.environmentalleader.com/2021/01/
report-north-american-ppa-prices-rose-throughout-2020;
T. Sylvia, “Solar PPA prices in the US rise for the second
consecutive quarter — after 18 months of decline”, pv magazine,
16 October 2020, https://pv-magazine-usa.com/2020/10/16/
after-18-months-of-decline-solar-ppa-prices-rise-for-the-second-
consecutive-quarter.
238 I. Gheorghiu, “El Paso Electric sees record low solar prices as it
secures New Mexico project approvals”, Utility Dive, 18 May 2020,
https://www.utilitydive.com/news/el-paso-electric-sees-record-low-
solar-prices-as-it-secures-new-mexico-proj/578113. The projects
and prices are a 100 MW solar PV plant with PPA price of USD 15 per
MWh, and a 100 MW solar PV plus 50 MW storage facility of USD
21 per MWh, from idem. Four solar-plus-storage plants to replace
a large coal-fired power plant, from T. Sylvia, “Solar-plus-storage
replaces coal plant in New Mexico, makes carbon-capture retrofit
moot”, pv magazine, 12 October 2020, https://pv-magazine-usa.
com/2020/10/12/solar-plus-storage-replaces-coal-plant-in-new-
mexico-makes-carbon-capture-retrofit-moot.
239 Pexapark cited in S. Enkhardt, “Rollercoaster for the
European PPA market in 2020”, pv magazine, 21 January
2021, https://www.pv-magazine.com/2021/01/21/
rollercoaster-for-the-european-ppa-market-in-2020.
240 Prices in Germany averaged EUR 41.61 per MWh, from Ibid.;
Denmark and Sweden from H. Edwardes-Evans, “PPA prices dip
in Q4 2020 as developers absorb COVID impacts: LevelTen”, S&P
Global, 13 January 2021, https://www.spglobal.com/platts/en/
market-insights/latest-news/electric-power/011321-ppa-prices-
dip-in-q4-2020-as-developers-absorb-covid-impacts-levelten;
Holbrook, “New report shows power purchase agreement prices
rising across North America”, op. cit. note 237.
241 Down in first half from Mints, op. cit. note 83, pp. 7, 14; up 7% for
entire year from Mints, Photovoltaic Manufacturer Capacity, op.
cit. note 1, p. 13. Capacity increased from 123.5 GWpeak to 131.7
GWpeak, from idem.
242 Mints, Photovoltaic Manufacturer Capacity, op. cit. note 1, pp.
17, 22. In 2020, China alone accounted for 67% of global cell
production capacity, 59% of module assembly capacity and
67% of global shipments, from Mints, Photovoltaic Manufacturer
Capacity, op. cit. note 1, p. 16. China is the top global supplier of
polysilicon (58%), silicon wafers (93%), cells (75%) and modules
(73%), from Jianhua, op. cit. note 199. The United States was the
leader in global solar PV shipments until 1996, and had a 1% share
in 2020, from Mints, op. cit. note 223, pp. 16-17.
243 Based on data from Mints, Photovoltaic Manufacturer Capacity,
op. cit. note 1, pp. 43, 105. Total shipments were 131.7 GWp, with
shipment shares as follows: LONGi (11%), Tongwei (9%), JA Solar
(8%), Aiko Solar (8%), Trina Solar (7%), Jinko Solar (7%), Canadian
Solar (Canada/China – 6%), Zhongli (6%), Suntech (5%) First Solar
(4%), and all others 29% (including Hanwha Q-Cells (Republic of
Korea), at 4%), based on shipments from in-house production of
crystalline and thin-film cells shipped to first buyer, from idem.
244 Thin films accounted for about 5% of global shipments in 2020,
down from 14% in 2011, from Mints, Photovoltaic Manufacturer
Capacity, op. cit. note 1, pp. 19, 70. First Solar accounted for 4%
of total shipments, or about 80% of thin film shipments, based
on data from idem, p. 17.
245 Based on information and sources throughout this text. Much of
the expansion outside of China was by Chinese-based companies
building new facilities or expanding in other countries, especially
in Asia. For example, Suntech (China) began operations at an
integrated cell (500 MW) and module (500 MW) manufacturing
facility in Indonesia in September with plans to expand capacity
to 1 GW by year’s end, from H. Shukla, “Daily news wrap-up:
Suntech’s 1 GW integrated solar cell and module facility opens”,
Mercom India, 18 September 2020, https://mercomindia.com/
daily-news-wrap-up-suntech-facility.
246 J. Zarco, “Production begins at 500 MW Mexican solar panel fab”,
pv magazine, 25 November 2020, https://www.pv-magazine.
com/2020/11/25/production-begins-at-500-mw-mexican-solar-
panel-fab; J. C. Machorro, “México busca la autosuficiencia
en insumos para la industria solar”, Periodismo y Ambiente,
4 December 2020, http://www.periodismoyambiente.com.
mx/2020/12/04/mexico-busca-la-autosuficiencia-en-insumos-
para-la-industria-solar (using Google Translate). Stantec Turkey,
Market Report for Turkey’s Photovoltaic Panel Manufacturing,
November 2020, cited in S. Inal, K. Goytan and A. Ozden
“Turkish PV manufacturer report reveals country’s annual
316
https://www.pv-magazine-india.com/2020/12/28/solar-industry-in-2020
https://www.pv-magazine-india.com/2020/12/28/solar-industry-in-2020
https://www.bloomberg.com/professional/blog/indias-stunning-solar-bid-rides-on-12-boosters
https://www.bloomberg.com/professional/blog/indias-stunning-solar-bid-rides-on-12-boosters
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https://www.pv-magazine-india.com/2020/07/01/india-sets-new-record-low-solar-tariff-of-rs-2-36-kwh
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https://www.esi-africa.com/industry-sectors/generation/eskom-keen-to-renegotiate-ppa-contracts-with-ipps
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https://www.pv-magazine.com/2020/11/25/production-begins-at-500-mw-mexican-solar-panel-fab
https://www.pv-magazine.com/2020/11/25/production-begins-at-500-mw-mexican-solar-panel-fab
http://www.periodismoyambiente.com.mx/2020/12/04/mexico-busca-la-autosuficiencia-en-insumos-para-la-industria-solar
http://www.periodismoyambiente.com.mx/2020/12/04/mexico-busca-la-autosuficiencia-en-insumos-para-la-industria-solar
http://www.periodismoyambiente.com.mx/2020/12/04/mexico-busca-la-autosuficiencia-en-insumos-para-la-industria-solar
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production capacity is 5,610 MW/year”, pv magazine, 19 January
2021, https://www.pv-magazine.com/2021/01/19/turkish-pv-
manufacturer-report-reveals-countrys-annual-production-
capacity-is-5610-mw-year. The Kalyon plant increased Turkey’s
annual manufacturing capacity to 5.6 GW, with all but two
manufacturers being domestic companies; Turkey exports about
one fourth of its production, mostly to Europe and the Middle
East, all from idem.
247 Crystalline and thin-film cell capacity increased from 153.1 GWp
in 2019 to 203.7 GWp in 2020, and module assembly capacity
increased from 185 GWp in 2019 to 248.6 GWp, from Mints,
Photovoltaic Manufacturer Capacity, op. cit. note 1, pp. 13, 15.
Commercial cell production capacity, including thin film and
crystalline cells, increased from 153 GW in 2019 to nearly 191
GW in 2020, and module assembly capacity increased to about
230 GW in 2020, all from Mints, op. cit. note 223, pp. 6-7; module
assembly capacity in 2019 was 185 GW, from Mints, The Solar
Flare, no. 4, op. cit. note 15, pp. 15, 25, 29.
248 Based on data from Mints, op. cit. note 223, p. 6. China accounted
for about 67% of global shipments in 2020, followed by Malaysia
(10%) and Vietnam (9%), from Mints, Photovoltaic Manufacturer
Capacity, op. cit. note 1, p. 31.
249 See, for example, I. Kaizuka, IEA PVPS, “Photovoltaic Market
and Industry Trends 2020” webinar, 4 February 2021. Other
examples from “Solar module manufacturers ZNShine and
Trina to expand production capacity”, Mercom India, 14 August
2020, https://mercomindia.com/solar-module-manufacturers-
znshine-trina; “Trina Solar expands 15 GW new module capacity”,
CleanTechnica, 30 September 2020, https://cleantechnica.
com/2020/09/30/trina-solar-expands-15-gw-new-module-
capacity; M. Osborne, “Tongwei investing US$2.86 billion in
new 30GW solar cell manufacturing hub in China”, PV-Tech,
11 February 2020, https://www.pv-tech.org/news/tongwei-
investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-
hub-i; D. Ayemba, “World’s largest solar modules production
plant to be constructed in China”, Construction News, 8 April
2020, https://constructionreviewonline.com/2020/04/worlds-
largest-solar-modules-production-plant-to-be-constructed-
in-china; “China solar giants get bigger as glut ignites battle
for share”, op. cit. note 199; Z. Shahan, “JinkoSolar begins
construction on 20 gigawatt solar cell factory”, CleanTechnica,
23 January 2021, https://cleantechnica.com/2021/01/23/
jinkosolar-begins-construction-on-20-gigawatt-solar-cell-
factory; J. Parnell, “5 would-be European giga-scale solar
manufacturers”, Greentech Media, 14 October 2020, https://
www.greentechmedia.com/articles/read/5-would-be-giga-
scale-solar-manufacturers; J. Zarco, “Production begins
at 500 MW Mexican solar panel fab”, pv magazine, 25
November 2020, https://www.pv-magazine.com/2020/11/25/
production-begins-at-500-mw-mexican-solar-panel-fab.
250 In addition to sources in previous endnote, see Trinasolar, “Trina
Solar to expand ultra-high-power module production capacity
by 15 GW with latest 3 billion Yuan investment”, 23 September
2020, https://www.trinasolar.com/en-apac/resources/newsroom/
aptrina-solar-expand-ultra-high-power-module-production-
capacity-15gw-latest-3; “The solar-powered future is being
assembled in China”, Bloomberg, 14 September 2020, https://
www.bloomberg.com/features/2020-china-solar-giant-longi.
251 Tongwei from P. Mints, SPV Market Research, The Solar Flare,
28 February 2020, p. 23, and from M. Osborne, “Tongwei investing
US$2.86 billion in new 30GW solar cell manufacturing hub in
China”, PV-Tech, 11 February 2020, https://www.pv-tech.org/
news/tongwei-investing-us2.86-billion-in-new-30gw-solar-
cell-manufacturing-hub-i. Tongwei also announced plans to
expand polysilicon production capacity more than three-fold
by 2023; Tongwei’s goal is to increase polysilicon production
capacity from 80 billion tonnes to 290 billion tonnes by 2023,
from idem. In addition, GCL-System Integration was considering
increasing its modules manufacturing capacity (7.2 GW as of
May) by building a new 60 GW per year factory, from “China’s
solar giants slash prices as virus curbs demand”, op. cit. note
199, from EurObserv’ER, op. cit. note 30, p. 14, and from D.
Ayemba, “World’s largest solar modules production plant to be
constructed in China”, Construction News, 8 April 2020, https://
constructionreviewonline.com/2020/04/worlds-largest-solar-
modules-production-plant-to-be-constructed-in-china.
252 Masson, op. cit. note 1, 4 May 2020, and examples and sources in
this paragraph.
253 Ecosolifer AG from E. Bellini, “A commercial bifacial HJT solar cell
with 24.1% efficiency”, pv magazine, 3 March 2020, https://www.
pv-magazine.com/2020/03/03/a-commercial-bifacial-hjt-solar-
cell-with-24-1-efficiency; Hevel Group, “Hevel Group launches
HJT solar cell production based on M2+ wafers”, pv magazine, 14
April 2020, https://www.pv-magazine.com/press-releases/hevel-
group-launches-hjt-solar-cell-production-based-on-m2-wafers;
Meyer Burger shift to HJT, from Mints, op. cit. note 204, p. 22; M.
Osborne, “Meyer Burger to start exclusive heterojunction solar
module manufacturing in the first half of 2021”, PV-Tech, 19 June
2020, https://www.pv-tech.org/meyer-burger-to-start-exclusive-
heterojunction-solar-module-manufacturing-i; S. Hanley, “Meyer
Burger plans 10 gigawatts of floating solar for North Rhine-
Westphalia”, CleanTechnica, 4 May 2020, https://cleantechnica.
com/2020/05/04/meyer-burger-plans-10-gigawatts-of-floating-
solar-for-north-rhine-westpahlia; plans to scale up by 2026 from
Parnell, op. cit. note 249. The company also announced (early
2021) plans to enter the US market to start selling cells in H2
2021, from H. Shukla, “Meyer Burger reports a net loss of CHF
64.47 million in 2020”, 15 March 2021, https://mercomindia.com/
meyer-burger-reports-net-loss-2020. In addition, 3Sun (owned
by utility Enel, Italy), had plans to expand a Sicilian cell and
module facility that opened in 2019, from Parnell, op. cit. note
249, and panel manufacturer REC (US) was planning to build
a new factory in France to make modules compliant with the
country’s low-carbon rules for large-scale plants, from J. Spaes,
“REC identifies location for 4 GW solar module factory in France”,
18 November 2020, https://www.pv-magazine.com/2020/11/18/
rec-identifies-location-for-4-gw-solar-module-factory-in-france.
254 P. Sanchez Molina, “Another solar module factory in North
Africa”, pv magazine, 24 July 2020, https://www.pv-magazine.
com/2020/07/24/another-solar-module-factory-in-north-africa.
255 Mints, op. cit. note 61, p. 11. By one estimate, about 180 Chinese
manufacturers exited the industry or went bankrupt over the
previous four years, from Y. Jiang, BloombergNEF, cited in “The
solar-powered future is being assembled in China”, op. cit. note
250. Consolidation also continued in China’s polysilicon industry,
from Chen, op. cit. note 202.
256 Jiang, cited in “The solar-powered future is being assembled in
China”, op. cit. note 250.
257 Borrowing and rising prices from Ibid.; Yingli entered
restructuring in June 2020 after falling into bankruptcy, from
Mints, op. cit. note 204, p. 25; brought under government control
and renamed from Mints, op. cit. note 83, pp. 6, 33.
258 Ended partnership from Willson, op. cit. note 208, and from F.
Lambert, “Tesla and Panasonic end solar deal at Gigafactory
New York ahead of battery event”, Electrek, 26 February 2020,
https://electrek.co/2020/02/26/tesla-panasonic-end-solar-deal-
gigafactory-new-york-battery. Panasonic stopped manufacturing
modules in the United States to streamline global operations,
from idem (both sources). Panasonic entered the solar sector
in 2008 by purchasing pieces of Sanyo Solar, and completed
acquisition in 2010, from Mints, op. cit. note 223, p. 30; pandemic
and pricing from idem, p. 31; end all production from idem, p. 29.
259 N. Huang and A. Hwang, “Invetec subsidiary ends solar cell
production”, DigiTimes, 19 August 2020, https://www.digitimes.
com/news/a20200819PD208.html; Mints, Photovoltaic
Manufacturer Capacity, op. cit. note 1, pp. 8, 33.
260 SunPower, “Company history”, https://us.sunpower.com/company/
history, viewed 12 April 2021; SunPower, “SunPower and Maxeon
Solar Technologies close spin-off transaction”, 27 August 2020,
https://newsroom.sunpower.com/2020-08-27-SunPower-and-
Maxeon-Solar-Technologies-Close-Spin-Off-Transaction; SunPower,
“SunPower Corporation to close manufacturing facility in Hillsboro,
Oregon”, 7 January 2021, https://newsroom.sunpower.com/2021-
01-07-SunPower-Corporation-to-Close-Manufacturing-Facility-
in-Hillsboro-Oregon; SunPower, “SunPower expands SunPower
Residential Installation (SPRI) across six states”, 26 January 2021,
https://newsroom.sunpower.com/2021-01-26-SunPower-Expands-
SunPower-Residential-Installation-SPRI-Across-Six-States.
261 Mints, op. cit. note 61, p. 28; “New US clean energy jobs
plummet; First Solar sells O&M division to NovaSource”, Reuters
Events, 19 August 2020, https://analysis.newenergyupdate.
com/solar/new-us-clean-energy-jobs-plummet-first-solar-
sells-om-division-novasource; E. F. Merchant, “First Solar sells
off majority of development pipeline”, Greentech Media, 25
January 2021, https://www.greentechmedia.com/articles/read/
first-solar-sells-off-majority-of-development-pipeline.
317
https://www.pv-magazine.com/2021/01/19/turkish-pv-manufacturer-report-reveals-countrys-annual-production-capacity-is-5610-mw-year
https://www.pv-magazine.com/2021/01/19/turkish-pv-manufacturer-report-reveals-countrys-annual-production-capacity-is-5610-mw-year
https://www.pv-magazine.com/2021/01/19/turkish-pv-manufacturer-report-reveals-countrys-annual-production-capacity-is-5610-mw-year
https://mercomindia.com/solar-module-manufacturers-znshine-trina
https://mercomindia.com/solar-module-manufacturers-znshine-trina
https://cleantechnica.com/2020/09/30/trina-solar-expands-15-gw-new-module-capacity
https://cleantechnica.com/2020/09/30/trina-solar-expands-15-gw-new-module-capacity
https://cleantechnica.com/2020/09/30/trina-solar-expands-15-gw-new-module-capacity
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://cleantechnica.com/2021/01/23/jinkosolar-begins-construction-on-20-gigawatt-solar-cell-factory
https://cleantechnica.com/2021/01/23/jinkosolar-begins-construction-on-20-gigawatt-solar-cell-factory
https://cleantechnica.com/2021/01/23/jinkosolar-begins-construction-on-20-gigawatt-solar-cell-factory
https://www.greentechmedia.com/articles/read/5-would-be-giga-scale-solar-manufacturers
https://www.greentechmedia.com/articles/read/5-would-be-giga-scale-solar-manufacturers
https://www.greentechmedia.com/articles/read/5-would-be-giga-scale-solar-manufacturers
https://www.pv-magazine.com/2020/11/25/production-begins-at-500-mw-mexican-solar-panel-fab
https://www.pv-magazine.com/2020/11/25/production-begins-at-500-mw-mexican-solar-panel-fab
https://www.trinasolar.com/en-apac/resources/newsroom/aptrina-solar-expand-ultra-high-power-module-production-capacity-15gw-latest-3
https://www.trinasolar.com/en-apac/resources/newsroom/aptrina-solar-expand-ultra-high-power-module-production-capacity-15gw-latest-3
https://www.trinasolar.com/en-apac/resources/newsroom/aptrina-solar-expand-ultra-high-power-module-production-capacity-15gw-latest-3
https://www.bloomberg.com/features/2020-china-solar-giant-longi
https://www.bloomberg.com/features/2020-china-solar-giant-longi
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://www.pv-tech.org/news/tongwei-investing-us2.86-billion-in-new-30gw-solar-cell-manufacturing-hub-i
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://constructionreviewonline.com/2020/04/worlds-largest-solar-modules-production-plant-to-be-constructed-in-china
https://www.pv-magazine.com/2020/03/03/a-commercial-bifacial-hjt-solar-cell-with-24-1-efficiency
https://www.pv-magazine.com/2020/03/03/a-commercial-bifacial-hjt-solar-cell-with-24-1-efficiency
https://www.pv-magazine.com/2020/03/03/a-commercial-bifacial-hjt-solar-cell-with-24-1-efficiency
https://www.pv-magazine.com/press-releases/hevel-group-launches-hjt-solar-cell-production-based-on-m2-wafers
https://www.pv-magazine.com/press-releases/hevel-group-launches-hjt-solar-cell-production-based-on-m2-wafers
https://www.pv-tech.org/meyer-burger-to-start-exclusive-heterojunction-solar-module-manufacturing-i
https://www.pv-tech.org/meyer-burger-to-start-exclusive-heterojunction-solar-module-manufacturing-i
https://cleantechnica.com/2020/05/04/meyer-burger-plans-10-gigawatts-of-floating-solar-for-north-rhine-westpahlia
https://cleantechnica.com/2020/05/04/meyer-burger-plans-10-gigawatts-of-floating-solar-for-north-rhine-westpahlia
https://cleantechnica.com/2020/05/04/meyer-burger-plans-10-gigawatts-of-floating-solar-for-north-rhine-westpahlia
https://mercomindia.com/meyer-burger-reports-net-loss-2020
https://mercomindia.com/meyer-burger-reports-net-loss-2020
https://www.pv-magazine.com/2020/11/18/rec-identifies-location-for-4-gw-solar-module-factory-in-france
https://www.pv-magazine.com/2020/11/18/rec-identifies-location-for-4-gw-solar-module-factory-in-france
https://www.pv-magazine.com/2020/07/24/another-solar-module-factory-in-north-africa
https://www.pv-magazine.com/2020/07/24/another-solar-module-factory-in-north-africa
https://electrek.co/2020/02/26/tesla-panasonic-end-solar-deal-gigafactory-new-york-battery
https://electrek.co/2020/02/26/tesla-panasonic-end-solar-deal-gigafactory-new-york-battery
https://www.digitimes.com/news/a20200819PD208.html
https://www.digitimes.com/news/a20200819PD208.html
https://us.sunpower.com/company/history
https://us.sunpower.com/company/history
https://newsroom.sunpower.com/2020-08-27-SunPower-and-Maxeon-Solar-Technologies-Close-Spin-Off-Transaction
https://newsroom.sunpower.com/2020-08-27-SunPower-and-Maxeon-Solar-Technologies-Close-Spin-Off-Transaction
https://newsroom.sunpower.com/2021-01-07-SunPower-Corporation-to-Close-Manufacturing-Facility-in-Hillsboro-Oregon
https://newsroom.sunpower.com/2021-01-07-SunPower-Corporation-to-Close-Manufacturing-Facility-in-Hillsboro-Oregon
https://newsroom.sunpower.com/2021-01-07-SunPower-Corporation-to-Close-Manufacturing-Facility-in-Hillsboro-Oregon
https://newsroom.sunpower.com/2021-01-26-SunPower-Expands-SunPower-Residential-Installation-SPRI-Across-Six-States
https://newsroom.sunpower.com/2021-01-26-SunPower-Expands-SunPower-Residential-Installation-SPRI-Across-Six-States
https://analysis.newenergyupdate.com/solar/new-us-clean-energy-jobs-plummet-first-solar-sells-om-division-novasource
https://analysis.newenergyupdate.com/solar/new-us-clean-energy-jobs-plummet-first-solar-sells-om-division-novasource
https://analysis.newenergyupdate.com/solar/new-us-clean-energy-jobs-plummet-first-solar-sells-om-division-novasource
https://www.greentechmedia.com/articles/read/first-solar-sells-off-majority-of-development-pipeline
https://www.greentechmedia.com/articles/read/first-solar-sells-off-majority-of-development-pipeline
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262 Vivint Solar, “Sunrun announces definitive agreement to acquire
Vivint Solar for an enterprise value of $3.2 billion”, 7 June 2020,
https://www.vivintsolar.com/newsroom/press-releases/
sunrun-difinitive-agree-ment-to-aquire-vivint-solar; I. Penn,
“Solar deal would create a new industry giant”, New York Times,
6 July 2020, https://www.nytimes.com/2020/07/06/business/
energy-environment/sunrun-vivint-solar.html; P. Eavis and I.
Penn, “Home solar is growing, but big installers are still losing
money”, New York Times, 4 January 2021, https://www.nytimes.
com/2021/01/04/business/energy-environment/rooftop-solar-
installers.html; largest consolidation from R. Ranjan, “In the
largest rooftop solar acquisition, Sunrun to acquire Vivint Solar
for $3.2 billion”, Mercom India, 7 July 2020, https://mercomindia.
com/sunrun-acquire-vivint-solar.
263 J. St. John, “Hanwha Q Cells to buy storage software startup Geli
to tackle C&I market”, Greentech Media, 6 August 2020, https://
www.greentechmedia.com/articles/read/hanwha-q-cells-buys-
geli-to-tap-into-north-american-ci-solar-storage-market; Geli,
“Geli to be acquired by Q Cells, expanding Q Cells’ offerings in
Integrated Energy Storage Solutions”, 6 August 2020, https://geli.
net/2020/08/geli_to_be_acquired_by_q_cells.
264 See sources throughout this paragraph. See also Wind Power
section in this chapter.
265 J. Deign, “The solar industry’s new power player: Oil
majors”, Greentech Media, 26 February 2020, https://www.
greentechmedia.com/articles/read/the-solar-industrys-new-
power-player-oil-majors; Total, “Spain: Total to enter into the
solar market with a pipeline of 2 GW of projects”, 11 February
2020, https://www.total.com/media/news/press-releases/spain-
total-enter-solar-market-pipeline-2-gw-projects; “Midwest leads
drop in US solar prices; European fund buys into giant Canadian
merchant project”, Reuters Events, 12 February 2020, https://
www.reutersevents.com/renewables/pv-insider/midwest-leads-
drop-us-solar-prices-european-fund-buys-giant-canadian-
merchant-project. Companies include BP (UK), Eni (Italy),
Equinor (Norway), Galp Energia (Portugal), Repsol (Spain), Shell
(Netherlands) and Total (France).
266 J. Parnell, “BP links with JinkoPower to bring clean energy to
China’s companies”, Greentech Media, 6 July 2020, https://www.
greentechmedia.com/articles/read/bp-and-jinko-buddy-up-on-ci-
solar-in-china; P. Sanchez Molina, “Hydrogen production coupled
to solar and storage to debut in Spain”, pv magazine, 2 March
2020, https://www.pv-magazine.com/2020/03/02/hydrogen-
production-coupled-to-solar-and-storage-to-debut-in-spain.
267 The company has been working on perovskite cells for
several years; in 2020 its cells exceeded several International
Electrotechnical Commission durability thresholds, from
Hunt, “Hunt achieves key milestone in perovskite technology
development”, 12 February 2020, https://huntperovskite.com/
wp-content/uploads/2020/08/20200212-Hunt-Perovskite-
Technologies-Press-Release-Final ; “Hunt Perovskite
Technologies reports 18% efficiency with its ink-based solar
cell process”, Perovskite Info, 13 February 2020, https://www.
perovskite-info.com/hunt-perovskite-technologies-reports-18-
efficiency-its-ink-based-solar-cell. See also C. Helman, “Why
a famed Texas oil family is hunting for cheap solar power from
‘Perovskites’”, Forbes, 25 February 2020, https://www.forbes.
com/sites/christopherhelman/2020/02/25/why-a-famed-texas-
oil-family-is-hunting-for-cheap-solar-power-from-perovskites;
T. Casey, “Super secret perovskite solar cell company bursts
out of stealth mode”, CleanTechnica, 29 February 2020, https://
cleantechnica.com/2020/02/29/super-secret-perovskite-solar-
cell-company-bursts-out-of-stealth-mode; PR Newswire, “Hunt
Energy announces Scott Burton as new CEO of Hunt Perovskite
Technologies”, 19 August 2020, https://www.prnewswire.com/
news-releases/hunt-energy-announces-scott-burton-as-new-
ceo-of-hunt-perovskite-technologies-301114937.html; patents
from Hunt, “Hunt Perovskite Technologies adds another key
patent in perovskite durability via Ink Chemistry”, 2 November
2020, https://huntperovskite.com/wp-content/uploads/2020/11/
Hunt-Perovskite-Technologies-Press-Release .
268 Pyper, op. cit. note 204; R. Ranjan, “Coal India to set up integrated
solar wafer manufacturing facility”, Mercom India, 29 December
2020, https://mercomindia.com/coal-india-to-set-up.
269 Solar cells and modules, value chain from Schmela, op. cit.
note 1, 12 May 2020. See also information and related sources
throughout this section.
270 See, for example, “JinkoSolar claims world record for bifacial solar
module efficiency”, Power Engineering International, 21 January
2020, https://www.powerengineeringint.com/2020/01/21/
jinkosolar-claims-world-record-for-bifacial-solar-module-
efficiency; E. Bellini, “Solar modules from Sharp with half-cut
technology exceed 19.5% efficiency”, pv magazine, 14 January
2020, https://pv-magazine-usa.com/2020/01/14/solar-modules-
from-sharp-with-half-cut-technology-exceed-19-5-efficiency;
R. Ranjan, “Panasonic claims highest conversion efficiency of
16.09% for perovskite solar panel”, Mercom India, 14 February
2020, https://mercomindia.com/panasonic-claims-conversion-
efficiency-perovskite-solar-panel; S. Enkhardt, “German scientists
develop solar facade with 50% higher yield”, pv magazine, 3
March 2020, https://www.pv-magazine.com/2020/03/03/
german-scientists-develop-solar-facade-with-50-higher-
yield; C. June, “Urban solar energy: Solar panels for windows
hit record 8% efficiency”, Michigan Engineer News Center,
17 August 2020, https://news.engin.umich.edu/2020/08/
urban-solar-energy-solar-panels-for-windows-hit-record-8-
efficiency; R. Ranjan, “Canadian Solar says it has achieved a
record solar cell efficiency of 23.81%”, Mercom India, 19 March
2020, https://mercomindia.com/canadian-solar-achieved-
solar-cell-efficiency; Sonnenseite, “World record: Efficiency of
perovskite silicon tandem solar cell jumps to 29.15 per cent”,
24 February 2020, https://www.sonnenseite.com/en/science/
world-record-efficiency-of-perovskite-silicon-tandem-solar-
cell-jumps-to-29.15-per-cent.html; R. Ranjan, “New perovskite
CIGS tandem cell achieves record efficiency of 24.16%”, Mercom
India, 29 April 2020, https://mercomindia.com/new-perovskite-
cigs-tandem-cell-efficiency; H. Shukla, “Weekly news wrap-up:
Jinko’s solar cell efficiency at 24.79%, Sungrow launches new
ESS”, Mercom India, 14 August 2020, https://mercomindia.
com/news-wrap-up-jinko-solar; Renewable Energy Magazine,
“Oxford PV hits new world record for solar cell”, 21 December
2020, https://www.renewableenergymagazine.com/pv_solar/
oxford-pv-hits-new-world-record-for-20201221; M. Hutchins,
“The state of the art in perovskite tandems”, pv magazine, 7
January 2021, https://www.pv-magazine.com/2021/01/07/
the-state-of-the-art-in-perovskite-tandems.
271 Lost and regained lead from Mints, The Solar Flare, no. 6 (23
December 2019), pp. 6, 12; S. Dutta, “Global module suppliers
Trina and Canadian Solar announce world record efficiencies”,
Mercom India, 31 May 2019, https://mercomindia.com/trina-
and-canadian-solar-record-efficiencies; J. Chase et al., “On
prices, technology and 2019 trends”, pv magazine, 6 September
2019, https://www.pv-magazine-australia.com/2019/09/06/
on-prices-technology-and-2019-trends. Share of global
shipments from Mints, Photovoltaic Manufacturer Capacity,
op. cit. note 1, p. 15; expansions were monocrystalline, from
SolarPower Europe, Global Market Outlook for Solar Power
2019-2023, op. cit. note 7, p. 49; SolarPower Europe, Global
Market Outlook for Solar Power 2020-2024, op. cit. note 9, p.
55; P. Mints, SPV Market Research, The Solar Flare, 31 October
2020, p. 19. For information on mono- v. multi-/poly-crystalline
technologies, see, for example, Evergreen Solar, “January 2020
best type of solar panels”, https://evergreensolar.com/types,
viewed 20 March 2020; Gold Coast Solar Power Solutions,
“Mono crystalline or poly/multi crystalline solar panels – does
it matter?” https://gold-coast-solar-power-solutions.com.au/
posts/mono-crystalline-or-poly-multi-crystalline-solar-panels-
does-it-matter, viewed 20 March 2020; “Monocrystalline and
polycrystalline solar panels: What you need to know”, Energy
Sage, 12 December 2019, https://www.energysage.com/solar/101/
monocrystalline-vs-polycrystalline-solar-panels.
272 “The solar-powered future is being assembled in China”, op. cit.
note 250; SolarPower Europe, Global Market Outlook for Solar
Power 2020-2024, op. cit. note 9, p. 55; Mints, op. cit. note 271, p. 19.
273 See sources below. The main reason for enlarging wafers has
been to continue with PERC for as long as possible because this
is less costly than investing in new cell production equipment for
new cell technology, from Schmela, op. cit. note 1, 26 May 2021.
274 Increasing size to optimise costs from “PV trends of 2020:
Part 3”, pv magazine, 28 December 2020, https://www.
pv-magazine.com/2020/12/28/pv-trends-of-2020-part-3, and
from M. Hutchins, “The weekend read: Big, and then bigger”,
pv magazine, 12 December 2020, https://www.pv-magazine.
com/2020/12/12/the-weekend-read-big-and-then-bigger.
Increase power from SolarPower Europe, Global Market Outlook
for Solar Power 2020-2024, op. cit. note 9, p. 55. See also M.
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https://www.pv-magazine.com/2020/12/12/the-weekend-read-big-and-then-bigger
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR PV
Hutchins, “The weekend read: Big, and then bigger”, pv magazine,
12 December 2020, https://www.pv-magazine.com/2020/12/12/
the-weekend-read-big-and-then-bigger.
275 By 2020 increasing sizes, from “PV trends of 2020: Part 3”, op.
cit. note 274; SolarPower Europe, Global Market Outlook for
Solar Power 2020-2024, op. cit. note 9, p. 55. For many years
the traditional wafer size was 156 millimetres, or M0, which was
overtaken by 156.75 (M2) in 2017; M2 was already being displaced
in 2020, and many manufacturers were shifting from M6 (166
millimetres, mm), first introduced in 2019, to M10 (182 mm) and
M12 (210 mm), from idem, both sources. Most major module
manufacturers from “PV trends of 2020: Part 3”, op. cit. note 274.
The size changes require that the downstream sectors also adjust
to different physical and electrical characteristics of the new
modules, from idem.
276 Left behind from R. Ranjan, “Changing wafer sizes will cost
cell and solar module manufacturers”, Mercom India, 20
January 2021, https://mercomindia.com/changing-wafer-
sizes-cost-module-manufacturers. Indian manufacturers, for
example, were still transitioning to the M6 wafer size in 2020,
from idem. Increased costs from R. Ranjan, “Technological
upgrades imperative for India’s solar manufacturing to take-
off”, op. cit. note 209, and from T. Sylvia, “Manufacturers
call for module size standardization”, pv magazine, 5
January 2021, https://www.pv-magazine.com/2021/01/05/
manufacturers-call-for-module-size-standardization.
277 Sylvia, op. cit. note 276.
278 Steer a shift from SolarPower Europe, Global Market Outlook for
Solar Power 2020-2024, op. cit. note 9, p. 57; cell shipments from
P. Mints, SPV Market Research, The Solar Flare, April 2021, p. 12.
Monocrystalline PERC provides increase in efficiency (by 0.5-1
percentage points) with little increase in the cost of production
and has become the new standard cell, from SolarPower
Europe, Global Market Outlook for Solar Power 2020-2024, op.
cit. note 9, p. 57. PERC cells produce 6-12% more energy than
conventional solar panels, from Sunpower, “What is PERC solar
cell technology?” https://us.sunpower.com/solar-resources/
what-perc-solar-cell-technology, viewed 17 March 2021.
279 PERC from SolarPower Europe, Global Market Outlook for Solar
Power 2020-2024, op. cit. note 9, p. 57. Shifting from idem, pp.
57-58; Schmela, op. cit. note 1, 26 May 2021; J. P. de Villiers,
Soventix South Africa, cited in “Surprising trends influencing
solar PV technology”, ESI Africa, 25 November 2020,https://
www.esi-africa.com/industry-sectors/renewable-energy/
surprising-trends-influencing-solar-pv-technology; Mints, op.
cit. note 278, p. 12; IEA PVPS, Trends in Photovoltaic Applications
2020, op. cit. note 1, pp. 7, 42-43. Most cell capacity added in 2020
and early 2021 was basically PERC-based, from Schmela, op.
cit. note 1, 26 May 2021. However, manufacturers are shifting to
n-Type production capacity, especially HJT (as noted), TOPCon
and n-PERC, from Mints, op. cit. note 278. For information
on n-type cell technologies, see K. Pickerel, “The different
between n-type and p-type solar cells”, Solar Power World, 2
July 2018, https://www.solarpowerworldonline.com/2018/07/
the-difference-between-n-type-and-p-type-solar-cells.
280 TOPCon from SolarPower Europe, Global Market Outlook for
Solar Power 2020-2024, op. cit. note 9, p. 57. PERC production
lines can be upgraded to TOPCon (passivated contact cells),
which many consider to be the next generation of solar cell after
PERC, from K. S. Chan, “What is a TOPCON solar cell?” KSChan,
21 November 2019, https://www.kschan.com/what-is-a-topcon-
solar-cell. HJT from SolarPower Europe, Global Market Outlook
for Solar Power 2019-2023, op. cit. note 7, p. 49; converting
factories from, for example, S. Chunduri, “Heterojunction
solar technology 2019 report. TaiyangNews’ first report on
heterojunction technology (HJT) explores if this promising
high-efficiency silicon cell species is the next big thing in solar
cell/module manufacturing”, TaiyangNews, 20 March 2019, http://
taiyangnews.info/reports/heterojunction-solar-technology-
2019-report; Recom Solar, “Heterojunction technology: The
solar cell of the future”, https://recom-solar.com/innovation,
viewed 29 April 2019; low temperatures and fewer steps from
G. Roters et al., Heterojunction Technology: The Solar Cell of the
Future (Gwatt, Switzerland: Meyer Burger, undated), https://
www.meyerburger.com/user_upload/dashboard_news_bundle/
da4c7a0b7c33e8e21ccddace78c76513b12cc727 . See also
“Risen Energy introduces 3 new high-power modules with
440W, 450W & 500W based on different technologies, incl. HJT,
M12”, TaiyangNews, 13 December 2019, http://taiyangnews.info/
technology/risen-energy-announces-500-w-hjt-modules, and
K. Pickerel, “What are heterojunction technology (HJT) solar
panels?” Solar Power World, 4 November 2019, https://www.
solarpowerworldonline.com/2019/11/what-are-heterojunction-
technology-hjt-solar-panels. In 2020, a number of China-based
companies were actively looking into HJT, and some brought
additional production lines into operation from for example,
“EnergyTrend survey on solar PV prices across supply chain
In China; Jinnergy goes M6, CSI setting up 250 MW HJT line”,
TaiyangNews, 9 July 2020, http://taiyangnews.info/markets/
china-pv-snippets-price-update-hjt-news; Jinergy, “Jinergy HJT
cell efficiency to reach 24.2% by the end of 2020”, 28 October
2020, https://en.prnasia.com/releases/apac/jinergy-hjt-cell-
efficiency-to-reach-24-2-by-the-end-of-2020-296427.shtml;
“China’s GS-Solar claims 25.2% as ‘highest efficiency’ for mass
produced heterojunction solar cells, certified by Germany’s TÜV
Nord”, TaiyangNews , 19 February 2021, http://taiyangnews.info/
technology/25-2-efficiency-for-gs-solar-hjt-solar-cell. China had
almost 10 GW of HJT cell capacity in construction by late 2020,
from Jinergy, op. cit. this note. See also J. Gifford, “Long read: Time
is now for HJT”, pv magazine, 19 September 2020, https://www.
pv-magazine-australia.com/2020/09/19/long-read-time-is-now-
for-hjt, and Pickerel, op. cit. this note.
281 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 57. At the current pace of development,
with improvements of 0.5 to 0.6% annually, cell technologies will
soon reach their practical efficiency limits, from idem.
282 Research dollars and increasing efficiencies, from, for example,
US DOE, Office of Energy Efficiency & Renewable Energy
(EERE), “Solar Energy Technologies Office Fiscal Year 2020
Perovskite Funding Program”,https://www.energy.gov/eere/solar/
solar-energy-technologies-office-fiscal-year-2020-perovskite-
funding-program, viewed 28 April 2021; E. Wesoff, “VC funding
in solar 2020: Perovskites, silicon and utility-scale foundations,
plus lots of software”, pv magazine, 16 December 2020, https://
pv-magazine-usa.com/2020/12/16/vc-funding-in-solar-2020-
perovskites-silicon-and-utility-scale-foundations-plus-lots-
of-software; European Perovskite Initiative, Perovskite-based
Photovoltaics: A Unique Chance for European PV-Industry
(Warsaw: September 2019), p. 3, https://www.zsw-bw.de/
uploads/media/EPKI_Perovskite_White_Paper_2019-09_01.
pdf; T. Metcalfe, “Solar panels are reaching their limit. These
crystals could change that.” NBC News, 19 April 2021, https://
www.nbcnews.com/science/environment/solar-panels-are-
reaching-limit-crystals-change-rcna545.Reports of about 3%
efficiency in 2006 to more than 25% in 2020, from US DOE, EERE,
“Perovskite solar cells”, https://www.energy.gov/eere/solar/
perovskite-solar-cells, viewed 17 March 2021, and from European
Perovskite Initiative, “Perovskite solar cells: A new paradigm in
photovoltaics”, PV-Tech, 17 October 2019, https://www.pv-tech.
org/corporate-updates/perovskite-solar-cells-a-new-paradigm-
in-photovoltaics; efficiency of 29.52% was achieved in a silicon-
based tandem in 2020, M. Hutchins, “Oxford PV retakes tandem
cell efficiency record”, pv magazine, 21 December 2020, https://
www.pv-magazine.com/2020/12/21/oxford-pv-retakes-tandem-
cell-efficiency-record. Closer to commercialisation from “PV
trends of 2020: Part 4”, pv magazine, 29 December 2020, https://
www.pv-magazine.com/2020/12/29/pv-trends-of-2020-part-4.
283 The efficiency record was certified by NREL, from Hutchins, op.
cit. note 282; ramp up and launch from idem and from M. Gallucci,
“Perovskite Solar out-benches rivals in 2021”, IEEE Spectrum,
1 January 2021, https://spectrum.ieee.org/tech-talk/energy/
renewables/oxford-pv-sets-new-record-for-perovskite-solar-cells.
The company pushed back its launch of commercial production
from 2021 to 2022 due to the pandemic and various delays.
284 A. Lydon, “Forget silicon. This material could be a game-changer
for solar power”, CNN, 14 October 2020, https://www.cnn.com/
2020/10/14/energy/solar-energy-perovskites-spc-intl/index.html.
285 Research under way from, for example, US DOE, EERE,
“Perovskite solar cells”, op. cit. note 282; Y. Cholteeva, “Record-
breaking solar perovskites”, Power Technology, 6 May 2020,
https://www.power-technology.com/features/record-breaking-
solar-perovskites; “Perovskite solar cells made with peppermint
oil and walnut aroma food additives, preventing lead leakage”,
Science Daily, 26 February 2020, https://www.sciencedaily.
com/releases/2020/02/200226102144.htm; I. Fadelli, “Inverted
perovskite solar cells with a power conversion efficiency of
22.3%”, TechXplore, 20 February 2020, https://techxplore.com/
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news/2020-02-inverted-perovskite-solar-cells-power.html; R.
Sanders, “Blue diode illustrates limitations, promise of perovskite
semiconductors”, Berkeley News, 24 January 2020, https://news.
berkeley.edu/2020/01/24/blue-diode-illustrates-limitations-
promise-of-perovskite-semiconductors; NREL, “Researchers
improve safety of lead-based perovskite solar cells”, press release
(Golden, CO: 19 February 2020), https://www.nrel.gov/news/
press/2020/researchers-improve-safety-lead-based-perovskite-
solar-cells.html; Sonnenseite, “Plants absorb lead from perovskite
solar cells more than expected”, 22 February 2020, https://
www.sonnenseite.com/en/science/plants-absorb-lead-from-
perovskite-solar-cells-more-than-expected.html; “Game-changer
in future solar technology: New perovskite solar modules with
greater size, power and stability”, SciTech Daily, 27 January
2021, https://scitechdaily.com/game-changer-in-future-solar-
technology-new-perovskite-solar-modules-with-greater-size-
power-and-stability. Other companies working on perovskite
technology include Energy Materials (US), Hunt Perovskite
Technologies (US) and Microquanta Semiconductor (China),
from Cholteeva, op. cit. this note; Evolar (Sweden) from L. Stoker,
“Solar perovskite start-up Evolar bags new investment to target
rapid commercialization”, PV-Tech, 17 November 2020, https://
www.pv-tech.org/solar-perovskite-start-up-evolar-bags-new-
investment-to-target-rapid-commercialisation.
286 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 59, and sources provided throughout this
paragraph.
287 Ibid., p. 59, and Schmela, op. cit. note 1, 26 May 2021. The
industry average for all modules produced, as of October
2020, was 400 W, from Mints, op. cit. note 271, p. 19, and the
average module wattage for all of 2020 was 435 W, from Mints,
Photovoltaic Manufacturer Capacity, op. cit. note 1, p. 13. For
example, in May, JinkoSolar launched what was then the most
powerful panel (530 W) for utility-scale solar, from Jinko Solar,
“JinkoSolar launches the world’s most powerful utility solar
panel”, ESI Africa, 20 May 2020, https://www.esi-africa.com/
industry-sectors/generation/solar/jinkosolar-launches-the-
worlds-most-powerful-utility-solar-panel. It was passed by
Trina Solar later in the year with a 600 W module and upgraded
panels ranging from 635-660 W, from V. Shaw, “Trina reveals
600 W module”, pv magazine, 20 July 2020, https://www.
pv-magazine.com/2020/07/20/trina-reveals-600-w-module; E.
Bellini, “New 635-660 W module series from Trina”, pv magazine,
19 August 2020, https://www.pv-magazine.com/2020/08/19/
new-635-660-w-module-series-from-trina. Trina also launched
two 500 W PERC mono bifacial modules in early 2020, from
E. Bellini, “Trina unveils two 500 W bifacial solar modules”,
pv magazine, 27 February 2020, https://www.pv-magazine.
com/2020/02/27/trina-unveils-two-500-w-bifacial-solar-
modules. JinkoSolar also announced its first panel specifically
for residential rooftops, a 405 W n-type panel, from “Jinko
enters the residential solar game with a bang”, pv magazine,
12 March 2020, https://pv-magazine-usa.com/2020/03/12/
jinko-enters-the-residential-solar-game-with-a-bang.
288 SolarPower Europe, Global Market Outlook for Solar Power 2020-
2024, op. cit. note 9, p. 59; M. Hutchins, “The weekend read: Big,
and then bigger”, pv magazine, 12 December 2020, https://www.
pv-magazine.com/2020/12/12/the-weekend-read-big-and-then-
bigger; E. Bellini, “Jinko launches PV module with record output
of 580 W”, pv magazine, 18 May 2020, https://pv-magazine-usa.
com/2020/05/18/jinko-launches-pv-module-with-record-output-
of-580-w. It also means one more decision for project developers,
from Hutchins, op. cit. this note.
289 L. Botti, “How to make the most of the bifacial solar module
opportunity”, Renewable Energy World, 10 March 2021, https://
www.renewableenergyworld.com/blog/how-to-make-the-most-
of-the-bifacial-solar-module-opportunity; gains in output also
from SolarPower Europe, Global Market Outlook for Solar Power
2020-2024, op. cit. note 9, p. 58; J. Crescenti, “Discussing bifacial
project economics”, pv magazine, 19 February 2020, https://
www.pv-magazine.com/2020/02/19/discussing-bifacial-project-
economics; potential for lower LCOE from P. Mints, SVP Market
Research, Photovoltaic Manufacturer Shipments: Capacity, Price &
Revenues 2019/2020 (San Francisco: April 2020), p. 57.
290 SolarPower Europe, Global Market Outlook for Solar Power
2020-2024, op. cit. note 9, p. 58. Another source put the increase
in energy yield from single-axis tracker bifacial systems as much
as 35%, while also reducing the levelised cost of energy by 16%
compared with conventional monofacial systems, from SERIS,
cited in “Global PV costs fall 13% in 2019; Bifacial offers higher
returns at over 93% of sites”, Reuters Events, 10 June 2020,
https://newenergyupdate.com/pv-insider/global-pv-costs-fall-
13-2019-bifacial-offers-higher-returns-over-93-sites; an NREL
study in 2019 revealed production gains of up to 9%, from NREL,
“Bifacial solar advances with the times—and the sun”, viewed 13
April 2021, https://www.nrel.gov/news/features/2020/bifacial-
solar-advances-with-the-times-and-the-sun.html. A SolarPro
study found bifacial yield increases of up to 11% for fixed-tilt
systems and 27% for tracker systems compared with similarly
rated traditional panels, from Botti, op. cit. note 289.
291 SolarPower Europe, Global Market Outlook for Solar Power
2020-2024, op. cit. note 9, p. 58. For some large projects using
bifacial, see “Bifacial PV developer doubles gains using simple
ground layer”, Reuters Events, 5 May 2021, https://analysis.
newenergyupdate.com/pv-insider/bifacial-pv-developer-doubles-
gains-using-simple-ground-layer; “Giant bifacial PV plants act as
springboard for growth”, Reuters Events, 10 June 2020, https://
newenergyupdate.com/pv-insider/giant-bifacial-pv-plants-act-
springboard-growth. Bifacial modules have increased equipment
and installation costs, from N. Lusson, “Bifacial modules: The
challenges and advantages”, pv magazine, 19 August 2020, https://
www.pv-magazine.com/2020/08/19/bifacial-modules-the-
challenges-and-advantages; and they require inverters that can
respond to higher rates of current, from Botti, op. cit. note 289.
292 IEA, “Renewable electricity”, op. cit. note 1; Schmela, op. cit. note
1, 26 May 2021.
293 Masson, op. cit. note 1, 9 March 2021. For example, solar PV’s
share of global polysilicon demand increased from 26% in 2000
to 84% in 2010, from IEA, “Share of PV in polysilicon demand (left)
and polysilicon price (right), 1975-2010”, 1 July 2020, https://www.
iea.org/data-and-statistics/charts/share-of-pv-in-polysilicon-
demand-left-and-polysilicon-price-right-1975-2010. Demand for
polysilicon used in solar PV production has only risen since 2010.
294 Minerals and metals from K. Hund et al., Minerals for Climate
Action: The Mineral Intensity of the Clean Energy Transition
(Washington, DC: World Bank, 2020), pp. 40-41, http://pubdocs.
worldbank.org/en/961711588875536384/Minerals-for-Climate-
Action-The-Mineral-Intensity-of-the-Clean-Energy-Transition .
295 More than doubled based on 1,546 tonnes used for solar PV
production in 2010, from The Silver Institute, World Silver Survey
2011 (Washington, DC: 2011), p. 62, https://www.silverinstitute.
org/wp-content/uploads/2017/10/2011WorldSilverSurvey.
pdf, and on 3,142 tons of silver used in 2020, from The Silver
Institute, World Silver Survey 2021 (Washington, DC: 2021), p. 48,
https://www.silverinstitute.org/wp-content/uploads/2021/04/
World-Silver-Survey-2021 . Solar PV share of global silver
demand based on above and on total global consumption of
27,333 tons in 2010, from The Silver Institute, World Silver Survey
2011, op. cit. this note, p. 10, and global consumption of 27,872
tons in 2020, from The Silver Institute, World Silver Survey
2021, op. cit. this note, p. 9. Figure of 80% from idem, p. 48. As
of 2019, researchers found a close correlation between rising
production of solar panels and an increase on the world price
of silver, from University of Kent, “Solar panel demand causing
spike in worldwide silver prices”, Science Daily, 17 April 2019,
https://www.sciencedaily.com/releases/2019/04/190417102750.
htm. For more on silver demand and solar PV, see E. Bellini,
“Silver prices expected to rise by 11% this year”, pv magazine,
12 February 2021, https://www.pv-magazine.com/2021/02/12/
silver-prices-expected-to-rise-by-11-this-year.
296 A solar PV system’s useful lifetime is 25 to 40 years, from NREL,
“Energy Analysis – Useful life”, https://www.nrel.gov/analysis/
tech-footprint.html, viewed 16 March 2021. Note that module
manufacturers generally offer warranties of 25-30 years, from
“Solar operators shun low-cost risks to extend lifespans”, Reuters
Events, 24 June 2020, https://newenergyupdate.com/pv-insider/
solar-operators-shun-low-cost-risks-extend-lifespans, and from
J. Gerdes, “US solar plants now expected to run for more than 30
years: Berkeley Lab”, Greentech Media, 29 June 2020, https://
www.greentechmedia.com/articles/read/solar-plants-expected-
to-operate-30-years. Many solar plant operators count on
lifespans over 35 years thanks to improvements in manufacturing
processes; this longer assumed lifetime also helps in terms of
assumptions about the LCOE of projects, from “Solar operators
shun low-cost risks to extend lifespans”, op. cit. this note; Gerdes,
op. cit. this note.
320
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297 Large volume of decommissioned panels from, for example, Md.
S. Chowdhury et al., “An overview of solar photovoltaic panels’
end-of-life material recycling”, Energy Strategy Reviews, vol. 27
(January 2020), https://www.sciencedirect.com/science/article/
pii/S2211467X19301245. US repowering, from E. Wesoff and B.
Beetz, “Solar panel recycling in the US — a looming issue that
could harm industry growth and reputation”, pv magazine, 3
December 2020, https://pv-magazine-usa.com/2020/12/03/
solar-panel-recycling-in-the-us-a-looming-issue-that-could-
harm-growth-and-reputation. NREL estimates a cumulative 80
million tonnes by 2050, from G.A. Heath et al., “Research and
development priorities for silicon photovoltaic module recycling to
support a circular economy”, Nature Energy, vol. 5 (July 2020), p.
502, https://www.nature.com/articles/s41560-020-0645-2.epdf.
298 A. M. Schmid, “Think before trashing: The second-hand solar
market is booming”, Solar Power World, 11 January 2021, https://
www.solarpowerworldonline.com/2021/01/think-before-trashing-
the-second-hand-solar-market-is-booming; Saur News Bureau,
“Recycling, the coming challenge for solar panels”, Saur Energy
International, 1 September 2020, https://www.saurenergy.com/solar-
energy-news/recycling-the-coming-challenge-for-solar-panels. See
also “Longer solar lifespans test analytics, repowering gains”, Reuters
Events, 9 July 2020, https://www.reutersevents.com/renewables/
pv-insider/longer-solar-lifespans-test-analytics-repowering-gains.
299 Second-hand panels from Schmid, op. cit. note 298. Major
markets include Afghanistan, Djibouti, Ethiopia and Somalia, from
idem. See also J. Deign, “Landfilling old solar panels likely safe
for humans, new research suggests”, Greentech Media, 2 April
2020, https://www.greentechmedia.com/articles/read/solar-
panel-landfill-deemed-safe-as-recycling-options-grow. Most
panels from the following: in the United States, for example, an
estimated 90% of decommissioned panels were going to landfill
as of 2018, from Recycle PV Solar, cited in idem, and nearly all
were going to landfill as of end-2020, from Wesoff and Beetz, op.
cit. note 297. Recycling facilities from S. K. Johnson, “Solar panel
recycling has a long way to go, and silicon may be the key”, Ars
Technica, 15 July 2020, https://arstechnica.com/science/2020/07/
solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-
be-the-key; Deign, op. cit. this note. Standard recycling facilities,
which can extract the glass and aluminum, for example, do not
recover valuable or environmentally harmful components, from
Heath et al., op. cit. note 297. Regarding damaged or faulty, in
Sub-Saharan Africa panels are frequently damaged during transit
and installation or by extreme weather and mishandling; also,
some panels becoming obsolete because of pace of technology
advancement, from Greencape, “Solar Panel Waste Workshop
at the Century City Conference Centre”, Cape Town, 5 March
2019, https://www.greencape.co.za/assets/Solar-Panel-Waste-
Workshop-Report-5Mar2020 .
300 PV CYCLE (Belgium) estimates that 94.7% of a solar panel is
recyclable, from Saur News Bureau, op. cit. note 298; do not
cover the costs from Wesoff and Beetz, op. cit. note 297; M.
Stone, “Solar panels are starting to die. What will we do with the
megatons of toxic trash?” Grist, 13 August 2020, https://grist.org/
energy/solar-panels-are-starting-to-die-what-will-we-do-with-
the-megatons-of-toxic-trash.
301 J. Clyncke, PV CYCLE aisbl, Brussels, personal communication
with REN21, 30 April and 3 May 2021. Note that markets for
recycled materials (e.g., silver, glass, silicon) operate on the scale
of tonnes for activities and pricing, which requires a large volume
of solar panels, from idem.
302 Ibid.
303 Only Europe from G. Cañadas, “The state of PV recycling: building
a solar circular economy”, Rated Power, 15 March 2021, https://
ratedpower.com/blog/pv-recycling; only the EU and Washington
State have laws that mandate panel recycling, from Johnson, op.
cit. note 299; New York state as of 2020 from D. Mulvaney and M.
D. Bazilian, “The downside of solar energy”, Scientific American,
1 December 2019, https://blogs.scientificamerican.com/
observations/the-downside-of-solar-energy. In the EU, under the
WEEE (Waste Electrical and Electronic Equipment) directive of
2012, installers are accountable for electronic waste (including
solar panels and inverters) and producers must recycle; in Japan,
project developers and owners are responsible for their own
panel disposal and must pay into a decommissioning fund; and
Washington state has a stewardship and takeback programme
requiring every panel supplier to provide a plan for recycling by
2022, all from Wesoff and Beetz, op. cit. note 297.
304 Operators of all solar power generation facilities in Japan with an
output of 10 kW or more installed under the FIT system, including
existing facilities, will be required to set aside the equivalent of 5%
of the total cost of the facilities as disposal costs to an external
institution for 10 years after 2022, from Matsubara, op. cit. note 53.
In Australia, Victoria, South Australia and the Australian Capital
Territory had bans on electronic waste going to landfill, from J.
Milbank, “Recycling solar”, Renew, 19 November 2019, https://
renew.org.au/renew-magazine/sustainable-tech/recycling-solar;
Queensland also had an e-waste ban that includes solar PV
panels, from Gunaratna, op. cit. note 149, 12 April 2021; in South
Africa, electronic waste is banned from landfills as of August
2021 as part of a drive to develop alternatives, from Greencape,
op. cit. note 299. Other countries – including India, Japan and
the Republic of Korea – were developing requirements as of
mid-2020, from Heath et al., op. cit. note 297. For India, see also
U. Gupta, “Managing solar PV waste in India”, pv magazine,
1 April 2021, https://www.pv-magazine.com/2021/04/01/
managing-solar-pv-waste-in-india. For Washington state, see
also SEIA, “Washington State passes bill that will improve
solar recycling program”, 10 March 2020, https://www.seia.
org/news/washington-state-passes-bill-will-improve-solar-
recycling-program. In the United States, California, New York
and Washington have programmes to incentivise and regulate
recycling, from A. Hobson, American Council of Renewable
Energy, cited in Deign, op. cit. note 299; New Jersey and North
Carolina passed laws in 2020 that require the study of end-of-
life options, California has universal waste regulations, Hawaii
had legislation pending in mid-2020 that would require a study
of issues related to module recycling, and Rhode Island had
legislation pending that would ensure reuse or recycling, all
from NREL, “What it takes to realize a circular economy for solar
photovoltaic system materials”, 2 April 2021, https://www.nrel.
gov/news/program/2021/what-it-takes-to-realize-a-circular-
economy-for-solar-photovoltaic-system-materials.html.
305 Clyncke, op. cit. note 301. The treatment line is the result of an R&D
project called PV MOREDE (2013-2016), which aims to deliver a
Mobile Recycling Device. The line has an initial capacity of 1,800
tonnes per year, with an option to increase to 4,000 tonnes per
year, and with a reported recovery rate of 95%, from idem. As of
August 2020, the Veolia (France) facility was reportedly the only
commercial-scale recycling facility for silicon panels; it launched
solar PV recycling operations in 2018 and recovers 95% of materials,
from Veolia, “Veolia opens the first European plant entirely dedicated
to recycling photovoltaic panels”, 5 July 2018, https://www.veolia.
com/en/newsroom/news/recycling-photovoltaic-panels-circular-
economy-france, viewed 18 March 2021; Waste360, “Veolia
opens solar recycling plant in France”, 26 June 2018, https://www.
waste360.com/solar/veolia-opens-solar-recycling-plant-france.
See also S. K. Johnson, “Solar panel recycling has a long way to
go, and silicon may be the key”, Ars Technica, 15 July 2020, https://
arstechnica.com/science/2020/07/solar-panel-recycling-has-a-
long-way-to-go-and-silicon-may-be-the-key; T. Sylvia, “NREL looks
to tackle PV waste before it’s too late”, pv magazine, 20 July 2020,
https://pv-magazine-usa.com/2020/07/20/nrel-looks-to-tackle-
pv-waste-before-its-too-late. The number of facilities in Europe is
limited, as is public information about economics and efficacy of
recycling, from idem; Heath et al., op. cit. note 297.
306 Clyncke, op. cit. note 301.
307 Japan from Heath et al., op. cit. note 297, and from Clyncke, op. cit.
note 301. Several organisations in Japan accept solar PV modules,
but only one specialises in recycling modules and the process
is limited, from idem. India from U. Gupta, “Establishing a solar
module recycling system in India”, pv magazine, 31 December
2020, https://www.pv-magazine.com/2020/12/31/establishing-
a-solar-module-recycling-system-in-india. United States from
Sylvia, op. cit. note 305. The SEIA is leading an industry-wide
recycling initiative with five partners; by end-2020 there were
12 recycling locations across the country and three more were
pending, from Wesoff and Beetz, op. cit. note 297. First Solar has
long had a recycling programme that recovers up to 90% of its
modules, from Deign, op. cit. note 299; First Solar, “First Solar
recycling recovers up to 90% of materials”, viewed 12 April 2021,
https://www.firstsolar.com/en/Modules/Recycling.
308 Reclaim PV from N. Filatoff, “Australia’s first large-scale PV
recycling operation amps up ‘waste’ collection”, pv magazine,
8 February 2021, https://www.pv-magazine.com/2021/02/08/
australias-first-large-scale-pv-recycling-operation-amps-up-
waste-collection; other companies in Australia – including Solar
321
https://www.sciencedirect.com/science/article/pii/S2211467X19301245
https://www.sciencedirect.com/science/article/pii/S2211467X19301245
https://pv-magazine-usa.com/2020/12/03/solar-panel-recycling-in-the-us-a-looming-issue-that-could-harm-growth-and-reputation
https://pv-magazine-usa.com/2020/12/03/solar-panel-recycling-in-the-us-a-looming-issue-that-could-harm-growth-and-reputation
https://pv-magazine-usa.com/2020/12/03/solar-panel-recycling-in-the-us-a-looming-issue-that-could-harm-growth-and-reputation
https://www.nature.com/articles/s41560-020-0645-2.epdf
https://www.solarpowerworldonline.com/2021/01/think-before-trashing-the-second-hand-solar-market-is-booming
https://www.solarpowerworldonline.com/2021/01/think-before-trashing-the-second-hand-solar-market-is-booming
https://www.solarpowerworldonline.com/2021/01/think-before-trashing-the-second-hand-solar-market-is-booming
https://www.saurenergy.com/solar-energy-news/recycling-the-coming-challenge-for-solar-panels
https://www.saurenergy.com/solar-energy-news/recycling-the-coming-challenge-for-solar-panels
https://www.reutersevents.com/renewables/pv-insider/longer-solar-lifespans-test-analytics-repowering-gains
https://www.reutersevents.com/renewables/pv-insider/longer-solar-lifespans-test-analytics-repowering-gains
https://www.greentechmedia.com/articles/read/solar-panel-landfill-deemed-safe-as-recycling-options-grow
https://www.greentechmedia.com/articles/read/solar-panel-landfill-deemed-safe-as-recycling-options-grow
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://www.greencape.co.za/assets/Solar-Panel-Waste-Workshop-Report-5Mar2020
https://www.greencape.co.za/assets/Solar-Panel-Waste-Workshop-Report-5Mar2020
https://grist.org/energy/solar-panels-are-starting-to-die-what-will-we-do-with-the-megatons-of-toxic-trash
https://grist.org/energy/solar-panels-are-starting-to-die-what-will-we-do-with-the-megatons-of-toxic-trash
https://grist.org/energy/solar-panels-are-starting-to-die-what-will-we-do-with-the-megatons-of-toxic-trash
https://ratedpower.com/blog/pv-recycling
https://ratedpower.com/blog/pv-recycling
https://blogs.scientificamerican.com/observations/the-downside-of-solar-energy
https://blogs.scientificamerican.com/observations/the-downside-of-solar-energy
https://renew.org.au/renew-magazine/sustainable-tech/recycling-solar
https://renew.org.au/renew-magazine/sustainable-tech/recycling-solar
https://www.pv-magazine.com/2021/04/01/managing-solar-pv-waste-in-india
https://www.pv-magazine.com/2021/04/01/managing-solar-pv-waste-in-india
https://www.seia.org/news/washington-state-passes-bill-will-improve-solar-recycling-program
https://www.seia.org/news/washington-state-passes-bill-will-improve-solar-recycling-program
https://www.seia.org/news/washington-state-passes-bill-will-improve-solar-recycling-program
https://www.nrel.gov/news/program/2021/what-it-takes-to-realize-a-circular-economy-for-solar-photovoltaic-system-materials.html
https://www.nrel.gov/news/program/2021/what-it-takes-to-realize-a-circular-economy-for-solar-photovoltaic-system-materials.html
https://www.nrel.gov/news/program/2021/what-it-takes-to-realize-a-circular-economy-for-solar-photovoltaic-system-materials.html
https://www.veolia.com/en/newsroom/news/recycling-photovoltaic-panels-circular-economy-france
https://www.veolia.com/en/newsroom/news/recycling-photovoltaic-panels-circular-economy-france
https://www.veolia.com/en/newsroom/news/recycling-photovoltaic-panels-circular-economy-france
https://www.waste360.com/solar/veolia-opens-solar-recycling-plant-france
https://www.waste360.com/solar/veolia-opens-solar-recycling-plant-france
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://arstechnica.com/science/2020/07/solar-panel-recycling-has-a-long-way-to-go-and-silicon-may-be-the-key
https://pv-magazine-usa.com/2020/07/20/nrel-looks-to-tackle-pv-waste-before-its-too-late
https://pv-magazine-usa.com/2020/07/20/nrel-looks-to-tackle-pv-waste-before-its-too-late
https://www.pv-magazine.com/2020/12/31/establishing-a-solar-module-recycling-system-in-india
https://www.pv-magazine.com/2020/12/31/establishing-a-solar-module-recycling-system-in-india
https://www.firstsolar.com/en/Modules/Recycling
https://www.pv-magazine.com/2021/02/08/australias-first-large-scale-pv-recycling-operation-amps-up-waste-collection
https://www.pv-magazine.com/2021/02/08/australias-first-large-scale-pv-recycling-operation-amps-up-waste-collection
https://www.pv-magazine.com/2021/02/08/australias-first-large-scale-pv-recycling-operation-amps-up-waste-collection
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR PV
Recovery Corporation, PV Industries and Lotus Energy – are
working on recycling and product stewardship, from Gunaratna,
op. cit. note 149, 12 April 2021.
309 Saur News Bureau, op. cit. note 298.
310 E. Bellini, “South Korea introduces carbon footprint rules for solar
modules”, pv magazine, 29 May 2020, https://www.pv-magazine.
com/2020/05/29/south-korea-introduces-carbon-footprint-rules-
for-solar-modules; E. Bellini, “Playing by the carbon footprint
rules”, pv magazine, 2 April 2019, https://www.pv-magazine.com/
magazine-archive/playing-by-the-carbon-footprint-rules.
311 K. Pickerel, “Influential solar panel players launch alliance to
promote their low-carbon products”, Solar Power World, 8
October 2020, https://www.solarpowerworldonline.com/2020/10/
influential-solar-panel-players-launch-alliance-to-promote-their-
low-carbon-products; Ultra Low-Carbon Solar Alliance, “Not
all solar panels are created equal”, https://ultralowcarbonsolar.
org, viewed 26 April 2021. One of its members, First Solar,
committed in 2020 to transition its US facilities to carbon-free
electricity by 2026 and to power global manufacturing operations
with renewable energy by 2028, from First Solar, “First Solar
commits to powering 100% of global operations with renewable
energy by 2028”, press release (Tempe: 6 August 2020), https://
investor.firstsolar.com/news/press-release-details/2020/First-
Solar-Commits-to-Powering-100-of-Global-Operations-with-
Renewable-Energy-by-2028/default.aspx.
322
https://www.pv-magazine.com/2020/05/29/south-korea-introduces-carbon-footprint-rules-for-solar-modules
https://www.pv-magazine.com/2020/05/29/south-korea-introduces-carbon-footprint-rules-for-solar-modules
https://www.pv-magazine.com/2020/05/29/south-korea-introduces-carbon-footprint-rules-for-solar-modules
https://www.pv-magazine.com/magazine-archive/playing-by-the-carbon-footprint-rules
https://www.pv-magazine.com/magazine-archive/playing-by-the-carbon-footprint-rules
https://www.solarpowerworldonline.com/2020/10/influential-solar-panel-players-launch-alliance-to-promote-their-low-carbon-products
https://www.solarpowerworldonline.com/2020/10/influential-solar-panel-players-launch-alliance-to-promote-their-low-carbon-products
https://www.solarpowerworldonline.com/2020/10/influential-solar-panel-players-launch-alliance-to-promote-their-low-carbon-products
https://ultralowcarbonsolar.org
https://ultralowcarbonsolar.org
https://investor.firstsolar.com/news/press-release-details/2020/First-Solar-Commits-to-Powering-100-of-Global-Operations-with-Renewable-Energy-by-2028/default.aspx
https://investor.firstsolar.com/news/press-release-details/2020/First-Solar-Commits-to-Powering-100-of-Global-Operations-with-Renewable-Energy-by-2028/default.aspx
https://investor.firstsolar.com/news/press-release-details/2020/First-Solar-Commits-to-Powering-100-of-Global-Operations-with-Renewable-Energy-by-2028/default.aspx
https://investor.firstsolar.com/news/press-release-details/2020/First-Solar-Commits-to-Powering-100-of-Global-Operations-with-Renewable-Energy-by-2028/default.aspx
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · CONCENTRATING SOL AR THERMAL POWER
CONCENTRATING SOL AR THERMAL POWER (CSP)
1 Data are compiled from the following sources: US National
Renewable Energy Laboratory (NREL), “Concentrating solar
power projects”, https://solarpaces.nrel.gov, with the page and
its subpages viewed on numerous dates leading up to 13 April
2021 (some subpages are referenced individually throughout this
section) and references cited in the CSP section of Renewable
Energy Policy Network for the 21st Century (REN21), Renewables
2020 Global Status Report (Paris: 2020), pp. 120-123, https://www.
ren21.net/reports/global-status-report. In some cases, information
from the above sources was verified against additional country-
specific sources, as cited in the rest of the endnotes for this
section. Global CSP data are based on commercial facilities only;
demonstration and pilot facilities as well as facilities of 5 MW or
less are excluded from capacity data, with the exception of certain
plants in China that are described as “demonstration” plants by
government but are nonetheless large- (utility-) scale, grid-
connected plants that are operating or will operate commercially.
Data discrepancies between REN21 and other reference sources
are due primarily to differences in categorisation and thresholds for
inclusion of specific CSP facilities in overall global totals.
2 Ibid. Figure 29 from idem.
3 J. Fialka, “Futuristic solar plants plagued by glitches, poor
training”, Scientific American, 17 June 2020, https://www.
scientificamerican.com/article/futuristic-solar-plants-plagued-
by-glitches-poor-training; J. Lilliestam et al., “The near- to
mid-term outlook for concentrating solar power: Mostly cloudy,
chance of sun”, Energy Sources, Part B: Economics, Planning, and
Policy, vol. 16, no. 1 (2021), pp. 23-41, https://www.tandfonline.
com/doi/full/10.1080/15567249.2020.1773580.
4 See sources in endnote 1.
5 Ibid.
6 Ibid.
7 Ibid.
8 Ibid.
9 Ibid.
10 NREL, “Concentrating Solar Power Projects: Urat Royal Tech
100 MW”, https://solarpaces.nrel.gov/urat-royal-tech-100mw-
thermal-oil-parabolic-trough-project, updated 22 January 2020.
11 Ibid.
12 HelioCSP, “Three concentrated sola power projects of 335 MW
rescued in China”, 10 March 2020, http://helioscsp.com/three-
concentrated-solar-power-projects-of-335-mw-rescued-in-china;
China Solar Thermal Alliance, “Updated progress of Chinese 20
CSP demonstration projects”, 3 April 2020, http://en.cnste.org/
html/csp/2017/0727/282.html.
13 See sources in endnote 1.
14 P. Lague, “Dubai commissions world’s tallest solar
power tower”, ESI Africa, 15 June 2020, https://www.
esi-africa.com/industry-sectors/renewable-energy/
dubai-commissions-worlds-tallest-solar-power-tower.
15 NREL, “Concentrating Solar Power Projects in United Arab
Emirates”, https://solarpaces.nrel.gov/by-country/AE, page and
its sub-pages viewed on various dates up to 31 March 2021.
16 NREL, “Concentrating Solar Power Projects: ISCC Duba 1“,
https://solarpaces.nrel.gov/iscc-duba-1, updated 31 January 2017.
17 See sources in endnote 1.
18 Ibid.
19 Ibid.
20 S. Djunisic, “Chile’s Cerro Dominador CSP project lands new
PPA”, Renewables Now, 26 August 2020, https://renewablesnow.
com/news/chiles-cerro-dominador-csp-project-lands-new-
ppa-711312; reve, “The Cerro Dominador concentrated solar
power plant, the first in Chile and Latin America, installs its solar
receiver”, 25 May 2020, https://www.evwind.es/2020/05/25/
the-cerro-dominador-concentrated-solar-power-plant-the-first-
in-chile-and-latin-america-installs-its-solar-receiver-at-a-height-
of-220-meters/74854; S. Djunisic, “Chile’s Cerro Dominador
CSP project completes salt melting process”, Renewables Now,
16 April 2020, https://renewablesnow.com/news/chiles-cerro-
dominador-csp-project-completes-salt-melting-process-695284.
21 J. M. Takouleu, “ZAMBIA: Sinohydro to carry out
work on Kalulushi CSP solar power plant”, Afrik21,
16 July 2020, https://www.afrik21.africa/en/
zambia-sinohydro-to-carry-out-work-on-kalulushi-csp-solar-
power-plant.
22 “Botswana to build 200MW of CSP; Cubico buys 100 MW of
CSP in Spain”, Reuters Events, 13 January 2021, https://www.
reutersevents.com/renewables/solar-thermal/botswana-build-
200-mw-csp-cubico-buys-100-mw-csp-spain.
23 See sources in endnote 1.
24 Ibid.
25 CSP Focus, “The good solar thermal numbers in 2019 reinforce
the importance of this technology”, 2 March 2020, http://www.
cspfocus.cn/en/market/detail_2702.htm; Agencia Estatal Boletin
Oficial del Estado, “Orden TED/1161/2020, de 4 de diciembre,
por la que se regula el primer mecanismo de subasta para el
otorgamiento del régimen económico de energías renovables
y se establece el calendario indicativo para el periodo 2020-
2025”, 5 December 2020, https://www.boe.es/diario_boe/txt.
php?id=BOE-A-2020-15689; C. Farand, “Spain unveils climate
law to cut emissions to net zero by 2050”, Climate Home News,
18 May 2020, https://www.climatechangenews.com/2020/05/18/
spain-unveils-climate-law-cut-emissions-net-zero-2050.
26 K. Chamberlain, “Abengoa to install first retrofit
CSP storage pilot”, Reuters, 10 June 2020, https://
www.reutersevents.com/renewables/solar-thermal/
abengoa-install-first-retrofit-csp-storage-pilot.
27 See sources in endnote 1.
28 Ibid. Figure 30 from idem.
29 NREL, “Concentrating Solar Power Projects: Ashalim Plot B
(Megalim)”, https://solarpaces.nrel.gov/ashalim-plot-b, updated
12 April 2019.
30 See sources in endnote 1. See also Systems Integration chapter
in this report.
31 See sources in endnote 1.
32 Ibid.
33 Ibid.
34 Ibid.
35 Ibid.
36 Ibid.
37 International Renewable Energy Agency (IRENA), Renewable
Power Generation Costs in 2020 (Abu Dhabi, 2021).
38 Ibid.
39 Cerro Dominador Concentrated Solar Power, “Projects”, https://
cerrodominador.com/en/projects, viewed 12 March 2021.
40 S. Kraemer, “Morocco pioneers PV with thermal storage at
800MW Midelt CSP project”, SolarPACES, 25 April 2020, https://
www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-
at-800-mw-midelt-csp-project.
41 M. Rycroft, "CSP-PV hybrid power systems: An attractive
future option", EE Publishers, 27 May 2019, https://www.
ee.co.za/article/csp-pv-hybrid-power-systems-an-attractive-
future-option.html; “Hybrid CSP-PV offers lowest cost for
Chile; US DOE reopens loan program”, Reuters, 11 March 2021,
https://www.reutersevents.com/renewables/solar-thermal/
hybrid-csp-pv-offers-lowest-cost-chile-us-doe-reopens-loan-
program; B. Bedeshci, "Hybrid concentrated solar power - PV
gains", Heliocsp, 15 August 2018, https://helioscsp.com/
hybrid-concentrated-solar-power-pv-gains.
42 K. Chamberlain, “Abengoa to install first retrofit
CSP storage pilot”, Reuters, 10 June 2020, https://
www.reutersevents.com/renewables/solar-thermal/
abengoa-install-first-retrofit-csp-storage-pilot.
43 European Commission (EC), “Competitive solar power towers
– CAPTure”, https://cordis.europa.eu/project/id/640905,
updated 27 August 2020; European Commission, “Modular
high concentration Solar Configuration”, updated 19 August
2020, https://cordis.europa.eu/project/id/727402; EC, “High
temperature concentrated solar thermal power plan with particle
receiver and direct thermal storage”, https://cordis.europa.eu/
project/id/727762, updated 1 September 2020.
44 Energy.gov, “Energy Department announces $130 million in solar
technology projects”, 12 November 2020, https://www.energy.
gov/articles/energy-department-announces-130-million-solar-
technology-projects; Energy.gov, “Concentrating solar power”,
https://www.energy.gov/sco2-power-cycles-renewable-energy-
applications/concentrating-solar-power, viewed 12 March 2020.
323
https://solarpaces.nrel.gov
https://www.ren21.net/reports/global-status-report
https://www.ren21.net/reports/global-status-report
https://www.scientificamerican.com/article/futuristic-solar-plants-plagued-by-glitches-poor-training
https://www.scientificamerican.com/article/futuristic-solar-plants-plagued-by-glitches-poor-training
https://www.scientificamerican.com/article/futuristic-solar-plants-plagued-by-glitches-poor-training
https://www.tandfonline.com/doi/full/10.1080/15567249.2020.1773580
https://www.tandfonline.com/doi/full/10.1080/15567249.2020.1773580
https://solarpaces.nrel.gov/urat-royal-tech-100mw-thermal-oil-parabolic-trough-project
https://solarpaces.nrel.gov/urat-royal-tech-100mw-thermal-oil-parabolic-trough-project
http://helioscsp.com/three-concentrated-solar-power-projects-of-335-mw-rescued-in-china
http://helioscsp.com/three-concentrated-solar-power-projects-of-335-mw-rescued-in-china
http://en.cnste.org/html/csp/2017/0727/282.html
http://en.cnste.org/html/csp/2017/0727/282.html
https://www.esi-africa.com/industry-sectors/renewable-energy/dubai-commissions-worlds-tallest-solar-power-tower
https://www.esi-africa.com/industry-sectors/renewable-energy/dubai-commissions-worlds-tallest-solar-power-tower
https://www.esi-africa.com/industry-sectors/renewable-energy/dubai-commissions-worlds-tallest-solar-power-tower
https://solarpaces.nrel.gov/by-country/AE
https://solarpaces.nrel.gov/iscc-duba-1
https://renewablesnow.com/news/chiles-cerro-dominador-csp-project-lands-new-ppa-711312
https://renewablesnow.com/news/chiles-cerro-dominador-csp-project-lands-new-ppa-711312
https://renewablesnow.com/news/chiles-cerro-dominador-csp-project-lands-new-ppa-711312
https://www.evwind.es/2020/05/25/the-cerro-dominador-concentrated-solar-power-plant-the-first-in-chile-and-latin-america-installs-its-solar-receiver-at-a-height-of-220-meters/74854
https://www.evwind.es/2020/05/25/the-cerro-dominador-concentrated-solar-power-plant-the-first-in-chile-and-latin-america-installs-its-solar-receiver-at-a-height-of-220-meters/74854
https://www.evwind.es/2020/05/25/the-cerro-dominador-concentrated-solar-power-plant-the-first-in-chile-and-latin-america-installs-its-solar-receiver-at-a-height-of-220-meters/74854
https://www.evwind.es/2020/05/25/the-cerro-dominador-concentrated-solar-power-plant-the-first-in-chile-and-latin-america-installs-its-solar-receiver-at-a-height-of-220-meters/74854
https://renewablesnow.com/news/chiles-cerro-dominador-csp-project-completes-salt-melting-process-695284
https://renewablesnow.com/news/chiles-cerro-dominador-csp-project-completes-salt-melting-process-695284
https://www.afrik21.africa/en/zambia-sinohydro-to-carry-out-work-on-kalulushi-csp-solar-power-plant
https://www.afrik21.africa/en/zambia-sinohydro-to-carry-out-work-on-kalulushi-csp-solar-power-plant
https://www.afrik21.africa/en/zambia-sinohydro-to-carry-out-work-on-kalulushi-csp-solar-power-plant
https://www.reutersevents.com/renewables/solar-thermal/botswana-build-200-mw-csp-cubico-buys-100-mw-csp-spain
https://www.reutersevents.com/renewables/solar-thermal/botswana-build-200-mw-csp-cubico-buys-100-mw-csp-spain
https://www.reutersevents.com/renewables/solar-thermal/botswana-build-200-mw-csp-cubico-buys-100-mw-csp-spain
http://www.cspfocus.cn/en/market/detail_2702.htm
http://www.cspfocus.cn/en/market/detail_2702.htm
https://www.boe.es/diario_boe/txt.php?id=BOE-A-2020-15689
https://www.boe.es/diario_boe/txt.php?id=BOE-A-2020-15689
https://www.climatechangenews.com/2020/05/18/spain-unveils-climate-law-cut-emissions-net-zero-2050
https://www.climatechangenews.com/2020/05/18/spain-unveils-climate-law-cut-emissions-net-zero-2050
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://solarpaces.nrel.gov/ashalim-plot-b
https://cerrodominador.com/en/projects
https://cerrodominador.com/en/projects
https://www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project
https://www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project
https://www.solarpaces.org/morocco-pioneers-pv-to-thermal-storage-at-800-mw-midelt-csp-project
https://www.ee.co.za/article/csp-pv-hybrid-power-systems-an-attractive-future-option.html
https://www.ee.co.za/article/csp-pv-hybrid-power-systems-an-attractive-future-option.html
https://www.ee.co.za/article/csp-pv-hybrid-power-systems-an-attractive-future-option.html
https://www.reutersevents.com/renewables/solar-thermal/hybrid-csp-pv-offers-lowest-cost-chile-us-doe-reopens-loan-program
https://www.reutersevents.com/renewables/solar-thermal/hybrid-csp-pv-offers-lowest-cost-chile-us-doe-reopens-loan-program
https://www.reutersevents.com/renewables/solar-thermal/hybrid-csp-pv-offers-lowest-cost-chile-us-doe-reopens-loan-program
https://helioscsp.com/hybrid-concentrated-solar-power-pv-gains
https://helioscsp.com/hybrid-concentrated-solar-power-pv-gains
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://www.reutersevents.com/renewables/solar-thermal/abengoa-install-first-retrofit-csp-storage-pilot
https://cordis.europa.eu/project/id/640905
https://cordis.europa.eu/project/id/727402
https://cordis.europa.eu/project/id/727762
https://cordis.europa.eu/project/id/727762
http://Energy.gov
https://www.energy.gov/articles/energy-department-announces-130-million-solar-technology-projects
https://www.energy.gov/articles/energy-department-announces-130-million-solar-technology-projects
https://www.energy.gov/articles/energy-department-announces-130-million-solar-technology-projects
http://Energy.gov
https://www.energy.gov/sco2-power-cycles-renewable-energy-applications/concentrating-solar-power
https://www.energy.gov/sco2-power-cycles-renewable-energy-applications/concentrating-solar-power
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR THERMAL HE ATING
SOL AR THERMAL HEATING
1 Revised gross additions for 2019 included in this GSR (26.1 GWth)
are significantly lower than those published in GSR 2020
(31.3 GWth) for two reasons: First, the Chinese Solar Thermal
Industry Federation (CSTIF) adjusted downwards its number for
China’s new additions in 2019, from 22.75 GWth (a preliminary
figure, available as of early 2020) to 20 GWth. Second, data for
new additions in China are based on produced collector area,
rather than on annual installations in China; as a result, export
volumes have been included in China’s national statistics for 2020
and earlier years. In past editions of the GSR, this has resulted in
a double counting of some collector area because the majority
of coated vacuum tubes installed worldwide are purchased
from China. The one exception is Turkey, which imposed a high
import tax on Chinese vacuum tubes in July 2011, resulting in
high national vacuum tube production capacities that supply
most of national demand. To correct the newly added solar
thermal capacity in China, newly added vacuum tube collector
capacities in large solar thermal markets outside of China and
Turkey were subtracted from the produced collector volume in
China for 2019 and 2020. The result has been a further reduction
to the number for China’s additions during 2019 (relative to data
in GSR 2020). Because China dominated global gross additions
in 2019 and 2020, downwards adjustments to China’s additions
also had a downwards effect on the data published for annual
global sales (see endnote 5), from M. Spörk-Dür, AEE – Institute
for Sustainable Technologies (AEE INTEC), Austria, personal
communication with Renewable Energy Policy Network for the
21st Century (REN21), April 2020.
2 Increasing demand from residential customers during the pandemic
was reported for India, Brazil and Turkey, from B. Epp, solrico,
Bielefeld, Germany, personal communication with REN21, April 2021.
3 Changes to support policies increased demand significantly in
Germany and the Netherlands in 2020, whereas the expiration of
support policies in India, Poland and the United States resulted
in strong declines in solar thermal capacity additions during the
year, from Ibid.
4 Solarthermalworld.org reported on solar thermal sales activities
in at least 134 countries worldwide during 2008-2020, from Ibid.
5 Figure 31 based on the following sources: Global solar thermal
capacity is based on the latest market data from the largest 20
solar thermal markets in terms of added capacity listed in order
of their additions: China, Turkey, India, Brazil, United States,
Germany, Australia, Mexico, Israel, Greece, Spain, Poland, South
Africa, Italy, Netherlands, Cyprus, Austria, Morocco, Tunisia and
Portugal, which represented 95% of cumulative installed capacity
in operation in 2019. Added capacities in other countries for
which new additions are available until 2019 (but not yet for 2020)
were projected according to national trends over the 2018-2019
period. The rest of the world – meaning those countries without
detailed solar thermal market information in 2019 and previous
years – accounted for an estimated 5% of the global market
volume excluding China in 2019 and 2020. Until 2018, the rest of
the world was considered to be 5% of the global market including
China, which overestimated its market share, from Spörk-Dür,
op. cit. note 1; W. Weiss and M. Spörk-Dür, Solar Heat Worldwide.
Global Market Development and Trends in 2019, Detailed Market
Figures 2018 (Gleisdorf, Austria: International Energy Agency (IEA)
Solar Heating and Cooling Programme (SHC), 2020), http://www.
iea-shc.org/solar-heatworldwide.
6 Spörk-Dür, op. cit. note 1. Equivalence of 407 terawatt-hours
(TWh) and 239 million barrels of oil equivalent from Kyle’s
Converter, http://www.kylesconverter.com.
7 T. Ramschak, AEE INTEC, Austria, personal communication with
REN21, April 2021; Weiss and Spörk-Dür, op. cit. note 5.
8 Epp, op. cit. note 2. Year-end total installations of concentrating
collector technologies (linear Fresnel, parabolic trough and dish)
were reported by aperture area and converted into solar thermal
capacity using the internationally accepted convention for
stationary collectors, 1 million m2 = 0.7 GWth.
9 The total installed capacity of air collectors declined to 1 GWth at
the end of 2020 (1.1 GWth at the end of 2019) due to 0.05 GWth of
air collector technology that went out of operation in 2020 after a
lifetime of 20 years, from Spörk-Dür, op. cit. note 1.
10 Figure 32 based on the latest market data available for gross
additions of glazed and unglazed water collectors (not including
concentrating collectors), at the time of publication, for countries
that together represent 96% of the world total. Data from original
country sources include gross national additions and were provided
to REN21 as follows: D. Ferrari, Sustainability Victoria, Melbourne,
Australia; W. Weiss, AEE INTEC, Vienna, Austria; D. Johann, Brazilian
Solar Thermal Energy Association (ABRASOL), São Paulo, Brazil;
H. Cheng, Shandong SunVision Management Consulting, Dezhou,
China (5% were subtracted from the Chinese additions reported by
Cheng, because the figures included vacuum tube collectors that
were manufactured in China and exported to other countries). The
5% subtracted represents the average share of China’s produced
vacuum tube collector area that was exported to other key markets
in the years 2015 to 2019 (for countries where final new additions
were available); P. Kastanias, Cyprus Union of Solar Thermal
Industrialists (EBHEK), Nicosia, Cyprus; A. Liesen, BSW Solar, Berlin,
Germany; C. Travasaros, Greek Solar Industry Association (EBHE),
Piraeus, Greece; J. Malaviya, Solar Thermal Federation of India
(STFI), Pune, India; E. Shilton, Elsol, Kohar-yair, Israel; F. Musazzi,
ANIMA, the Federation of Italian Associations in the Mechanical and
Engineering Industries, Milan, Italy; N. Jaeger, Holland Solar, Utrecht,
Netherlands (preliminary estimation for the Netherlands, share of
flat plate and vacuum tubes were applied as in 2019 – latest data
available); T. Kousksou, University of Pau and the Pays de l’Adour,
Pau, France (for Morocco; share of vacuum tube and flat plate
collectors was not available); D. Garcia, Solar Thermal Manufacturers
Organisation (FAMERAC), Mexico City, Mexico; P. Dias, Solar Heat
Europe, Brussels, Belgium (for Portugal); J. Staroscik, Association
of Manufacturers and Importers of Heating Appliances (SPIUG),
Warsaw, Poland; K. Kritzinger, Centre for Renewable and Sustainable
Energy Studies, University of Stellenbosch, Stellenbosch, South
Africa; P. Polo, Spanish Solar Thermal Association (ASIT), Madrid,
Spain; A. Baccouche, ANME, Tunis, Tunisia; K. Ülke, Bural Heating,
Kayseri, Turkey; B. Heavner, California Solar & Storage Association
(CALSSA), Sacramento, California, United States, all personal
communications with REN21, February-April 2021.
11 Global additions from Spörk-Dür, op. cit. note 1. For country
additions, see endnote 10.
12 Epp, op. cit. note 2.
13 Global additions from Spörk-Dür, op. cit. note 1. For country
additions, see endnote 10.
14 B. Epp, “China sees strong growth in demand for solar
space heating”, Solarthermalworld.org, 9 February
2021, https://www.solarthermalworld.org/news/
demand-clean-space-heating-rebounds-germany.
15 Ibid. As per endnote 1 the new additions in 2020 and the
decline rates in 2019 and 2020 were calculated by subtracting
the exported vacuum tube collector area produced in China
as reported from CSTIF in the years 2018, 2019 and 2020. As a
preliminary correction for 2020, 5% of the produced volume in
China was subtracted for exports, as this corresponds with the
average export share for the last five years.
16 Total capacity in operation in China at the end of 2019 was
calculated with a system lifetime of 11 years, instead of the 10-year
lifetime assumed until 2018. China’s total capacity at the end of
2020 was calculated with a system lifetime of 12 years, which
increases the total in operation relative to data in previous GSRs,
from Spörk-Dür, op. cit. note 1.
17 Epp, op. cit. note 14.
18 Ibid.
19 Ibid.
20 CSTIF, Chinese Solar Thermal Industry Status Report 2020 (Beijing:
8 December 2020), https://mp.weixin.qq.com/s/3YOksFnzrMy
Umrt79HTpGg.
21 Ibid.
22 Ibid.
23 Ibid.
24 K. Ülke, Bural Heating, Kayseri, Turkey, personal communication
with REN21, March 2021.
25 Spörk-Dür, op. cit. note 1.
26 Ülke, op. cit. note 24.
27 B. Epp, “Opposing trends in India’s solar thermal
market 2020”, Solarthermalworld.org, 20 April
2021, https://www.solarthermalworld.org/news/
opposing-trends-indias-solar-thermal-market-2020.
28 Ibid.
324
http://www.iea-shc.org/solar-heatworldwide
http://www.iea-shc.org/solar-heatworldwide
http://www.kylesconverter.com
https://www.solarthermalworld.org/news/demand-clean-space-heating-rebounds-germany
https://www.solarthermalworld.org/news/demand-clean-space-heating-rebounds-germany
https://mp.weixin.qq.com/s/3YOksFnzrMyUmrt79HTpGg
https://mp.weixin.qq.com/s/3YOksFnzrMyUmrt79HTpGg
https://www.solarthermalworld.org/news/opposing-trends-indias-solar-thermal-market-2020
https://www.solarthermalworld.org/news/opposing-trends-indias-solar-thermal-market-2020
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR THERMAL HE ATING
29 Ibid.
30 J. Malaviya, STFI, Pune, India, personal communication with
REN21, April 2021.
31 Ibid.
32 Epp, op. cit. note 27.
33 D. Johann, ABRASOL, São Paulo, Brazil, personal communication
with REN21, April 2021.
34 Ibid.
35 Ibid.
36 Ibid.
37 Ibid.; B. Heavner, CALSSA, Sacramento, United States, personal
communication with REN21, April 2021; D. Ferrari, Sustainability
Victoria, Melbourne, Australia, personal communication with
REN21, March 2021.
38 Johann, op. cit. note 33.
39 Ibid.
40 Ibid.
41 Ibid.
42 Heavner, op. cit. note 37.
43 Ibid.
44 Ibid.
45 Spörk-Dür, op. cit. note 1.
46 Ferrari, op. cit. note 37.
47 Ibid.
48 Ibid.
49 Ibid.
50 P. Dias, Solar Heat Europe, Brussels, Belgium, personal
communication with REN21, March 2021.
51 Ibid.
52 Ibid.
53 Ibid.
54 B. Epp, “Demand for clean space heating rebounds
in Germany”, Solarthermalworld.org, 9 February
2021, https://www.solarthermalworld.org/news/
demand-clean-space-heating-rebounds-germany.
55 The new German support scheme also covers 45% of the
costs if a heat pump or a pellet boiler is installed instead
of an oil boiler, from B. Epp, “High scrappage bonus for oil
boilers”, Solarthermalworld.org, 3 March 2020, https://www.
solarthermalworld.org/news/high-scrappage-bonus-oil-boilers.
56 Epp, op. cit. note 54.
57 Spörk-Dür, op. cit. note 1.
58 C. Travasaros, EBHE, Piraeus, Greece, personal communication
with REN21, February 2021.
59 Ibid.
60 P. Polo, ASIT, Madrid, Spain, personal communication with REN21,
March 2021; J. Staroscik, SPIUG, Warsaw, Poland, personal
communication with REN21, March 2021.
61 Staroscik, op. cit. note 60.
62 New plant in Tibet from R. Ge, Micoe Corporation, Lianyungang,
China, personal communication with solrico, March 2021; solar
district heating in Tibet in 2019 from B. Epp, “SDH system with
parabolic troughs in Tibet”, Solarthermalworld.org, 17 December
2019, https://www.solarthermalworld.org/news/sdh-system-
parabolic-troughs-tibet; B. Epp, “Second Arcon-Sunmark SDH
system up and running in Tibet”, Solarthermalworld.org, 25
November 2019, https://www.solarthermalworld.org/news/second-
arcon-sunmark-sdh-system-and-running-tibet; B. Epp, “Saga in
Tibet tests solar heating in public buildings”, Solarthermalworld.
org, 25 March 2020, https://www.solarthermalworld.org/news/
saga-tibet-tests-solar-heating-public-buildings.
63 CSTIF, op. cit. note 20.
64 Ibid.
65 P. Geiger, Solites – Steinbeis Forschungsinstitut für solare und
zukunftsfähige thermische Energiesysteme, Stuttgart, Germany,
personal communication with REN21, March 2021.
66 J. Berner, “Large-scale solar heat is cost-competitive in
Germany”, Solarthermalworld.org, 13 December 2019,
https://www.solarthermalworld.org/news/large-scale-solar-
heat-cost-competitive-germany.
67 Geiger, op. cit. note 65.
68 Ibid.
69 “Kommunale Klimaschutz-Modellprojekte“, https://www.
klimaschutz.de/modellprojekte, viewed 7 May 2021.
70 J. Berner, “Support for 90 Heat Network 4.0 feasibility studies”,
Solarthermalworld.org, 2 October 2019, https://www.solarthermalworld.
org/news/support-90-heat-network-40-feasibility-studies.
71 Berner, op. cit. note 66.
72 B. Epp, “Danish SDH market reaches new milestone”,
Solarthermalworld.org, 1 September 2019,
https://www.solarthermalworld.org/news/
danish-sdh-market-reaches-new-milestone.
73 D. Trier, PlanEnergi, Skørping, Denmark, personal communication
with REN21 in March 2021.
74 Ibid.
75 Ibid.
76 Ibid.
77 Ibid.
78 B. Epp, “NewHeat secures EUR 13 million loan to finance 5 solar
heat plants”, Solarthermalworld.org, 14 September 2020,
https://www.solarthermalworld.org/news/newheat-secures-
eur-13-million-loan-finance-5-solar-heat-plants.
79 H. Defréville, NewHeat, Bordeaux, France, personal
communication with solrico in March 2021.
80 G. Wörther, Klima- und Energiefonds, Vienna, Austria, personal
communication with REN21, April 2021.
81 Spörk-Dür, op. cit. note 1.
82 R. Hackstock, Austria Solar, Vienna, Austria, personal
communication with REN21, April 2021.
83 B. Epp, “Construction of largest Swedish SDH plant
with parabolics”, Solarthermalworld.org, 23 December
2020, https://www.solarthermalworld.org/news/
construction-largest-swedish-sdh-plant-parabolics.
84 B. Epp, “Reducing the level of harmful air pollutants
is vital”, Solarthermalworld.org, 5 March 2021,
https://www.solarthermalworld.org/news/
reducing-level-harmful-air-pollutants-vital.
85 F. Stier, “Three SDH plants under development
in Croatia”, Solarthermalworld.org, 22 October
2020, https://www.solarthermalworld.org/news/
three-sdh-plants-under-development-croatia.
86 F. Stier, “Serbia’s first big online conference on solar energy
draws 2,000 attendees”, Solarthermalworld.org, 23 April 2021,
https://www.solarthermalworld.org/news/serbias-first-big-
online-conference-solar-energy-draws-2000-attendees.
87 Ibid.
88 Ibid.
89 Spörk-Dür, op. cit. note 1.
90 Figure 33 based on data from Spörk-Dür, op. cit. note 1, and
from W. Weiss and M. Spörk-Dür, Solar Heat Worldwide. Global
Market Development and Trends in 2020, Detailed Market Figures
2019 (Gleisdorf, Austria: IEA SHC, 2020). http://www.iea-shc.org/
solar-heat-worldwide. Year-end total installations of concentrating
collector technologies (linear Fresnel, parabolic trough and dish)
were reported by aperture area and converted into solar thermal
capacity using the internationally accepted convention for
stationary collectors, 1 million m2 = 0.7 GWth.
91 Spörk-Dür, op. cit. note 1.
92 Ibid.
93 International Renewable Energy Agency (IRENA) Coalition for
Action, Companies in Transition Towards 100% Renewables:
Focus on Heating and Cooling (Abu Dhabi: 2021).
94 B. Epp, “China keeps top spot for industrial solar heat”,
Solarthermalworld.org, 10 May 2021, https://www.solarthermalworld.
org/news/china-keeps-top-spot-industrial-solar-heat.
95 Malaviya, op. cit. note 30.
96 B. Epp, “Industrial sector sees record-breaking capacity
additions in 2019”, Solarthermalworld.org, 26 April
2020, https://www.solarthermalworld.org/news/
industrial-sector-sees-record-breaking-capacity-additions-2019.
325
https://www.solarthermalworld.org/news/demand-clean-space-heating-rebounds-germany
https://www.solarthermalworld.org/news/demand-clean-space-heating-rebounds-germany
https://www.solarthermalworld.org/news/high-scrappage-bonus-oil-boilers
https://www.solarthermalworld.org/news/high-scrappage-bonus-oil-boilers
https://www.solarthermalworld.org/news/sdh-system-parabolic-troughs-tibet
https://www.solarthermalworld.org/news/sdh-system-parabolic-troughs-tibet
https://www.solarthermalworld.org/news/second-arcon-sunmark-sdh-system-and-running-tibet
https://www.solarthermalworld.org/news/second-arcon-sunmark-sdh-system-and-running-tibet
https://www.solarthermalworld.org/news/saga-tibet-tests-solar-heating-public-buildings
https://www.solarthermalworld.org/news/saga-tibet-tests-solar-heating-public-buildings
https://www.solarthermalworld.org/news/large-scale-solar-heat-cost-competitive-germany
https://www.solarthermalworld.org/news/large-scale-solar-heat-cost-competitive-germany
https://www.klimaschutz.de/modellprojekte
https://www.klimaschutz.de/modellprojekte
https://www.solarthermalworld.org/news/support-90-heat-network-40-feasibility-studies
https://www.solarthermalworld.org/news/support-90-heat-network-40-feasibility-studies
https://www.solarthermalworld.org/news/danish-sdh-market-reaches-new-milestone
https://www.solarthermalworld.org/news/danish-sdh-market-reaches-new-milestone
https://www.solarthermalworld.org/news/newheat-secures-eur-13-million-loan-finance-5-solar-heat-plants
https://www.solarthermalworld.org/news/newheat-secures-eur-13-million-loan-finance-5-solar-heat-plants
https://www.solarthermalworld.org/news/construction-largest-swedish-sdh-plant-parabolics
https://www.solarthermalworld.org/news/construction-largest-swedish-sdh-plant-parabolics
https://www.solarthermalworld.org/news/reducing-level-harmful-air-pollutants-vital
https://www.solarthermalworld.org/news/reducing-level-harmful-air-pollutants-vital
https://www.solarthermalworld.org/news/three-sdh-plants-under-development-croatia
https://www.solarthermalworld.org/news/three-sdh-plants-under-development-croatia
https://www.solarthermalworld.org/news/serbias-first-big-online-conference-solar-energy-draws-2000-attendees
https://www.solarthermalworld.org/news/serbias-first-big-online-conference-solar-energy-draws-2000-attendees
http://www.iea-shc.org/solar-heatworldwide
http://www.iea-shc.org/solar-heatworldwide
https://www.solarthermalworld.org/news/china-keeps-top-spot-industrial-solar-heat
https://www.solarthermalworld.org/news/china-keeps-top-spot-industrial-solar-heat
https://www.solarthermalworld.org/news/industrial-sector-sees-record-breaking-capacity-additions-2019
https://www.solarthermalworld.org/news/industrial-sector-sees-record-breaking-capacity-additions-2019
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · SOL AR THERMAL HE ATING
97 Epp, op. cit. note 94.
98 Ibid.
99 Ibid.
100 M. Oropeza, solrico, Berlin, Germany, personal communication
with REN21, April 2021.
101 Epp, op. cit. note 94.
102 Ibid.
103 Ibid.
104 Ibid.
105 Ibid.
106 Ibid.
107 Ibid.
108 Ramschak, op. cit. note 7.
109 Ibid.
110 Ibid.
111 B. Epp, “Hybrid solutions maximise solar yield per area”,
Solarthermalworld.org, 29 April 2020, https://www.solarthermalworld.
org/news/hybrid-solutions-maximise-solar-yield-area.
112 Ramschak, op. cit. note 7.
113 B. Epp, “Mixed performance of world’s largest flat plate producers
in COVID year 2020”, Solarthermalworld.org, 7 April 2021, https://
www.solarthermalworld.org/news/mixed-performance-worlds-
largest-flat-plate-producers-covid-year-2020.
114 Ibid.
115 Epp, op. cit. note 14.
116 News about ranking of the largest flat plate collector
manufacturers yet to be published.
117 Epp, op. cit. note 113.
118 Epp, op. cit. note 14.
119 Epp, op. cit. note 113.
120 B. Epp, “Acquisition of strategic importance”, Solarthermalworld.org,
3 April 2020, https://www.solarthermalworld.org/news/acquisition-
strategic-importance.
121 Ibid.
122 Ibid.
123 C. Stadler, Viessmann, Allendorf, Germany, personal
communication with REN21, March 2021; Epp, op. cit. note 120.
124 B. Epp, “Shareholders force Glasspoint into liquidation”,
Solarthermalworld.org, 27 May 2020, https://www.solarthermalworld.
org/news/shareholders-force-glasspoint-liquidation.
125 Ibid.
126 Ibid.
127 B. Epp, “NewHeat secures EUR 13 million loan to finance 5 solar
heat plants”, Solarthermalworld.org, 14 September 2020,
https://www.solarthermalworld.org/news/newheat-secures-
eur-13-million-loan-finance-5-solar-heat-plants.
128 Ibid.
129 B. Epp, “Kyotherm wins 2019 SHC Solar Award”, Solarthermalworld.
org, 14 November 2019, https://www.solarthermalworld.org/news/
kyotherm-wins-2019-shc-solar-award.
130 R. Cuer, Kyotherm, Paris, France, personal communication with
REN21, December 2020.
131 J. Byström, Absolicon Solar Collector, Härnösand, Sweden,
personal communication with solrico, March 2021.
132 Ibid.
133 Ibid.
134 Dias, op. cit. note 50.
135 Solar Payback, “Suppliers of Turnkey Solar Process Heat
Systems”, http://www.solar-payback.com/suppliers, viewed 28
February 2021.
136 The aperture area of the parabolic trough collector plant
in Handan is planned to be 117,000 m2, or 83 MWth when
using a conversion factor of 0.7 kW/m2, from Y. Wang,
Inner Mongolia XuChen Energy, Baotou, Inner Mongolia,
China, personal communication with solrico, April 2021;
B. Epp, “World´s largest solar district heating plant with
concentrating collectors”, Solarthermalworld.org, 25
September 2020, https://www.solarthermalworld.org/news/
worlds-largest-solar-district-heating-plant-concentrating-
collectors.
137 N. Irwin, Solaflux, Reading, Pennsylvania, United States, personal
communication with solrico, March 2021.
138 A. Gupta, Skyven Technologies, Fresno, California, United States,
personal communication with solrico, March 2021; J. Ruiz Morales,
True Solar Power, Madrid, Spain, personal communication with
solrico, March 2021; E. Almaraz, Umbral Energia, Monterrey, Nuevo
León, Mexico, personal communication with solrico, March 2021.
139 M. Berrada, Alto Solution, Aix-en-Provence, France, personal
communication with solrico, March 2021; C. Graf von Moy,
Heliovis, Wiener Neudorf, Austria, personal communication with
solrico, March 2021.
140 E. Gerden, “Collector factory starts up in Saint Petersburg”,
Solarthermalworld.org, 11 August 2020, https://www.
solarthermalworld.org/news/collector-factory-starts-saint-
petersburg; E. Gerden, “Air collectors from Saint Petersburg”,
Solarthermalworld.org, 17 March 2021, https://www.
solarthermalworld.org/news/air-collectors-saint-petersburg.
141 Epp, op. cit. note 94.
142 Survey among SHIP system suppliers listed in Solar Payback, op.
cit. note 135, carried out in March/April 2021, from B. Epp, Bielefeld,
Germany, personal communication with REN21, March 2021.
143 Ibid.
144 Ibid.
145 Epp, op. cit. note 94.
146 Ibid.
147 Ibid.
148 Survey among SHIP system suppliers, Epp, op. cit. note 142.
149 R. Cuer, Kyotherm, Paris, France, personal communication with
REN21, March 2021.
150 Ibid.
151 Survey among SHIP system suppliers, Epp, op. cit. note 142.
326
https://www.solarthermalworld.org/news/hybrid-solutions-maximise-solar-yield-area
https://www.solarthermalworld.org/news/hybrid-solutions-maximise-solar-yield-area
https://www.solarthermalworld.org/news/mixed-performance-worlds-largest-flat-plate-producers-covid-year-2020
https://www.solarthermalworld.org/news/mixed-performance-worlds-largest-flat-plate-producers-covid-year-2020
https://www.solarthermalworld.org/news/mixed-performance-worlds-largest-flat-plate-producers-covid-year-2020
https://www.solarthermalworld.org/news/acquisition-strategic-importance
https://www.solarthermalworld.org/news/acquisition-strategic-importance
https://www.solarthermalworld.org/news/shareholders-force-glasspoint-liquidation
https://www.solarthermalworld.org/news/shareholders-force-glasspoint-liquidation
https://www.solarthermalworld.org/news/newheat-secures-eur-13-million-loan-finance-5-solar-heat-plants
https://www.solarthermalworld.org/news/newheat-secures-eur-13-million-loan-finance-5-solar-heat-plants
https://www.solarthermalworld.org/news/kyotherm-wins-2019-shc-solar-award
https://www.solarthermalworld.org/news/kyotherm-wins-2019-shc-solar-award
http://www.solar-payback.com/suppliers
https://www.solarthermalworld.org/news/worlds-largest-solar-district-heating-plant-concentrating-collectors
https://www.solarthermalworld.org/news/worlds-largest-solar-district-heating-plant-concentrating-collectors
https://www.solarthermalworld.org/news/worlds-largest-solar-district-heating-plant-concentrating-collectors
https://www.solarthermalworld.org/news/collector-factory-starts-saint-petersburg
https://www.solarthermalworld.org/news/collector-factory-starts-saint-petersburg
https://www.solarthermalworld.org/news/collector-factory-starts-saint-petersburg
https://www.solarthermalworld.org/news/air-collectors-saint-petersburg
https://www.solarthermalworld.org/news/air-collectors-saint-petersburg
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
WIND POWER
1 Figure of 93 gigawatts (GW) based on data from Global Wind
Energy Council (GWEC), Global Wind Report 2021 (Brussels:
March 2021), p. 53, https://gwec.net/global-wind-report-2021, and
from World Wind Energy Association (WWEA), “Worldwide wind
capacity reaches 744 gigawatts – an unprecedented 93 gigawatts
added in 2020”, press release (Bonn: 24 March 2021), https://
wwindea.org/worldwide-wind-capacity-reaches-744-gigawatts.
Capacity added onshore (a record high) and offshore (second
highest ever) from GWEC, op. cit. this note, p. 44. Additions
are gross, but year-end totals account for decommissioned
capacity. Note that GWEC reports installations with turbines
larger than 200 kilowatts (kW); projects with smaller turbines
are not included. Global net additions were 111,027 megawatts
(MW), based on 733,276 MW at end-2020 and 622,249 MW at
end-2019, from International Renewable Energy Agency (IRENA),
Renewable Capacity Statistics (Abu Dhabi: March 2021), https://
www.irena.org/publications/2021/March/Renewable-Capacity-
Statistics-2021. Of this, 105,015 MW was added onshore and the
remainder was offshore, based on data from IRENA, op. cit. this
note. Global additions were 96.3 GW in 2020, compared with 60.7
GW in 2019, with 94% of additions onshore and the rest offshore
(down 19% to 6.1 GW), from BloombergNEF, “Global wind industry
had a record, near 100GW, year as GE, Goldwind took lead from
Vestas”, 10 March 2021, https://about.bnef.com/blog/global-wind-
industry-had-a-record-near-100gw-year-as-ge-goldwind-took-
lead-from-vestas. Note that additional capacity was in operation
via small-scale turbines. See Box 7 in this section for details on
turbines up to 100 kW in size.
2 Figure of 45% based on installations in 2015 of 63.8 GW, from
GWEC, op. cit. note 1, p. 51, and 53% increase based on additions of
60,877 MW in 2019, from idem, p. 53.
3 GWEC, Global Offshore Wind Report 2020 (Brussels: 5 August 2020),
p. 24, http://gwec.net/global-offshore-wind-report-2020; WWEA,
“World wind power deployment: Some delays in 2020 due to Covid-
19, but bright future prospects”, 6 November 2020, https://wwindea.
org/world-wind-power-deployment-some-delays-in-2020-due-to-
covid-19-but-bright-future-prospects; various impacts of pandemic
from, for example, GWEC, op. cit. note 1, p. 53; B. Backwell and S.
Mullin, GWEC, “2020 In review: End of year special”, The Offshore
Wind Podcast, December 2020, https://gwec.net.
4 Based on year-end 2020 capacity of 742,689 MW and year-end
2019 capacity of 650,199 MW, from GWEC, op. cit. note 1, p. 53, and
double total capacity at end-2014 (370 GW), from idem, p. 52. Year-
end global capacity was 733,276 MW, from IRENA, op. cit. note
1. China accounts for most of the difference between data from
GWEC and IRENA. See endnote 26. Note that annual additions
reported in this section are gross additions unless otherwise noted,
but most countries did not decommission capacity during the year.
Figure 34 based on historical data from GWEC, op. cit. note 1, pp.
51-52; data for 2021 based on sources provided in endnote 1.
5 China’s market was driven by the cut-off to the national feed-in
tariff at year’s end, and the US market was driven by a scheduled
step-down in the production tax credit as of 1 January 2021 (the
step-down was postponed in December), from GWEC, op. cit. note
1, p. 6. Rest of world based on data from idem, p. 53.
6 See, for example, infrastructure, policy and regulatory challenges in
India, from GWEC, “China blows past global wind power records,
doubling annual installations in 2020”, 18 March 2021, https://
gwec.net/china-blows-past-global-wind-power-records-doubling-
annual-installations-in-2020; slow permitting or lack thereof was
an issue in Germany and Italy, from WindEurope, Wind Energy in
Europe: 2020 Statistics and the Outlook for 2021-2025, p. 23, https://
windeurope.org/data-and-analysis/product/wind-energy-in-
europe-in-2020-trends-and-statistics; lack of interconnections in
Chile, Vietnam and other countries, and permitting processes in
the Philippines, and financing in Ethiopia from GWEC, op. cit. note
1. Record installations based on the following: Argentina (added
1,014 MW), Australia (1,097 MW), Chile (684 MW), Japan (551 MW),
Kazakhstan (300 MW) and Sri Lanka (88 MW), from GWEC, op. cit.
note 1, p. 53, and from GWEC, “Global Wind Statistics 2020: Status
as end of 2020” (Brussels: March 2020); Norway (1,532 MW) from
WindEurope, op. cit. this note, pp. 11, 13; and the Russian Federation
(715 MW), from WWEA, op. cit. note 1.
7 At least 49 countries and Tanzania, based on data from GWEC,
“Global Wind Statistics 2020”, op. cit. note 6, and from F. Zhao,
GWEC, Copenhagen, personal communication with REN21,
26 April 2021. At least 55 countries in 2019 based on data from
GWEC, “Global Wind Statistics 2019: Status as End of 2019”
(Brussels: March 2020), and from Zhao, op. cit. this note, 13 April
2020. In 2018, at least 47 countries based on data from GWEC,
Global Wind Report 2018 (Brussels: April 2019), https://gwec.net/
wp-content/uploads/2019/04/GWEC-Global-Wind-Report-2018.
pdf. Tanzania added its first commercial wind farm, from Future
Power Technology, “A look at Tanzania’s first wind farm”, https://
power.nridigital.com/future_power_technology_jul20/tanzania_
wind_farm, viewed 27 April 2021, and from GWEC, “Global Wind
Statistics 2020”, op. cit. note 6.
8 Based on data from GWEC, “Global Wind Statistics 2020”, op. cit.
note 6, and from Zhao, op. cit. note 7, 26 April 2021.
9 GWEC, op. cit. note 1, p. 17; B. Eckhouse, “Solar and wind cheapest
source of power in most of the world”, Bloomberg, 28 April 2020,
https://www.bloomberg.com/news/articles/2020-04-28/solar-
and-wind-cheapest-sources-of-power-in-most-of-the-world;
IRENA, Renewable Power Generation Costs in 2018 (Abu Dhabi:
2019), pp. 9-11, https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2019/May/IRENA_Renewable-Power-
Generations-Costs-in-2018 ; GWEC and MEC Intelligence, India
Wind Outlook Towards 2022: Looking Beyond Headwinds (Brussels
and Gurugram, India: May 2020), pp. 9, 13, https://gwec.net/india-
wind-outlook-towards-2022-looking-beyond-headwinds; Frankfurt
School-UNEP Collaborating Centre on Climate & Energy Finance
(FS-UNEP) and BloombergNEF, Global Trends in Renewable
Energy Investment 2020 (Frankfurt: 2020), pp. 27-29, https://www.
fs-unep-centre.org. See also, for example: Clean Energy Council,
Clean Energy Australia Report 2019 (Melbourne: 2019), p. 72,
https://assets.cleanenergycouncil.org.au/documents/resources/
reports/clean-energy-australia/clean-energy-australia-report-2019.
pdf; American Wind Energy Association (AWEA), “US wind power
grew 8 percent amid record demand”, press release (Washington,
DC: 9 April 2019), https://www.awea.org/2018-market-report_
us-wind-power-grew-8-percent-in-2018; B. Chapman, “Offshore
wind energy price plunges 30 per cent to a new record low”,
Independent (UK), 20 September 2019, https://www.independent.
co.uk/news/business/news/offshore-wind-power-energy-price-
falls-record-low-renewables-a9113876.html.
10 S. Sawyer, GWEC, Brussels, personal communication with REN21,
13 March 2019. See also C. Bogmans, “Falling costs make wind, solar
more affordable”, International Monetary Fund, 26 April 2019, https://
blogs.imf.org/2019/04/26/falling-costs-make-wind-solar-more-
affordable; FS-UNEP and BloombergNEF, op. cit. note 9, p. 29.
11 GWEC, op. cit. note 1, p. 46; GWEC, Global Wind Market Outlook
Update Q3 2019 (Brussels: September 2019), p. 2; GWEC, Global
Wind Report 2019 (Brussels: March 2020), p. 37, https://gwec.net/
global-wind-report-2019; Latin American Energy Organization
(OLADE) and GWEC, cited in GWEC, “Public tenders and auctions
have driven 80% of current renewable energy capacity in Latin
America and the Caribbean”, press release (Brussels: 4 March
2020), https://gwec.net/public-tenders-and-auctions-have-driven-
80-of-current-renewable-energy-capacity-in-latin-america-and-
the-caribbean. In 2020, about 56% of the market was driven by
feed-in tariffs (FITs) (China), 19% was driven by the US Production
Tax Credit, followed by auctions and tenders (19.7%), and green
certificates and other mechanisms (totalling a combined 4.6%),
from GWEC, op. cit. note 1.
12 BloombergNEF, cited in GWEC, op. cit. note 1, p. 7.
13 EU share and five Member States (Denmark, Ireland, Germany,
Portugal and Spain), from WindEurope, op. cit. note 6, p. 19, and
from I. Komusanac, WindEurope, personal communication with
REN21, 12 April 2021. If the United Kingdom were still an EU
member, the total share from wind would be 16% and the country
would be on this list as well, from idem, both sources.
14 Denmark’s share of consumption based on total of 16,353 gigawatt-
hours (GWh) of wind energy generation and total electricity supply
(including imports) of 34,104 GWh, for a share of 48%; share of
net generation from wind based on total of 16,353 GWh from wind
energy in 2020 and 27,907 GWh of total net generation, for a share
of 58.6%, all from Danish Energy Agency, “Monthly energy statistics,
electricity supply”, https://ens.dk/en/our-services/statistics-data-
key-figures-and-energy-maps/annual-and-monthly-statistics,
viewed 1 March 2021. Denmark’s share of consumption was 46.1%,
from Wind Denmark, “2020 bød på rekordhøj produktion fra landets
vindmøller”, 2 January 2021, https://winddenmark.dk/nyheder/2020-
boed-paa-rekordhoej-produktion-fra-landets-vindmoeller (using
Google Translate), and it would have been closer to 51%, if not for
curtailment during the year, from idem.
327
https://gwec.net/global-wind-report-2021
https://wwindea.org/worldwide-wind-capacity-reaches-744-gigawatts
https://wwindea.org/worldwide-wind-capacity-reaches-744-gigawatts
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://www.irena.org/publications/2021/March/Renewable-Capacity-Statistics-2021
https://about.bnef.com/blog/global-wind-industry-had-a-record-near-100gw-year-as-ge-goldwind-took-lead-from-vestas
https://about.bnef.com/blog/global-wind-industry-had-a-record-near-100gw-year-as-ge-goldwind-took-lead-from-vestas
https://about.bnef.com/blog/global-wind-industry-had-a-record-near-100gw-year-as-ge-goldwind-took-lead-from-vestas
http://gwec.net/global-offshore-wind-report-2020
https://wwindea.org/world-wind-power-deployment-some-delays-in-2020-due-to-covid-19-but-bright-future-prospects
https://wwindea.org/world-wind-power-deployment-some-delays-in-2020-due-to-covid-19-but-bright-future-prospects
https://wwindea.org/world-wind-power-deployment-some-delays-in-2020-due-to-covid-19-but-bright-future-prospects
https://gwec.net
https://gwec.net/china-blows-past-global-wind-power-records-doubling-annual-installations-in-2020
https://gwec.net/china-blows-past-global-wind-power-records-doubling-annual-installations-in-2020
https://gwec.net/china-blows-past-global-wind-power-records-doubling-annual-installations-in-2020
https://windeurope.org/data-and-analysis/product/wind-energy-in-europe-in-2020-trends-and-statistics
https://windeurope.org/data-and-analysis/product/wind-energy-in-europe-in-2020-trends-and-statistics
https://windeurope.org/data-and-analysis/product/wind-energy-in-europe-in-2020-trends-and-statistics
https://gwec.net/wp-content/uploads/2019/04/GWEC-Global-Wind-Report-2018
https://gwec.net/wp-content/uploads/2019/04/GWEC-Global-Wind-Report-2018
https://gwec.net/wp-content/uploads/2019/04/GWEC-Global-Wind-Report-2018
https://power.nridigital.com/future_power_technology_jul20/tanzania_wind_farm
https://power.nridigital.com/future_power_technology_jul20/tanzania_wind_farm
https://power.nridigital.com/future_power_technology_jul20/tanzania_wind_farm
https://www.bloomberg.com/news/articles/2020-04-28/solar-and-wind-cheapest-sources-of-power-in-most-of-the-world
https://www.bloomberg.com/news/articles/2020-04-28/solar-and-wind-cheapest-sources-of-power-in-most-of-the-world
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/May/IRENA_Renewable-Power-Generations-Costs-in-2018
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/May/IRENA_Renewable-Power-Generations-Costs-in-2018
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/May/IRENA_Renewable-Power-Generations-Costs-in-2018
https://gwec.net/india-wind-outlook-towards-2022-looking-beyond-headwinds
https://gwec.net/india-wind-outlook-towards-2022-looking-beyond-headwinds
https://www.fs-unep-centre.org
https://www.fs-unep-centre.org
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2019
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2019
https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2019
https://www.awea.org/2018-market-report_us-wind-power-grew-8-percent-in-2018
https://www.awea.org/2018-market-report_us-wind-power-grew-8-percent-in-2018
https://www.independent.co.uk/news/business/news/offshore-wind-power-energy-price-falls-record-low-renewables-a9113876.html
https://www.independent.co.uk/news/business/news/offshore-wind-power-energy-price-falls-record-low-renewables-a9113876.html
https://www.independent.co.uk/news/business/news/offshore-wind-power-energy-price-falls-record-low-renewables-a9113876.html
https://blogs.imf.org/2019/04/26/falling-costs-make-wind-solar-more-affordable
https://blogs.imf.org/2019/04/26/falling-costs-make-wind-solar-more-affordable
https://blogs.imf.org/2019/04/26/falling-costs-make-wind-solar-more-affordable
https://gwec.net/global-wind-report-2019
https://gwec.net/global-wind-report-2019
https://gwec.net/public-tenders-and-auctions-have-driven-80-of-current-renewable-energy-capacity-in-latin-america-and-the-caribbean
https://gwec.net/public-tenders-and-auctions-have-driven-80-of-current-renewable-energy-capacity-in-latin-america-and-the-caribbean
https://gwec.net/public-tenders-and-auctions-have-driven-80-of-current-renewable-energy-capacity-in-latin-america-and-the-caribbean
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://winddenmark.dk/nyheder/2020-boed-paa-rekordhoej-produktion-fra-landets-vindmoeller
https://winddenmark.dk/nyheder/2020-boed-paa-rekordhoej-produktion-fra-landets-vindmoeller
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
15 List of countries based on data from WindEurope, op. cit. note 6,
p. 19. Data for Ireland based on EIRGRID GROUP, “System and
Renewable Summary Report”, http://www.eirgridgroup.com/
how-the-grid-works/renewables, viewed 28 February 2021; United
Kingdom (24.18%), based on 34,948 GWh generation onshore
plus 40,662 GWh generated offshore, and total UK generation of
312,759 GWh in 2020, from UK Department for Business, Energy &
Industrial Strategy (BEIS), “Energy Trends: Renewables”,Table 6.1.
Renewable electricity capacity and generation, https://www.gov.
uk/government/statistics/energy-trends-section-6-renewables,
updated 25 March 2021; Portugal from Associação Portuguesa de
Energias Renováveis (APREN), Portuguese Renewable Electricity
Report (Lisbon: December 2020), p. 1, https://www.apren.pt/
contents/publicationsreportcarditems/portuguese-renewable-
electricity-report-december2020 ; Germany share of gross
generation in 2020 was 23.2%, based on wind energy gross
generation of 130,965 GWh (including 103,662 GWh onshore
and 27,303 GWh offshore), from Federal Ministry for Economic
Affairs and Energy (BMWi) and Arbeitsgruppe Erneuerbare
Energien-Statistik (AGEE-Stat), Time Series for the Development of
Renewable Energy Sources in Germany – based on statistical data
from the Working Group on Renewable Energy-Statistics (AGEE-
Stat) (Status: February 2021) (Dessa-Roßlau: February 2021), p.
46, https://www.erneuerbare-energien.de/EE/Navigation/DE/
Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.
html, and on 565.3 terawatt-hours (TWh) of total gross generation
(not including pumped storage) in 2020, from AG Energiebilanzen
e.V., “Bruttostromerzeugung”, Strommix – Stromerzeugung
nach Energieträgern 1990-2020 (Stand Februar 2021)”, https://
ag-energiebilanzen.de/4-0-Arbeitsgemeinschaft.html, viewed 5 May
2021. Note that the share of national production in 2020 was 27.1%,
from Fraunhofer ISE, “Annual wind share of electricity production
in Germany”, Energy-Charts, https://energy-charts.info/charts/
renewable_share/chart.htm?l=en&c=DE&share=wind_share,
updated 19 April 2021, and wind energy’s share of national gross
consumption in Germany was 23.6%, from BMWi and AGEE-Stat,
op. cit. this note, p. 46. Spain from Red Eléctrica de España (REE),
“2020, the year with the 'greenest' energy thanks to record wind
and solar photovoltaic generation”, press release (Madrid: 12
March 2021), https://www.ree.es/en/press-office/news/press-
release/2021/03/2020-the-year-with-the-greenest-energy-thanks-
to-record-wind-and-solar-photovoltaic-generation. Other European
countries with shares of 10% or higher included Belgium (14%),
Lithuania (13%), Netherlands, Romania and Austria (all 12%),
Estonia (11%) and Croatia (10%), all based on data from ENTSO-E
and corrected with data from national transmission service operators
and governments and cited in WindEurope, op. cit. note 6, p. 19.
Shares were 27% in the United Kingdom, 25% in Portugal, 22% in
Spain and 20% in Sweden, from Komusanac, op. cit. note 13.
16 Uruguay generated 40.4% of its electricity with wind energy in
2020, based on production of 5,437.7 GWh from wind energy
and 13,470.5 GWh total, from Ministerio de Industria, Energía y
Minería (MIEM), Balance Energético Nacional Uruguay, “Balance
preliminar 2020”, https://ben.miem.gub.uy/preliminar.php, viewed
16 April 2021. Nicaragua generated 27.62% of total net electricity
output with wind energy, from Instituto Nicaragüense de Energía
(INE), Ente Regulador, “Generación neta de energía eléctrica
sistema eléctrico nacional año 2020”, https://www.ine.gob.ni/
DGE/estadisticas/2020/Generacion_Neta_2020_actagost20 ,
viewed 1 March 2021; and wind energy accounted for 23.58% of
total electricity generation, from INE, Ente Regulador, “Generación
bruta de energía eléctrica sistema eléctrico nacional año 2020”,
https://www.ine.gob.ni/DGE/estadisticas/2020/Generacion_
Bruta_2020_actagost20 , viewed 1 March 2021.
17 Share of generation in 2020 based on estimated total global
electricity generation of 25,849.92 TWh and total wind generation
of 1,590.19 TWh, from Ember, Global Electricity Review 2021
(London: 2021), https://ember-climate.org/project/global-
electricity-review-2021. Global totals for 2020 were estimated by
summing total electricity generation and electricity generation
per energy source in 36 countries where 2020 national sources
(including official government data and utility data) were available,
comprising 90% of global generation. See Ember, “Methodology”,
https://ember-climate.org/global-electricity-review-2021/
methodology, viewed 7 April 2021. Note that by the end of 2020,
there was enough wind power capacity in operation to provide an
estimated 6.38% of global electricity generation, based on GWEC,
“Global Wind Energy Statistics 2020 Database”, provided by Zhao,
op. cit. note 7, 26 April 2021.
18 Share of market in 2019 (including Turkey), and total year-end capacity
(including Turkey), based on data from GWEC, op. cit. note 1, p. 53;
Asia (including Turkey) and China shares of market in 2020, based
on data from GWEC, “Global Wind Statistics 2020”, op. cit. note 6,
and revised data for Spain (1,720 MW added), from Komusanac, op.
cit. note 13. Asia’s share in 2018 was 51.9% (also including Turkey),
based on data from GWEC, “Global Wind Statistics 2019”, op. cit.
note 7; and the share in 2017 was 48%, based on data from GWEC,
Global Wind Report – Annual Market Update 2017 (Brussels: April
2018), p. 17, http://files.gwec.net/files/GWR2017 .
19 Regional shares based on data from GWEC, “Global Wind
Statistics 2020”, op. cit. note 6, and from Komusanac, op. cit. note
13. Numbers in text are based on regional groupings that include
Turkey as part of Asia, rather than Europe, and Mexico as part of
Latin America, rather than North America. Other regional shares
include Oceania (Australia and New Zealand added capacity) with
1.3% of the total added in 2020, Africa with almost 0.8%, and the
Middle East with 0.1%, all from idem.
20 GWEC, op. cit. note 1, pp. 48, 53; Europe projects delayed to 2021
from Komusanac, op. cit. note 13.
21 GWEC, “Global Wind Statistics 2020”, op. cit. note 6; Komusanac,
op. cit. note 13.
22 Based on data from GWEC, op. cit. note 1, p. 53, from WindEurope,
op. cit. note 6, p. 11, and from Komusanac, op. cit. note 13. Figure 35
based on country-specific data and sources provided throughout
this section, and largely drawn from the following: GWEC, op.
cit. note 1; GWEC, “Global Wind Statistics 2020”, op. cit. note 6;
WindEurope, op. cit. note 6; WWEA, op. cit. note 1.
23 Based on data from GWEC, op. cit. note 1, p. 53; WindEurope,
op. cit. note 6, p. 11; WWEA, op. cit. note 1; GWEC, “Global Wind
Statistics 2019”, op. cit. note 7; WindEurope, Wind Energy in Europe
in 2019: Trends and Statistics (Brussels: 2020), p. 10, https://
windeurope.org/wp-content/uploads/files/about-wind/statistics/
WindEurope-Annual-Statistics-2019 .
24 Grid connections from G. Baiyu, “Despite coronavirus, China aims
for renewables grid parity”, China Dialogue, 2 June 2020, https://
chinadialogue.net/en/energy/despite-coronavirus-china-aims-
for-renewables-grid-parity. China recovered quickly from the
economic impacts of the pandemic, and the rapid recovery enabled
project installations and manufacturing to bounce back as early
as March; also, grid companies undertook measures to address
bottlenecks and connect as much capacity as possible during the
year, from GWEC, “A gust of growth in China makes 2020 a record
year for wind energy”, 21 January 2021, https://gwec.net/a-gust-of-
growth-in-china-makes-2020-a-record-year-for-wind-energy.
25 China added an estimated 52,000 MW in 2020, including 48,940
MW onshore and 3,060 MW offshore, for a year-end total of
288,320 MW (278.3 GW onshore and nearly 10 GW offshore), and
added 26,785 MW in 2019, all preliminary data from Chinese Wind
Energy Association (CWEA), provided by GWEC, op. cit. note 1,
p. 53, and GWEC, “Global Wind Statistics 2020”, op. cit. note 6;
and added 52 GW (48.9 GW onshore and 3.1 GW offshore) for a
year-end total of 288.32 GW (278.19 GW onshore and 10.13 GW
offshore), all preliminary data from H. Yu, CWEA, Beijing, personal
communication with REN21, 12 May 2021; and China added 52,000
MW in 2020 for a total of 290,000 MW, from WWEA, op. cit. note 1.
In 2018, global capacity additions totalled 50.7 GW, from GWEC, op.
cit. note 1, p. 51.
26 Net additions of 72,380 MW, for a total of 281,530 MW, are official
data based on 209,150 MW in operation at end of 2019 and
281,530 MW in operation at end of 2020, from China Electricity
Council (CEC), cited in China Energy Portal, “2020 electricity &
other energy statistics (preliminary)”, 22 January 2021, https://
chinaenergyportal.org/en/2020-electricity-other-energy-statistics-
preliminary; and additions of 71.67 GW of grid-connected wind
power capacity (68.61 GW onshore and 3.06 GW offshore) for a
total of 281 GW (271 GW onshore and 9 GW offshore), from National
Energy Board, cited in National Energy Administration (NEA),
“Transcript of the online press conference of the National Energy
Administration in the first quarter of 2021”, 30 January 2021, http://
www.nea.gov.cn/2021-01/30/c_139708580.htm (using Google
Translate). Note that these data are based on grid-connected
capacity; in addition, “Due to differences in statistical standards,
confirmation of moment of grid connection, and other reasons,
there are certain discrepancies in data on total and newly installed
generation capacity”, from CEC cited in idem. China added a total
of 71.7 GW, from C. Richard, “China reports 72GW wind connected
to grid in record-breaking 2020”, Windpower Monthly, 22 January
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
2021, https://www.windpowermonthly.com/article/1705268/
china-reports-72gw-wind-connected-grid-record-breaking-2020.
China added 68.6 GW of onshore wind capacity to the grid in 2020,
from China’s NEA, cited in GWEC, op. cit. note 1, p. 45, and GWEC,
op. cit. note 24. However, CWEA estimates that 26 GW of this
total was installed by the end of 2019 and only connected to the
grid in 2020. Not including the 26 GW, new onshore installations
in 2020 totalled 48.9 GW, and the amount of capacity installed
and grid-connected in 2020 was about 45.4 GW, from GWEC,
op. cit. note 1, p. 45, and GWEC, op. cit. note 24. In addition, some
experts believed that the official Chinese numbers did not match
observations on the ground, and that massive installations at year’s
end would have created supply constraints, for which there was
little evidence in early 2021, from J. Deign, “What is going on with
China’s crazy clean energy installation figures?” Greentech Media,
2 February 2021, https://www.greentechmedia.com/articles/read/
what-is-going-on-with-chinas-crazy-clean-energy-installation-
figures. Note that the GSR uses GWEC/CWEA data for China
rather than official data, which vary depending on government
agency; GWEC/CWEA use these numbers because of the delay
of grid connection in China, from GWEC, op. cit. note 1, p. 74. The
difference in statistics among Chinese organisations and agencies
results from the fact that they count different things. There are no
Chinese statistics that provide actual grid-connected capacity, and
discrepancies among available statistics can be large. In general,
installed capacity refers to capacity that is constructed and usually
has wires carrying electricity from the turbines to a sub-station
(i.e., CWEA annual statistics); capacity qualifies as officially
grid-connected (i.e., included in CEC statistics) once certification is
granted and operators begin receiving the FIT premium payment,
which at times has required weeks or even months. In recent years,
due to transmission constraints in China, there often were lags of
several months from when turbines were wire-connected to the
sub-station until the process of certification and payment of the FIT
premium was complete. In 2020, there was a great rush to ensure
that projects were officially deemed to be grid-connected before
the end of the year in order to guarantee receipt of the expiring
onshore FIT; the higher, official statistics include capacity that was
connected to the grid during the year at wind projects that were
installed in 2020, as well as those from previous years. Data cited
by CWEA are based on information collected from the industry
during 2020 and early 2021, and are believed to most closely reflect
the status of the market in China. All based on information provided
in past years by GWEC and CWEA, as well as updates for 2020 and
confirmation of accuracy provided by Yu, op. cit. note 25.
27 GWEC, op. cit. note 1, pp. 45, 49, 71; GWEC, “China blows past
global wind power records”, op. cit. note 6; GWEC, op. cit. note 24;
Richard, op. cit. note 26. These were all projects that were approved
through 2018.
28 GWEC, op. cit. note 1, p. 49. See also Everchem, “Chinese
wind subsidies to end in December. China’s renewable
power price and subsidy: ‘new’ design in 2020?” 28
October 2020 / 29 January 2020, https://everchem.com/
chinese-wind-subsidies-to-end-in-december.
29 See, for example, Reuters, “China to stop subsidy for offshore
renewables, eyes 2021 start for green quota trading”, Nasdaq, 23
January 2020, https://www.nasdaq.com/articles/china-to-stop-
subsidy-for-offshore-renewables-eyes-2021-start-for-green-
quota-trading-2020; Everchem, op. cit. note 28; Bloomberg
News, “China boosts renewable power subsidies 7.5% to $13
billion”, MSN, 18 June 2020, https://www.msn.com/en-us/money/
markets/china-boosts-renewable-power-subsidies-7-5-to-13-
billion/ar-BB15E9sk; I. Shumkov, “China to reduce subsidies for
renewables by 30% in 2020”, Renewables Now, 22 November 2019,
https://renewablesnow.com/news/china-to-reduce-subsidies-for-
renewables-by-30-in-2020-677495. China introduced the feed-in
tariff for onshore wind power in 2009 and for offshore wind in 2014,
from Everchem, op. cit. note 28.
30 Deficit and backlog from Everchem, op. cit. note 28; EurObserv’ER,
Wind Energy Barometer (Paris: March 2020), p. 3, https://www.
eurobserv-er.org/wind-energy-barometer-2020. The deficit
situation was worsened by pandemic, from Baiyu, op. cit. note
24; competing subsidy-free from Reuters, op. cit. note 29. The
cumulative deficit for all renewables amounted to the equivalent
of USD 50 billion at the end of 2020, from Credit Suisse, cited in J.
Wong, “China’s green-power funding is blowing in the wind”, Wall
Street Journal, 21 April 2021, https://www.wsj.com/articles/chinas-
green-power-funding-is-blowing-in-the-wind-11619003815. One
source notes that wind and solar power projects benefit from lower
technology costs, but other costs – such as curtailment, taxes on
land, financing and initial development – remain high (accounting
for 20% or more of wind and solar power project costs) and are
barriers to grid parity, from Baiyu, op. cit. note 24.
31 GWEC, op. cit. note 1, p. 46.
32 360doc.com, “Multi-pictures: overview of the details of photovoltaic
and wind power installed capacity and power generation in various
provinces across the country in 2020”, 17 February 2021, http://
www.360doc.com/content/21/0217/07/73752269_962367138.
shtml (using Google Translate). Wind power accounted for more
than 20% of power capacity in Inner Mongolia (25.5%), Gansu
(24.4%), Ningxia (23.2%), Hebei (22.8%), Xinjiang (21.7%) and
Qinghai (20.9%), from idem.
33 Continued to shift from Ibid.; 40% from National Energy Board, op.
cit. note 26.
34 Top provinces for total from 360doc.com, op. cit. note 32. Top
provinces for additions in 2020 were Inner Mongolia (5.9 GW),
Henan (5.5 GW) and Shanxi (4.7 GW), from Yu, op. cit. note 25, 10
May 2021.
35 M. Lifang, China Renewable Energy Industries Association,
cited in G. Baiyu, “Offshore wind takes off in China”, China
Dialogue, 9 October 2020, https://chinadialogue.net/en/energy/
china-offshore-wind-power-growth.
36 Figure of 16.6 TWh of potential curtailed, and 3% curtailment
rate, from National Energy Board, op. cit. note 26; down from 4%
(16.9 TWh) in 2019, based on data from NEA, “Wind power grid-
connected operation in 2019”, 28 February 2020, http://www.nea.
gov.cn/2020-02/28/c_138827910.htm (using Google Translate);
targeted cap of 5% for 2020 was set in China’s Clean Energy
Consumption Action Plan (2018-20), from Z. Tong, “Greening of
renewable sector”, China Daily, 20 January 2021, http://www.
chinadaily.com.cn/a/202101/20/WS60077241a31024ad0baa3b71.
html. Note that the rate of average curtailment was 2% in 2020, per
NEA, 30 January 2021, provided by F. Haugwitz, Asia Europe Clean
Energy (Solar) Advisory Co. Ltd. (AECEA), personal communication
with REN21, 26 March 2021. National curtailment was 7% (27.7
TWh) in 2018, based on data from NEA, “Wind power grid-
connected operation in 2019”, op. cit. this note; national curtailment
in 2017 was 12% (41.9 TWh), from China National Energy Board,
cited in NEA, “Wind grid operation in 2017”, 1 February 2018, http://
www.nea.gov.cn/2018-02/01/c_136942234.htm (using Google
Translate); national curtailment in 2016 was 17% (49.7 TWh),
from NEA and CEC, provided by S. Pengfei, CWEA, personal
communication with REN21, 21 March 2017, and from NEA, “Wind
power grid operation in 2016”, 26 January 2017, http://www.nea.
gov.cn/2017-01/26/c_136014615.htm (using Google Translate).
37 In Xinjiang, the curtailment rate fell 3.7 percentage points in 2020,
to 10.3%; Gansu’s declined 1.3 percentage points, to 6.4%, and
Western Inner Mongolia’s fell 1.9 percentage points, to 7.0%, from
National Energy Board, op. cit. note 26. In Xinjiang, the curtailment
rate fell more than 9 percentage points in 2019 relative to 2018, to
14%; Gansu’s declined 11.4 percentage points in 2019, to 7.6%; Inner
Mongolia’s fell nearly 3 percentage points in 2019, to 7.1%, based
on 2019 data from NEA, “Wind power grid-connected operation
in 2019”, op. cit. note 36, and on 2018 data from NEA, “2018 added
solar PV capacities”, Finance World, 28 January 2019, https://
baijiahao.baidu.com/s?id=1623876437525496663&wfr=spider&fo
r=pc (using Google Translate).
38 Based on total power production in 2020 of 7,623,600 GWh
and total wind energy production of 466,500 GWh (based on
grid-connected capacity), for a share of 6.1%, from CEC, op. cit.
note 26. This was up from a share of 5.5% in 2019, based on total
annual generation of 7,326,900 GWh and wind energy generation
of 405,300 GWh, from idem. Wind energy produced 5.2% of total
in 2018 based on generation of 365.8 TWh that year, from China
Energy Portal, “2018 wind power installations and production
by province”, 28 January 2019, https://chinaenergyportal.org/
en/2018-wind-power-installations-and-production-by-province,
and based on data from China Electricity Council Express, cited
in NEA, “National Energy Administration released statistics on
national power industry in 2018”, 18 January 2019, http://www.nea.
gov.cn/2019-01/18/c_137754977.htm (using Google Translate). In
2017, wind energy generation was 305.7 TWh and its share of total
generation was 4.8%, from China National Energy Board, cited in
NEA, “Wind grid operation in 2017”, op. cit. note 36.
39 Turkey installed a net of 1,224.8 MW in 2020, up from 671.5 MW in
2019, for a year-end total of 9,305 MW, from Turkish Wind Energy
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
Association (TWEA), “With 1.224 MWm new capacity in 2020,
Turkey’s cumulative installed wind power capacity reached 9.305
MWm”, https://tureb.com.tr/eng/lib/uploads/6371c2b9854591cf.
pdf, viewed 26 March 2021. Turkey added 1,224 MW for a total of
9,305 MW, from WindEurope, op. cit. note 6, p. 11; added 1,249 MW
for a total of 9,305 MW, from WWEA, op. cit. note 1; and added
1,224 MW for a total of 9,279.5 MW, from GWEC, “Global Wind
Statistics 2020”, op. cit. note 6.
40 Based on data from TWEA, op. cit. note 39; WindEurope, op. cit.
note 6, p. 11; GWEC, “Global Wind Statistics 2020”, op. cit. note 6.
41 T. Sidki Uyar, Eurosolar Turkey, presentation for WWEA webinar
“Wind power around the world”, 7 April 2021, https://wwindea.org/
wweawebinar-wind-power-around-the-world.
42 “Turkey aims to double its solar energy capacity in 2021, compared
to 2020”, TRT World, 21 January 2021, https://www.trtworld.com/
turkey/turkey-aims-to-double-its-solar-energy-capacity-in-2021-
compared-to-2020-43452.
43 TWEA, op. cit. note 39.
44 Based on data from GWEC, op. cit. note 1, p. 53, and from GWEC,
“Global Wind Statistics 2020”, op. cit. note 6.
45 Net additions of 1,119 MW for total of 38,624 MW based on
37,505.18 MW at end-2019 from Government of India, Ministry
of New and Renewable Energy (MNRE), “Physical progress
– programme/scheme wise physical progress in 2019-20 &
cumulative upto Dec, 2019”, https://mnre.gov.in/physical-progress-
achievements, viewed 9 January 2020, and 38,624.15 MW at
end-2020 from Government of India, MNRE, “Physical progress
– programme/scheme wise physical progress in 2020-21 &
cumulative upto Dec, 2020”, https://mnre.gov.in/physical-progress-
achievements, viewed 3 February 2021.
46 Data from GWEC, op. cit. note 1, p. 53, and from GWEC, “Global
Wind Statistics 2020”, op. cit. note 6; decline from N. T. Prasad,
“Solar is the new king as installed capacity surpasses wind”,
Mercom India, 4 February 2021, https://mercomindia.com/
solar-is-the-new-king.
47 S. Gsänger, “A dangerous trend is challenging the success of wind
power around the globe: Concentration and monopolization”,
WindTech International, 4 February 2020, https://www.
windtech-international.com/view-from-inside/a-dangerous-trend-
is-challenging-the-success-of-wind-power-around-the-globe-
concentration-and-monopolisation; geographically concentrated
from J. Hossain, WWEA, “Experience with auctions in India”, from
WWEA, “Webinar: Wind power and renewable energy policies:
What is best to reach 100% RE”, 14 May 2020, https://wwindea.
org/blog/2020/05/07/wweawebinar-wind-power-and-renewable-
energy-policies-what-is-best-to-reach-100-re-14-may.
48 Government of India, MNRE, “State-wise installed capacity of grid
interactive renewable power as on 31.12.2020”, https://mnre.gov.
in/img/documents/uploads/file_s-1612163907504.xlsx, viewed 3
February 2021.
49 Figure of 5% based on wind generation of 60.428 BU, from
Central Electricity Authority, Centre for Energy Finance, India
Renewables Dashboard, Monthly generation for 1 January 2020
through 31 December 2020, https://www.renewablesindia.
in, viewed 6 May 2021,and total generation of 1,197.29 BU, from
Government of India, Ministry of Power, Central Electricity
Authority, “Dashboard – all India power generation from Jan-2020
to Dec-2020”, https://cea.nic.in/dashboard/?lang=en, viewed
6 May 2021; down 24% during peak season, from D. Agarwal
and G. Sidhu, “How did India’s renewable energy sector perform
during the year of COVID-19 lockdown?” 7 April 2021, https://
www.ceew.in/blogs/how-did-india%E2%80%99s-renewable-
energy-sector-perform-during-year-covid-19-lockdown; down
5% for the year from BloombergNEF, “Wind and solar supply
one-tenth of India’s power in 2020”, New Energy Finance, 18
January 2021, https://about.newenergyfinance.com/blog/
wind-and-solar-supply-one-tenth-of-indias-power-in-2020.
50 GWEC, op. cit. note 1, p. 48.
51 V. Petrova, “Only 2 GW of SECI wind projects for 2017-18 come to
commissioning – report”, Renewables Now, 15 May 2020, https://
renewablesnow.com/news/only-2-gw-of-seci-wind-projects-for-
2017-18-come-to-commissioning-report-699123. About two-thirds
of the 6 GW in awarded by the Solar Energy Corporation of India in
2017, and 2018 tenders were not yet online by mid-year, from idem.
52 Caps have often been too low to attract investors and have
resulted in undersubscribed tenders, leading to delayed deadlines
and retenders, from A. Parikh, “No more tariff caps for solar and
wind tenders”, Mercom India, 6 March 2020, https://mercomindia.
com/no-more-tariff-caps-solar-wind-tenders; the companies that
announced they would not participate were Acciona (Spain) and
Nordex (Germany), from K. Chandrasekaran, “Spain’s Acciona
and Germany’s Nordex bearish on India’s wind energy prospects”,
Economic Times, 7 September 2020, https://economictimes.
indiatimes.com/industry/energy/power/spanish-firm-acciona-
may-keep-away-from-new-renewables-projects-in-india/
articleshow/77979193.cms.
53 Japan added 551 MW onshore for a total of 4,432 MW (4,373 MW
onshore and 58.6 MW offshore), installations in 2019 and ranking, all
based on data from GWEC, “Global Wind Statistics 2020”, op. cit. note 6.
54 IEA, “Wind”, in Renewables 2020 (Paris: 2020), https://www.iea.
org/reports/renewables-2020/wind.
55 GWEC, “Global Wind Statistics 2020”, op. cit. note 6. See
also: A. Satubaldina, “Nine renewable energy projects to
be launched in Kazakhstan by December”, Astana Times,
27 April 2021, https://astanatimes.com/2020/05/nine-
renewable-energy-projects-to-be-launched-in-kazakhstan-
by-december; A. Cohen, “Oil-rich Kazakhstan begins the
long march towards renewables”, Forbes, 18 October 2019,
https://www.forbes.com/sites/arielcohen/2019/10/18/
oil-rich-kazakhstan-begins-the-long-march-towards-renewables.
56 GWEC, “Global Wind Statistics 2020”, op. cit. note 6. Pakistan
added 48.3 MW, the Republic of Korea added 160 MW (including
60 MW offshore), Sri Lanka added 88 MW, Chinese Taipei 74 MW
and Vietnam 125 MW, from idem. Vietnam’s FIT expiration from
S. Lim, “Market to watch: Vietnam”, GWEC, 23 April 2020, https://
gwec.net/market-to-watch-vietnam-2, and from L. Qiao, “Vietnam
needs to act now to mitigate wind development disruptions”,
GWEC, 23 April 2020, https://gwec.net/vietnam-needs-to-act-
now-to-mitigate-wind-development-disruptions; and capital
costs (down 30% in recent years) and electricity demand (average
annual growth of 10%), from McKinsey, cited in GWEC, op. cit.
note 1, p. 60. Vietnam ended the year short of a wind power target
(800 MW) set in 2018, due largely to permitting delays and lack of
interconnection availability (due to a surge of solar PV installations),
from GWEC, op. cit. note 1, pp. 60-61. Vietnam added 125 MW for
a year-end total of 612.3 MW, including 513.3 MW onshore and 99
MW offshore, from GWEC, “Global Wind Statistics 2020”, op. cit.
note 6.
57 The Americas added 21,763 MW in 2020 for a total of 170 GW, and
US share, based on data from GWEC, “GWEC: North and Latin
America increased wind power installations by 62% in 2020”, 11
March 2021, https://gwec.net/north-and-latin-america-increased-
wind-power-installations-by-62-in-2020. Figure of 62% based on
data from GWEC, op. cit. note 1, p. 53. The region’s estimated share
(for all Americas and Caribbean) was 23%, based on total global
additions of 93 GW, from idem, p. 53.
58 The United States added 16,913 MW for a total of 122,468 MW,
from American Clean Power Association (ACPA), ACP Market
Report – Fourth Quarter 2020 (Washington, DC: 2021), p. 4, https://
cleanpower.org/resources/american-clean-power-market-
report-q4-2020. Utility-scale capacity added in 2020 was 14.2
GW, for a year-end total of 118 GW, from US Department of Energy
(DOE), US Energy Information Administration (EIA), Electric Power
Monthly, cited in R. Bowers and O. Comstock, “The United States
installed more wind turbine capacity in 2020 than in any other
year”, US EIA, Today in Energy, 3 March 2021, https://www.eia.gov/
todayinenergy/detail.php?id=46976. More than 60,000 turbines
were operating across 41 US states and two territories at end-2020,
from ACPA, op. cit. this note, p. 4.
59 ACPA, op. cit. note 58, p. 6. In the fourth quarter 10,593 MW was
added, from idem.
60 Ibid., p. 9.
61 Ibid., p. 4; 38 million from ACPA, “Wind industry closes record 2020
with strongest quarter ever”, 4 February 2021, https://cleanpower.
org/news/wind-industry-closes-record-2020-with-strongest-
quarter-ever. A further 17.3 GW was under construction with 17.5
GW in the advanced development stage (more than one quarter of
this for offshore projects in US federal waters), from idem.
62 Texas lead, share and total capacity (33,133 MW), from ACPA,
op. cit. note 58, p. 11. Fifth globally based on idem and data from
GWEC, op. cit. note 1, p. 53. Other top states for total capacity at the
end of 2020 were Iowa (11,660 MW), Oklahoma (9,048 MW) and
Kansas (7,016 MW), and more than 20 US states had over 1 GW of
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installed capacity, from ACPA, op. cit. this note. Texas leads for total
utility-scale capacity (30.2 GW), from US EIA, cited in Bowers and
Comstock, op. cit. note 58.
63 US EIA, cited in Bowers and Comstock, op. cit. note 58. The 100%
PTC was scheduled to phase out at year’s end for wind power
projects that began construction in 2016, from GWEC, op. cit. note
57. In December, Congress passed a one-year extension of the
PTC and investment tax credit (ITC) for land-based wind power,
and a 30% ITC for offshore projects that start construction from
the beginning of 2017 through 2025, from D. Wagman, “US to
extend Investment Tax Credit for solar to 2024”, pv magazine, 22
December 2020, https://www.pv-magazine.com/2020/12/22/
us-to-extend-investment-tax-credit-for-solar-to-2024.
64 Demand from utilities from ACPA, op. cit. note 58, p. 18. Utilities
commissioned 4,918 MW of new wind power capacity in 2020,
from idem.
65 A total of 5,444 MW was contracted through PPAs, and
announcements down, from ACPA, op. cit. note 58, pp. 4, 19. New
wind power PPAs reached a record 8.7 GW in 2019, from AWEA,
U.S. Wind Industry Quarterly Market Report, Fourth Quarter 2019
(Washington, DC: January 2020), pp. 3, 4, https://www.awea.
org/resources/publications-and-reports/market-reports/2019-u-
s-wind-industry-market-reports/4q2019_marketreport. Utilities
signed 5,085 MW, their second highest amount, out of a record
total of 8,726 MW of PPAs, from AWEA, Wind Powers America –
Annual Report 2019, Executive Summary (Washington, DC: 2020),
p. 5, https://www.awea.org/resources/publications-and-reports/
market-reports/2019-u-s-wind-industry-market-reports/amr2019_
executivesummary. Most of the projects under construction were
expected to come online in 2020 to receive the full PTC value,
from AWEA, U.S. Wind Industry Quarterly Market Report, op. cit.
this note, pp. 3, 4. At year’s end, more than 16 GW of projects was
in the pipeline (just over half of the capacity) had a PPA in place;
utilities accounted for 70% of the capacity under construction or in
advanced development, from ACPA, op. cit. note 58, p. 18.
66 US EIA, cited in Bowers and Comstock, op. cit. note 58. Wind’s
share was 7.3% in 2019 and 6.5% of US total generation in 2018
based on data for utility-scale facilities net generation during
2018, from US EIA, Electric Power Monthly with Data for December
2020 (Washington, DC: February 2021), Table ES1.B. Share from
a decade earlier, from GWEC, op. cit. note 57. Daily highs were
far higher in 2020; for example, on 23 December, wind energy
accounted for 17% of total US electricity generation, from US EIA,
“U.S. wind generation sets new daily and hourly records at end
of 2020”, Today in Energy, 2 February 2021, https://www.eia.gov/
todayinenergy/detail.php?id=46617.
67 Texas the largest consumer and figure of nearly 20% of state
generation from US EIA, cited in Bowers and Comstock, op.
cit. note 58. Wind passed coal based on data from the Electric
Reliability Council of Texas (the state’s main grid operator), cited
in K. Lowder, “Texas wind power dominates coal In crossover
year”, CleanTechnica, 17 January 2021, https://cleantechnica.
com/2021/01/17/texas-wind-power-dominates-coal-in-
crossover-year. Wind energy was second only to natural gas
for Texas generation, accounting for 22% (compared with 18%
from coal) in 2020, up from 8% in 2010, from idem. Wind power
has seen billions of dollars in capital investment in the state
since 2010; the investment and jobs created have helped wind
power gain strong political support, from The Finance Info,
“Wind power overtakes coal in Texas electricity generation”,
12 January 2021, https://thefinanceinfo.com/2021/01/12/
wind-power-overtakes-coal-in-texas-electricity-generation.
68 US EIA, cited in Bowers and Comstock, op. cit. note 58. Other
states with higher shares than Texas include Nebraska (24%),
Colorado (23%), Minnesota (22%), as well as Maine, New Mexico
and South Dakota; also, in-state wind capacity accounted for at
least 10% of 2020 generation in Idaho, Illinois, Montana, Oregon,
Wyoming and Vermont, and accounted for 7% in California, all from
idem.
69 Southwest Power Pool, “SPP becomes first regional grid operator
with wind as No. 1 annual fuel source, considers electric storage
participation in markets, approves 2021 transmission plan”,
26 January 2021, https://spp.org/newsroom/press-releases/
spp-becomes-first-regional-grid-operator-with-wind-as-no-1-
annual-fuel-source-considers-electric-storage-participation-
in-markets-approves-2021-transmission-plan; M. Bates, “Wind
energy tops coal, natural gas in Southwest Power Pool”, North
American Wind Power, 26 January 2021, https://nawindpower.
com/spp-in-2020-wind-energy-tops-coal-natural-gas. SPP meets
electricity needs of 19 million people, from Southwest Power Pool,
“About us – reliability through relationships”, https://spp.org/
about-us, viewed 26 March 2021. Wind energy’s share is 31.3%,
compared with coal’s share of 30.9%, from Institute for Energy
Economics and Financial Analysis, “Wind surpassed coal as No.
1 fuel source in 2020 for Southwest Power Pool”, Energy Central
News, 12 February 2021, https://energycentral.com/news/energy-
ieefa-us-wind-surpassed-coal-no-1-fuel-source-2020-southwest-
power-pool.
70 Bates, op. cit. note 69; windiest states from J. Broehl, ACPA,
personal communication with REN21, 27 April 2021.
71 ACPA, op. cit. note 61.
72 Siting and resource availability from J. Gerdes, “California’s wind
market has all but died out. Could grid services revenue help?”
Greentech Media, 30 March 2020, https://www.greentechmedia.
com/articles/read/justin-california; grid congestion from K.
Lydersen, “Grid congestion a growing barrier for wind, solar
developers in MISO territory”, Energy News Network, 29
September 2020, https://energynews.us/2020/09/29/midwest/
grid-congestion-a-growing-barrier-for-wind-solar-developers-in-
miso-territory.
73 Ibid, both sources. See also: E. Pearcey and R. Sayles, “As Texas
probes power grid, national failings bite”, Reuters Events, 17
March 2021, https://www.reutersevents.com/renewables/wind/
texas-probes-power-grid-national-failings-bite; J. St. John, “Report:
Renewables are suffering from broken US transmission policy”,
Greentech Media, 12 January 2021, https://www.greentechmedia.
com/articles/read/report-renewables-are-suffering-from-broken-
u.s-transmission-policy.
74 Canada added 185 MW, based on 13,413 MW at end-2019 and
13,588 MW at end-2020, from Canadian Renewable Energy
Association, “By the numbers”, https://renewablesassociation.ca/
by-the-numbers, viewed 4 March 2021. The leading provinces for
cumulative capacity continued to be Ontario, which ended the year
with 5,436 MW (same as 2019), followed by Quebec (3,896 MW)
and Alberta (1,822 MW), where most new installations took place,
from idem.
75 Hardest hit from R. Fiestas, quoted in GWEC, op. cit. note 57; the
region added 4,672.8 MW including in Argentina, Brazil, Chile,
Mexico, Panama and Peru, and Brazil ranked third and eighth, all
based on data from GWEC, “Global Wind Statistics 2020”, op. cit.
note 6.
76 Fastest growing from R. Fiestas, quoted in GWEC, op. cit. note
57; 33.9 GW from idem; number of countries based on data from
GWEC, “Global Wind Statistics 2020”, op. cit. note 6.
77 Brazil added 2,297 MW in 2020, up from 745 MW in 2019, for a total
of 17,749.7 MW at end-2020, from GWEC, “Global Wind Statistics
2020”, op. cit. note 6.
78 GWEC, op. cit. note 1, p. 49.
79 I. Atxalandabaso, “Renewable energy in Latin America: 5 renewable
energy trends emerging from south of Rio Grande”, Rated Power,
16 April 2021, https://ratedpower.com/blog/renewable-energy-
latin-america; B. Bungane, “GWEC: Nearly 30GW of new wind
energy capacity was auctioned in 2020”, ESI Africa, 22 February
2021, https://www.esi-africa.com/industry-sectors/renewable-
energy/gwec-nearly-30gw-of-new-wind-energy-capacity-was-
auctioned-in-2020.
80 Brazil’s wind capacity generated 56,623 GWh in 2020, amounting
to 9.7%, based on data from Operador Nacional do Sistema
Elétrico, “Geração de Energia Tipo de Usina” accessed at “Geração
de Energia”, for period 1 January 2020 through 31 December 2020,
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-
da-operacao/geracao_energia.aspx, viewed 4 March 2021. Wind
power accounted for 9.4% of Brazil’s electricity generation in 2019,
up from 8.3% in 2018, based on total annual generation of 593,591
GWh and annual wind energy generation of 55,932 GWh in 2019,
and on total annual generation of 581,923 GWh and annual wind
energy generation of 48,443 GWh in 2018, all from Operador
Nacional do Sistema Elétrico (ONS), “Geração de energia –
composição”, for period 1 January 2019 to 31 December 2019,
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-
da-operacao/geracao_energia.aspx, viewed 24 April 2020.
81 Argentina added 1,014 MW for a total of 2,618 MW, and Chile
added 683.5 MW for a total of 2,828.5 MW, from GWEC, “Global
Wind Statistics 2020”, op. cit. note 6. Argentina ended the year
331
https://www.pv-magazine.com/2020/12/22/us-to-extend-investment-tax-credit-for-solar-to-2024
https://www.pv-magazine.com/2020/12/22/us-to-extend-investment-tax-credit-for-solar-to-2024
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/4q2019_marketreport
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/4q2019_marketreport
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/4q2019_marketreport
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/amr2019_executivesummary
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/amr2019_executivesummary
https://www.awea.org/resources/publications-and-reports/market-reports/2019-u-s-wind-industry-market-reports/amr2019_executivesummary
https://www.eia.gov/todayinenergy/detail.php?id=46617
https://www.eia.gov/todayinenergy/detail.php?id=46617
https://cleantechnica.com/2021/01/17/texas-wind-power-dominates-coal-in-crossover-year
https://cleantechnica.com/2021/01/17/texas-wind-power-dominates-coal-in-crossover-year
https://cleantechnica.com/2021/01/17/texas-wind-power-dominates-coal-in-crossover-year
https://thefinanceinfo.com/2021/01/12/wind-power-overtakes-coal-in-texas-electricity-generation
https://thefinanceinfo.com/2021/01/12/wind-power-overtakes-coal-in-texas-electricity-generation
https://spp.org/newsroom/press-releases/spp-becomes-first-regional-grid-operator-with-wind-as-no-1-annual-fuel-source-considers-electric-storage-participation-in-markets-approves-2021-transmission-plan
https://spp.org/newsroom/press-releases/spp-becomes-first-regional-grid-operator-with-wind-as-no-1-annual-fuel-source-considers-electric-storage-participation-in-markets-approves-2021-transmission-plan
https://spp.org/newsroom/press-releases/spp-becomes-first-regional-grid-operator-with-wind-as-no-1-annual-fuel-source-considers-electric-storage-participation-in-markets-approves-2021-transmission-plan
https://spp.org/newsroom/press-releases/spp-becomes-first-regional-grid-operator-with-wind-as-no-1-annual-fuel-source-considers-electric-storage-participation-in-markets-approves-2021-transmission-plan
https://nawindpower.com/spp-in-2020-wind-energy-tops-coal-natural-gas
https://nawindpower.com/spp-in-2020-wind-energy-tops-coal-natural-gas
https://spp.org/about-us
https://spp.org/about-us
https://energycentral.com/news/energy-ieefa-us-wind-surpassed-coal-no-1-fuel-source-2020-southwest-power-pool
https://energycentral.com/news/energy-ieefa-us-wind-surpassed-coal-no-1-fuel-source-2020-southwest-power-pool
https://energycentral.com/news/energy-ieefa-us-wind-surpassed-coal-no-1-fuel-source-2020-southwest-power-pool
https://www.greentechmedia.com/articles/read/justin-california
https://www.greentechmedia.com/articles/read/justin-california
https://energynews.us/2020/09/29/midwest/grid-congestion-a-growing-barrier-for-wind-solar-developers-in-miso-territory
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https://energynews.us/2020/09/29/midwest/grid-congestion-a-growing-barrier-for-wind-solar-developers-in-miso-territory
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https://www.esi-africa.com/industry-sectors/renewable-energy/gwec-nearly-30gw-of-new-wind-energy-capacity-was-auctioned-in-2020
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http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
http://www.ons.org.br/Paginas/resultados-da-operacao/historico-da-operacao/geracao_energia.aspx
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with 2,623 MW and wind energy accounted for 7% of generation
during the year, from Compañía Administradora del Mercado
Mayorista Eléctrico S.A. (CAMMESA), Informe Mensual Principales
Variables del Mes (Buenos Ares: December 2020), pp. 12, 17, 23,
https://portalweb.cammesa.com/memnet1/Pages/descargas.
aspx. Share of generation based on 9,406 GWh of electricity
generated with wind energy and total generation of 134,173
GWh, from idem. Chile’s year-end capacity was 2,657 MW and
wind energy accounted for 7.1% of annual generation, from
Asociación Chilena de Energías Renovables y Almacenamiento AG.
(ACERA), Estadísticas Sector de Generación de Energía Eléctrica
Renovable (December 2020), pp. 1, 3, https://acera.cl/wp-content/
uploads/2021/01/2020-12-Bolet%C3%ADn-Estad%C3%ADsticas-
ACERA . Chile ended the year with another 1.5 GW under
construction – completion was pushed into 2021 due to pandemic-
related delays, from GWEC, op. cit. note 1, pp. 53, 56. Another 1,823
MW was under construction at end-2020 and 4,426 MW had been
approved, from ACERA, op. cit. this note, pp. 3, 5.
82 Mexico added 574 MW for a total of 6,789 MW, Panama added
66 MW for a total of 336 MW, and Peru added 38 MW for a total
of 411 MW, from GWEC, op. cit. note 57, and GWEC, “Global Wind
Statistics 2020”, op. cit. note 6.
83 Among top 10 and declined 45%, based on data from GWEC,
“Global Wind Statistics 2020”, op. cit. note 6. Policy and regulatory
changes from R. Lozano, Emerging Leaders in Environmental
and Energy Policy Network, Mexico, personal communication
with REN21, 11 April 2021. Political challenges and rule changes in
2020 also from J. Villamil, “Why Mexico is pushing to slow down
clean energy”, Bloomberg, 16 July 2020, https://www.bloomberg.
com/news/articles/2020-07-16/why-mexico-is-pushing-to-slow-
down-clean-energy-quicktake; cancellation of auctions in 2019
from GWEC, Global Wind Market Outlook Update Q3 2019, op. cit.
note 11, p. 4; GWEC, “Americas wind installations rise 12% in 2019
to 13.4GW”, 4 February 2020, https://gwec.net/americas-wind-
installations-rise-12-in-2019-to-13-4gw. Mexico ended the year far off
track from its generation targets for 2021 (30% renewable electricity)
and 2024 (35%), from Villamil, op. cit. this note. See also A. Stillman,
“Mexico judge suspends controversial power law indefinitely”,
Bloomberg, 19 March 2021, https://www.bloomberg.com/news/
articles/2021-03-19/mexico-judge-suspends-nationalistic-
electricity-law-indefinitely, and “Mexico faces potential ‘tsunami’
of arbitration cases over electricity reform”, BNAmericas, 9 April
2021, https://www.bnamericas.com/en/interviews/mexico-faces-
potential-tsunami-of-arbitration-cases-over-electricity-reform.
84 Lozano, op. cit. note 83. See also Stillman, op. cit. note 83, and
“Mexico faces potential ‘tsunami’ of arbitration cases over
electricity reform”, op. cit. note 83.
85 IEA, op. cit. note 54.
86 “Global corporate clean energy purchasing up 18% in 2020”,
Renewable Energy World, 27 January 2021, https://www.
renewableenergyworld.com/solar/global-corporate-clean-energy-
purchasing-up-18-in-2020. Brazil signed a record 1,057 MW of
corporate PPAs for renewables (not only wind power), accounting
for most of the 1.5 GW signed in Latin America during 2020, from
BloombergNEF, cited in idem. That said, at least one PPA was
signed in Mexico for a 105 MW wind farm, from A. Danigelis, “Bayer
signs PPA for wind power in Mexico”, 27 August 2020, https://www.
environmentalleader.com/2020/08/bayer-wind-power-mexico.
87 All Europe data (not including Turkey) and down 6.6%, based
on data from WindEurope, op. cit. note 6, pp. 7, 11, and from
Komusanac, op. cit. note 13. Note that GWEC has lower numbers
for Europe (not including Turkey), with 13.5 GW gross additions for
a year-end total of 209.6 GW, from GWEC, op. cit. note 1, p. 53.
88 WindEurope, op. cit. note 6, p. 12; permitting delays in Germany
from R. Hinrichs-Rahlwes, European Renewable Energy
Federation, personal communication with REN21, 6 April 2021.
89 Many markets across the EU collapsed as a consequence of the
shift away from FITs, with the diversity and number of investors
declining, from S. Gsänger, WWEA, Bonn, personal communication
with REN21, 20 April 2021.
90 WindEurope, op. cit. note 6, p. 12.
91 Norway added 1,532 MW for a total of 3,980 MW, from
WindEurope, op. cit. note 6, pp. 11, 12, 13.
92 J. Agyepong-Parsons, “Europe’s largest wind farm finished despite
reindeer protests”, Windpower Monthly, 21 August 2020, https://
www.windpowermonthly.com/article/1692420/europes-largest-
wind-farm-finished-despite-reindeer-protests. Due to its size and
the geography of the chosen area, Fosen Vind is partitioned into a
group of six individually named wind farms for a total of 1 GW, from
Komusanac, op. cit. note 13.
93 The Russian Federation added 713 MW for a total of 905 MW, and
2018 auction, from WindEurope, op. cit. note 6, pp. 11, 14; added
0.7 GW for a total of more than 1 GW as of early 2021, from T.
Lanshina, Russia’s Wind Energy Market: Potential for New Economy
Development (Bonn: Friedrich Ebert Stiftung, March 2021), pp. 5,
6, https://wwindea.org/wp-content/uploads/2021/03/210319-
FESMOS-windenergy-en . See also E. Gerden, “Russia more
than triples capacity in 2020 but now faces delays”, Windpower
Monthly, 26 November 2020, https://www.windpowermonthly.
com/article/1701020/russia-triples-capacity-2020-faces-delays.
The Russian Federation’s largest wind farm (210 MW) was
commissioned in December 2020, from Novawind Rosatom,
“Electricity and power from the Rosatom’s Kochubeyevskaya Wind
Farm have entered the wholesale market”, press release (Moscow:
11 January 2021), http://novawind.ru/eng/press/news/news_item.
php?page=375.
94 Only major economy from Lanshina, op. cit. note 93, p. 6, and from
S. Gsänger, P. Teschendorf and L. Gürth, preface in idem, p. 5. Wind
power accounted for 0.4% of the Russian Federation’s generating
capacity (0.13% of generation) as of early 2021, from idem. Awarded
capacity from E. Nikolaev, Russianwind, presentation for WWEA
webinar “Wind power around the world”, 7 April 2021, https://
wwindea.org/wweawebinar-wind-power-around-the-world. Total
installed capacity rose from 136 MW in 2018 to 191 in 2019 and
905 MW in 2020; a total of 3,351 MW is expected until 2024 due to
tenders in past years, from idem.
95 Based on data from WindEurope, op. cit. note 6, p. 11, and from
GWEC, “Global Wind Statistics 2020”, op. cit. note 6. The United
Kingdom added 598 MW (115 MW onshore and 483 MW offshore)
for a total of 24,167 MW, from WindEurope, op. cit. note 6. The
country’s end-2020 capacity totalled 24,665 MW (14,282 MW
onshore and 10,383 MW offshore) (preliminary data), up from a
total of 24,095 MW (14,125 MW onshore and 9,971 MW offshore),
from UK BEIS, “Renewable electricity capacity and generation”,
Main Table, https://www.gov.uk/government/statistics/energy-
trends-section-6-renewables, viewed 16 April 2021. The UK added
598 MW (115 MW onshore and 483 MW offshore) for a total of
23,937 MW, from GWEC, “Global Wind Statistics 2020”, op. cit. note
6.
96 J. Parnell, “UK lifts block on new onshore wind and solar”,
Greentech Media, 2 March 2020, https://www.greentechmedia.
com/articles/read/uk-lifts-block-on-new-onshore-wind-and-solar.
97 UK BEIS, “Energy Trends UK, October to December 2020 and
2020“, 25 March 2021, pp. 14, 17, https://assets.publishing.service.
gov.uk/government/uploads/system/uploads/attachment_data/
file/972790/Energy_Trends_March_2021 .
98 J. Parnell, “Renewable generators are the UK’s latest tool to
smooth out renewable generation”, Greentech Media, 23
June 2020, https://www.greentechmedia.com/articles/read/
renewable-generators-are-uks-latest-tool-to-smooth-out-
renewable-generation; National Grid ESO, “Power Available phase
2 further unlocks the potential for variable generation to provide
balancing services“, 30 March 2021, https://www.nationalgrideso.
com/news/power-available-phase-2-further-unlocks-potential-
variable-generation-provide-balancing; National Grid ESO, “Power
Available: Unlocking renewables’ potential to help balance the
electricity system”, 18 May 2020, https://www.nationalgrideso.
com/news/power-available-unlocking-renewables-potential-help-
balance-electricity-system. See also L. Stroker, “World’s ‘largest,
most ambitious’ energy flexibility market trials to launch in the UK”,
Current+, 26 February 2020, https://www.current-news.co.uk/
news/worlds-largest-most-ambitious-energy-flexibility-market-
trials-to-launch-in-the-uk.
99 WindEurope, op. cit. note 6, p. 11; Komusanac, op. cit. note 13.
100 Based on data from WindEurope, op. cit. note 6, p. 11; WindEurope,
op. cit. note 23, p. 10.
101 Gross additions were down 1.5% and net additions were down 8%,
based on data from WindEurope, op. cit. note 6, p. 11; WindEurope,
op. cit. note 23, p. 10; and Komusanac, op. cit. note 13. The countries
that installed more in 2020 than in 2019 were Belgium, Croatia,
Finland, Luxembourg, the Netherlands and Poland, based on data
from WindEurope, op. cit. note 6, p. 11, and from Komusanac, op. cit.
note 13.
102 WindEurope, op. cit. note 6, p. 11; Komusanac, op. cit. note 13.
332
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103 Based on data from WindEurope, op. cit. note 6, p. 11; Komusanac,
op. cit. note 13. France added 1,104.8 MW added in 2020 for year-
end total of 17,616 MW, from Le Réseau de Transport d’Électricité
(RTE), Bilan Electrique 2020 (Paris: 2020), p. 54, https://assets.
rte-france.com/prod/public/2021-03/Bilan%20electrique%20
2020_0 , and added 1,105 MW for total of 17,616 MW, from
RTE, Panorama de l’Électricité Renouvelable (Paris: 31 December
2020), p. 17, https://assets.rte-france.com/prod/public/2021-02/
Panorama%20EnR_T4_2020_ .
104 Poland added 731 MW in 2020 (up from 53 MW in 2019) for a year-
end total of 6,614 MW, all onshore, from WindEurope, op. cit. note 6,
p. 11, and WindEurope, op. cit. note 23, p. 10.
105 Based on data from WindEurope, op. cit. note 6, p. 11. France added
1,318 MW (net 1,303 MW) for a total of 17,949 MW, Italy added 137
MW for a total of 10,852 MW, and Sweden added 1,007 MW for
a total of 9,992 MW, from WindEurope, op. cit. note 6, and from
Komusanac, op. cit. note 13.
106 The Netherlands added 486 MW onshore and 1,493 MW offshore
(total additions 1,979 MW) for a year-end total of 6,784 MW
(4,174 MW onshore and 2,611 MW offshore), from WindEurope,
op. cit. note 6, pp. 7, 11. In 2019, the country added 0.3 GW, from
Komusanac, op. cit. note 13. The Netherlands added nearly 2 GW
for a total of almost 6.6 GW, from GWEC, “Global Wind Statistics
2020”, op. cit. note 6.
107 WindEurope, op. cit. note 6, pp. 7, 11; P. Shreshtha,
“Ørsted fully commissions ‘largest’ Dutch offshore
wind farm”, Energy Live News, 1 December 2020,
https://www.energylivenews.com/2020/12/01/
orsted-fully-commissions-largest-dutch-offshore-wind-farm.
108 K. Chamberlain and R. Sayles, “Community wind set to
combat Europe's permit crisis”, Reuters Events, 26 August
2020, https://www.reutersevents.com/renewables/wind/
community-wind-set-combat-europes-permit-crisis.
109 Ibid. The Zeewolde project will have 322 MW of capacity, from
idem.
110 Ibid.
111 Ibid. Community-owned projects accounted for only a small
fraction of the country’s wind (and solar) power capacity in 2020,
but the Dutch government plans to require that all projects coming
online from 2030 be at least 50% locally owned, from idem.
112 Ranking in region and capacity data from WindEurope, op.
cit. note 6, p. 11, and from Komusanac, op. cit. note 13; global
ranking also based on data from GWEC, “Global Wind Statistics
2020”, op. cit. note 6. Spain added 1,720 MW in 2020 for a
total of 27,446 MW, from Asociación Empresarial Eólica (AEE),
cited in “Spain increases wind capacity by 1.7GW in 2020”,
reNEWS Biz, 24 February 2021, https://renews.biz/66696/
spain-increases-wind-capacity-by-172gw-in-2020.
113 Figure of 2.2 GW added in 2019, based on 2,243 MW from
Komusanac, op. cit. note 13, and from AEE, cited in “Spain
increases wind capacity by 1.7GW in 2020”, op. cit. note 112; other
data from GWEC, “Global Wind Statistics 2020”, op. cit. note
6; target is from the country’s 2030 National Energy & Climate
Plan, submitted to the EU, which called for annual installations
of 2.2 GW of wind power capacity up to 2030, from WindEurope,
“Spain submits ambitious 2030 National Plan – example for
other countries to follow”, 3 April 2020, https://windeurope.org/
newsroom/press-releases/spain-submits-ambitious-2030-
national-plan-example-for-other-countries-to-follow.
114 Watson Farley & Williams, “What you need to know about the
Spanish renewable sector’s first auction mechanism introduced
in 2021”, 17 December 2020, https://www.wfw.com/articles/what-
you-need-to-know-about-the-spanish-renewable-sectors-first-
auction-mechanism-introduced-in-2021.
115 REE, op. cit. note 15.
116 WindEurope, op. cit. note 6, p. 11; Komusanac, op. cit. note 13, 28
April 2021.
117 Germany added 1,650 MW gross (1,431 MW onshore and 219 MW
offshore) and decommissioned 222 MW for a total of 62,627 MW
(54,938 MW onshore and 7,689 MW offshore), from WindEurope,
op. cit. note 6, pp. 7, 11, 17. Germany’s additions in 2020 round up to
1.7 GW, from Komusanac, op. cit. note 13. Germany’s net increase
in capacity was 1,446 MW in 2020 (1,227 MW onshore and 219
MW offshore), for a year-end total of 62,167 MW (with 54,420 MW
onshore and 7,847 MW onshore), from BMWi and AGEE-Stat, op.
cit. note 15, p. 7. Germany added a gross of 1,668 MW (net 1,446
MW) for a total of 62,850 MW, from GWEC, “Global Wind Statistics
2020”, op. cit. note 6. WindEurope data are used in text to ensure
consistent methodology across all countries in Europe.
118 Additions in 2020 from WindEurope, op. cit. note 6, p. 11; additions
in 2019 from WindEurope, op. cit. note 23, p. 10; second lowest
based on data from S. Hermann, German Environment Agency,
personal communication with REN21, 13 April 2021; since 2010
from GWEC, “Global Wind Statistics 2020”, op. cit. note 6; shift
to tenders from Global Data, “Despite 46% growth in annual
installed onshore wind capacity in 2020, Germany still off-target,
says GlobalData”, 5 February 2021, https://www.globaldata.com/
despite-46-growth-annual-installed-onshore-wind-capacity-2020-
germany-still-off-target-says-globaldata.
119 Wind energy generated 103,662 GWh onshore and 27,303 GWh
offshore for a total of 130,965 GWh, and shares of national gross
electricity consumption were 18.7% for onshore wind and 4.9% for
offshore wind for a total of 23.6%, all from BMWI and AGEE-Stat,
op. cit. note 15, p. 46; increase of 4% based on these data as well
as numbers for 2019, from idem, p. 45. Surpassed lignite (92 TWh)
for second consecutive year, from Hermann, op. cit. note 118. Nearly
passed output of lignite and hard coal (43 TWh) combined, from
idem. Note that wind accounted for 24.6% of output; its share
increased due in part to a decline in overall electricity demand (and
production), based on data from Germany’s Federal Statistical
Office (Destatis), cited in “Renewables deliver 47% of Germany
power in 2020”, reNEWS Biz, 5 March 2021, https://renews.
biz/66943/renewables-deliver-47-of-germany-power-in-2020.
Wind surpassed coal for generation in Germany for first time in
2020, generating 25.6% of electricity fed into the grid, from N.
Weekes, “Wind beats coal to top spot in Germany’s electricity
supply”, Windpower Monthly, https://www.windpowermonthly.
com/article/1709227/wind-beats-coal-top-spot-germanys-
electricity-supply. Wind passed lignite and hard coal (118 TWh
combined), from D. Loy, Loy Energy Consulting, Germany, personal
communication with REN21, 12 April 2021.
120 Undersubscribed, including in 2020, from WindEurope, op. cit. note
6, p. 23. In Germany, only 2.7 GW of 3.9 GW on offer were awarded
because there were not enough projects permitted, from idem. See
also C. Richard, “Looking back on 2020 – Part 5: Politicians pledge
green post-Covid recovery”, Windpower Monthly, 19 January 2021,
https://www.windpowermonthly.com/article/1704283/looking-
back-2020-%E2%80%93-part-5-politicians-pledge-green-post-
covid-recovery; C. Richard, “German onshore wind reverses
trend with successful tender”, Windpower Monthly, 21 December
2020, https://www.windpowermonthly.com/article/1703315/
german-onshore-wind-reverses-trend-successful-tender. Complex
planning and local opposition from H. Schmitz, “New distance
rules for wind turbines”, Noerr, 26 August 2020, https://www.noerr.
com/en/newsroom/news/new-distance-rules-for-wind-turbines;
undersubscribed and lack of permitted projects from C. Richard,
“Government plans to speed up wind lawsuits”, Windpower
Monthly, September 2020, p. 19, https://www.windpowermonthly.
com/article/1692957/read-windpower-monthly-online. The lack of
permitted projects is due to lack of investors, with many small- to
medium-scale enterprises and community energy investors unable
to assume the risks of preparing for and participating in tenders;
in addition, well-connected opposition to wind power projects
has risen as Germany has transitioned away from the FIT, and the
number of local investors (and thus local proponents has declined)
as only relatively large-scale developers have been able to
participate, from Gsänger, op. cit. note 89, April and May 2021. See
also S. Gsänger, WWEA, presentation for “WWEA webinar: Wind
power and renewable energy policies: What is best to reach 100%
RE”, 7 May 2020, https://wwindea.org/wweawebinar-wind-power-
and-renewable-energy-policies-what-is-best-to-reach-100-re-14-
may. The decline in onshore wind energy installations in Germany
is due to switch from FITs to tenders, which brought about
dramatic decline in investment, from H-J. Fell, Energy Watch Group,
presentation for “WWEA webinar: Wind power and renewable
energy policies: What is best to reach 100% RE”, 7 May 2020,
https://wwindea.org/wweawebinar-wind-power-and-renewable-
energy-policies-what-is-best-to-reach-100-re-14-may. The volume
of tenders for onshore wind power in 2020 was 3,860 MW in seven
rounds; only about 68% of the tender volume awarded (2,672
MW). But participation was up from 2019, when only about half
was awarded, from Deutsche WindGuard, Status of Onshore Wind
Energy Development in Germany – Year 2020 (Varel: 2021), p. 8,
https://www.windguard.com/publications-wind-energy-statistics.
html. The December tender saw bidding for onshore wind exceed
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
offered capacity for first time in 2020, from A. Lee, “End of year
cheer for German onshore wind as tender bids overshoot for
first time in 2020”, Recharge, 21 December 2021, https://www.
rechargenews.com/wind/end-of-year-cheer-for-german-onshore-
wind-as-tender-bids-overshoot-for-first-time-in-2020/2-1-935048.
121 According to data from Germany’s wind industry association
Bundesverband WindEnergie e.V. (BWE), cited in Chamberlain and
Sayles, op. cit. note 108.
122 Richard, “German onshore wind reverses trend with successful
tender”, op. cit. note 120; new rules also from Schmitz, op. cit. note
120; WDR, “Neue Windrad-Abstandsregelung: Was macht NRW?”
19 May 2020, https://www1.wdr.de/nachrichten/landespolitik/
einigung-abstandregelung-windkraft-windrad-100.html.
123 Deutsche WindGuard, op. cit. note 120, p. 3; Global Data, op. cit.
note 118. The offshore target for 2030 was increased from 15 GW to
20 GW, with an additional target of 40 GW by 2040, from Deutsche
WindGuard, Status of Offshore Wind Energy Development in
Germany – Year 2020 (Varel: 2021), p. 4, https://www.windguard.
com/publications-wind-energy-statistics.html.
124 WindEurope, op. cit. note 6, p. 18. Wind energy generated an
estimated 417 TWh in the EU during the year, from WindEurope, op.
cit. note 23, p. 8.
125 Figure of 1.9 percentage points from Komusanac, op. cit. note
13; causes from WindEurope, op. cit. note 6, p. 18. See also
“Renewables achieve clean energy record as COVID-19 hits
demand”, Renewable Energy World, 6 April 2020, https://www.
renewableenergyworld.com/2020/04/06/renewables-achieve-
clean-energy-record-as-covid-19-hits-demand. Denmark,
Germany and Ireland each covered almost 50% of their electricity
demand with wind energy in February, due in part to volatile
weather and to the large COVID-related demand drop from early
February through March, which had the biggest impact on fossil
and nuclear generation, but also a general trend of increasing share
of wind capacity and generation, all from idem.
126 New Zealand added 103 MW of new capacity for a total of 793 MW,
from GWEC, “Global Wind Statistics 2020”, op. cit. note 6.
127 Australia added 1,097 MW for a total of 7,376 MW, from Clean Energy
Council, Clean Energy Australia Report 2021 (Melbourne: 2021),
pp. 84, 88, https://assets.cleanenergycouncil.org.au/documents/
resources/reports/clean-energy-australia/clean-energy-australia-
report-2021 . This was up from a record 837 MW installed in
2019 for a total of 6,279 MW, from idem, p. 88. By year’s end, more
than 21 projects were under construction or financially committed,
representing additional capacity totalling over 4 GW, from idem, p.
84. Australia added 1,097 MW for a total of 7,296 MW, from GWEC,
“Global Wind Statistics 2020”, op. cit. note 6.
128 Clean Energy Council, op. cit. note 127, pp. 45, 46, 49; figure of 41%
from Business Renewables Centre Australia, cited in idem, p. 49.
129 Clean Energy Council, op. cit. note 127, p. 89.
130 Wind power generated 22,605 TWh, accounting for 9.9% of Australia’s
total generation, from Ibid., p. 9. Increase over 2019 output based on
generation of 19.487 TWh in 2019, accounting for 8.5% of Australia’s
total generation, from Clean Energy Council, Clean Energy Australia
Report 2020 (Melbourne: 8 April 2020), pp. 6, 9, 79, 81, https://assets.
cleanenergycouncil.org.au/documents/resources/reports/clean-
energy-australia/clean-energy-australia-report-2020 .
131 Based on data from Green Energy Markets, cited in Clean Energy
Council, op. cit. note 127, p. 86. In 2019, the top three states/
territories for share of generation from wind energy were South
Australia (29.2%), Victoria (27.8%) and New South Wales (22.9%),
from Green Energy Markets, cited in Clean Energy Council, op. cit.
note 130, p. 80; shares in 2018 were South Australia (35%), Victoria
(28%) and New South Wales (19%), from Clean Energy Council, op.
cit. note 9, pp. 72-76. For more information, and different statistics,
for Victoria, see E. Ingram, “Australia’s Victoria doubles share of
wind in generation mix in four years”, 22 March 2021, https://www.
renewableenergyworld.com/wind-power/australias-victoria-
doubles-share-of-wind-in-generation-mix-in-four-years.
132 Clean Energy Council, op. cit. note 127, pp. 4-5, 8. Clean Energy
Council, op. cit. note 130, pp. 4, 7. See also Solar PV section in this
chapter for more on challenges in Australia. Australia is seeing
an increasing number of large-scale projects (both wind and
solar) that need connection to a 5,000-kilometre transmission
line that was built to carry electricity from coal plants near three
large mining areas, and not designed to carry electricity from
variable and remote wind and solar projects. Delays in project
approvals and grid connections are causing project delays
and unanticipated costs for developers who fail to account for
grid-related issues (e.g., congestion, curtailment), all from S.
Paul, “Australia’s solar, wind boom to power past grid woes in
2019”, Reuters, 20 January 2019, https://www.reuters.com/article/
us-australia-renewables-idUSKCN1PE0V8.
133 GWEC, “Africa is only tapping into 0.01% of its wind
power potential”, 4 March 2021, https://gwec.net/
africa-is-only-tapping-into-0-01-of-its-wind-power-potential.
134 South Africa installed 515 MW for a year-end total of 2,495 MW,
Senegal added 103.5 MW for a total of 158.7 MW and Morocco
added 92 MW for a total of 1,315 MW, all from GWEC, op. cit. note
133, and from GWEC, “Global Wind Statistics 2020”, op. cit. note
6. Senegal’s wind farm began providing electricity to the grid
in 2019 and was fully commissioned in 2020, from C. Richard,
“First power from first West African wind farm”, Windpower
Monthly, 12 December 2019, https://www.windpowermonthly.
com/article/1668654/first-power-first-west-african-wind-farm;
A. Frangoul, “West Africa’s first large-scale wind farm starts
generating power”, CNBC Sustainable Energy, 13 December 2019,
https://www.cnbc.com/2019/12/13/west-africas-first-large-scale-
wind-farm-starts-generating-power.html. Additional projects
in Morocco included a 210 MW wind farm in Midelt that began
operations in 2020, and construction starts for a 300 MW project
in Boujdour and an 87 MW project in Taza, from L. El Bouazzati,
Energy Policy Consultant, Morocco, personal communication with
REN21, 4 April 2021. There were several new wind farms in South
Africa; see, for example: B. Bungane, “Excelsior wind farm connects
to South Africa’s power grid”, ESI Africa, 17 September 2020,
https://www.esi-africa.com/industry-sectors/renewable-energy/
excelsior-wind-farm-connects-to-south-africas-power-grid; B.
Bungane, “SA’s Perdekraal East Wind Farm celebrates commercial
operations”, ESI Africa, 8 October 2020, https://www.esi-africa.
com/industry-sectors/renewable-energy/sas-perdekraal-east-
wind-farm-celebrates-commercial-operations; B. Bungane, “South
Africa: Kangnas Wind Farm kicks off operations”, ESI Africa, 16
November 2020, https://www.esi-africa.com/industry-sectors/
renewable-energy/south-africa-kangnas-wind-farm-kicks-off-
operations. The 140 MW Nxuba wind farm began commercial
operations in late December 2020 or the beginning of January
2021, from T. Smith, “Enel Green Power: Nxuba wind farm now
operational in Eastern Cape”, ESI Africa, 6 January 2021, https://
www.esi-africa.com/industry-sectors/generation/enel-green-
power-nxuba-wind-farm-now-operational-in-eastern-cape.
135 Jordan installed 52 MW (including 7 MW reported by GE and the
45 MW Shoubak project) for a total of 527 MW, Iran added 45 MW
for a total of 247 MW, Egypt added 13 MW for a total of 1,465 MW,
and Tanzania added its first wind project, from GWEC, op. cit. note
133, from GWEC, “Global Wind Statistics 2020”, op. cit. note 6, and
from Zhao, op. cit. note 7, 27 April 2021. Tanzania’s first wind farm, a
2.4 MW project, was connected to a regional grid to compensate for
low water levels during the dry season that reduce output of the local
hydropower plant, from Future Power Technology, op. cit. note 7.
136 Numbers of countries by region based on data from GWEC, “Global
Wind Statistics 2020”, op. cit. note 6; cumulative combined capacities
in the regions, and in South Africa, Egypt and Morocco, all from idem,
from GWEC, op. cit. note 133, and from GWEC, op. cit. note 1, p. 53.
137 Diversify energy mix from, for example: Future Power Technology,
op. cit. note 7; T. Smith, “How Egypt banks on renewables to meet
likely energy demand surge”, ESI Africa, 16 July 2020, https://www.
esi-africa.com/industry-sectors/renewable-energy/how-egypt-
banks-on-renewables-to-meet-likely-energy-demand-surge; T.
Smith, “Wind plans for Ghana gaining momentum”, ESI Africa,
21 July 2020, https://www.esi-africa.com/industry-sectors/
renewable-energy/wind-plans-for-ghana-gaining-momentum; and
(in Mozambique) GWEC, op. cit. note 1, p. 65. Lower costs and meet
rising demand from, for example: Smith, “How Egypt banks on
renewables to meet likely energy demand surge”, op. cit. this note.
Reduce reliance on imports from, for example: B. Bungane, “MIGA
supports Djibouti’s first utility-scale wind project”, ESI Africa, 6 May
2020, https://www.esi-africa.com/industry-sectors/renewable-
energy/miga-supports-djiboutis-first-utility-scale-wind-project;
B. Bungane, “Siemens Gamesa lands contract to build Djibouti’s
first wind farm”, ESI Africa, 26 February 2020, https://www.
esi-africa.com/industry-sectors/generation/siemens-gamesa-
lands-contract-to-build-djiboutis-first-wind-farm; Smith, “Wind
plans for Ghana gaining momentum”, op. cit. this note. Free up oil
and gas for export from, for example, Smith, “How Egypt banks on
renewables to meet likely energy demand surge”, op. cit. this note.
334
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https://www.esi-africa.com/industry-sectors/renewable-energy/excelsior-wind-farm-connects-to-south-africas-power-grid
https://www.esi-africa.com/industry-sectors/renewable-energy/sas-perdekraal-east-wind-farm-celebrates-commercial-operations
https://www.esi-africa.com/industry-sectors/renewable-energy/sas-perdekraal-east-wind-farm-celebrates-commercial-operations
https://www.esi-africa.com/industry-sectors/renewable-energy/sas-perdekraal-east-wind-farm-celebrates-commercial-operations
https://www.esi-africa.com/industry-sectors/renewable-energy/south-africa-kangnas-wind-farm-kicks-off-operations
https://www.esi-africa.com/industry-sectors/renewable-energy/south-africa-kangnas-wind-farm-kicks-off-operations
https://www.esi-africa.com/industry-sectors/renewable-energy/south-africa-kangnas-wind-farm-kicks-off-operations
https://www.esi-africa.com/industry-sectors/generation/enel-green-power-nxuba-wind-farm-now-operational-in-eastern-cape
https://www.esi-africa.com/industry-sectors/generation/enel-green-power-nxuba-wind-farm-now-operational-in-eastern-cape
https://www.esi-africa.com/industry-sectors/generation/enel-green-power-nxuba-wind-farm-now-operational-in-eastern-cape
https://www.esi-africa.com/industry-sectors/renewable-energy/how-egypt-banks-on-renewables-to-meet-likely-energy-demand-surge
https://www.esi-africa.com/industry-sectors/renewable-energy/how-egypt-banks-on-renewables-to-meet-likely-energy-demand-surge
https://www.esi-africa.com/industry-sectors/renewable-energy/how-egypt-banks-on-renewables-to-meet-likely-energy-demand-surge
https://www.esi-africa.com/industry-sectors/renewable-energy/wind-plans-for-ghana-gaining-momentum
https://www.esi-africa.com/industry-sectors/renewable-energy/wind-plans-for-ghana-gaining-momentum
https://www.esi-africa.com/industry-sectors/renewable-energy/miga-supports-djiboutis-first-utility-scale-wind-project
https://www.esi-africa.com/industry-sectors/renewable-energy/miga-supports-djiboutis-first-utility-scale-wind-project
https://www.esi-africa.com/industry-sectors/generation/siemens-gamesa-lands-contract-to-build-djiboutis-first-wind-farm
https://www.esi-africa.com/industry-sectors/generation/siemens-gamesa-lands-contract-to-build-djiboutis-first-wind-farm
https://www.esi-africa.com/industry-sectors/generation/siemens-gamesa-lands-contract-to-build-djiboutis-first-wind-farm
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
138 Bungane, “MIGA supports Djibouti’s first utility-scale wind project”,
op. cit. note 137; Bungane, “Siemens Gamesa lands contract to
build Djibouti’s first wind farm”, op. cit. note 137; Smith, “Wind plans
for Ghana gaining momentum”, op. cit. note 137.
139 GWEC, op. cit. note 133; “Barriers to foreign Investment”, in Future
Power Technology, op. cit. note 7; GWEC, “Africa and Middle East
add 894MW of wind energy capacity in 2019, market expected to
grow by over 10GW by 2024”, 12 February 2020, https://gwec.net/
africa-and-middle-east-add-894mw-of-wind-energy-capacity-in-
2019-market-expected-to-grow-by-over-10gw-by-2024. See also
IEA, op. cit. note 54.
140 Based on data from GWEC, “China installed half of new global
offshore wind capacity during 2020 in record year”, 25 February
2021, https://gwec.net/china-installed-half-of-new-global-offshore-
wind-capacity-during-2020-in-record-year, from WindEurope,
op. cit. note 6, p. 11, from GWEC, “Global Wind Statistics 2020”,
op. cit. note 6, and from Yu, op. cit. note 25. Note that GWEC
has a figure of 24,837 MW for all of Europe, from idem, whereas
Europe had a total 25,013 MW of offshore wind power capacity
in operation at end-2020, from WindEurope, op. cit. note 6, pp. 11,
17. An estimated 5.2 GW (including only those projects with entire
capacity in operation) was added to grids around the world in 2020,
from World Forum Offshore Wind, Global Offshore Wind Report
2020, cited in A. McCorkell, “WFO: Record growth for offshore
wind in 2020 despite Covid-19”, Windpower Monthly, 9 February
2021, https://www.windpowermonthly.com/article/1706847/
wfo-record-growth-offshore-wind-2020-despite-covid-19.
141 Figures for 2020 based on data from GWEC, op. cit. note 1, p.
53; less than 5% of capacity in 2019 based on data from GWEC,
“Global Wind Statistics 2019”, op. cit. note 7; 10% of global
installations in 2019 from GWEC, “Record 6.1 GW of new offshore
wind capacity installed globally in 2019”, 19 March 2019, https://
gwec.net/record-6-1-gw-of-new-offshore-wind-capacity-installed-
globally-in-2019. Offshore accounted for 12% of commissioned
wind power capacity in 2019, up from 8% in 2018, from C. Richard,
“Vestas leads the pack with squeezed market share”, Windpower
Monthly, 18 February 2020, https://www.windpowermonthly.com/
article/1674420/vestas-leads-pack-squeezed-market-share.
142 GWEC, op. cit. note 140.
143 China added 3.1 GW for a total of 10.13 GW (preliminary estimates),
from Yu, op. cit. note 25, and added 3,060 MW for a total of 9,996
MW, from GWEC, op. cit. note 1, p. 53.
144 GWEC, op. cit. note 1, p. 49; “China’s offshore
wind energy industry post-2021”, reve, 22 October
2020, https://www.evwind.es/2020/10/22/
chinas-offshore-wind-energy-industry-post-2021/77839.
145 GWEC, op. cit. note 140; GWEC, op. cit. note 1, p. 49. China’s offshore
projects must be grid-connected before end of 2021 to qualify for the
RMB 0.85 per kWh FIT, from GWEC, op. cit. note 1, p. 49.
146 The three provinces were home to nearly 85% of China’s offshore
capacity at the end of 2020, based on data from CWEA, “The
potential of China offshore wind market and Sino-Norwegian
Cooperation”, presentation, April 2021, slide 4; 81% from GWEC,
“Global Offshore Wind Project Database CY2020” (forthcoming),
provided by Zhao, op. cit. note 7, 27 April 2021.
147 Provincial level targets include: Guangdong 30 GW by 2030,
Jiangsu 15 GW, Zhejiang 6.5 GW, Fujian 5 GW, Shandong 3 GW;
there are also development plans in other coastal provinces,
from GWEC, op. cit. note 3, pp. 52-53. In addition, Guangdong
is targeting cumulative offshore wind capacity of 15 GW by the
end of 2025, from GWEC, op. cit. note 1, pp. 23-24, and from
Polaris Wind Power Network News, “Guangdong Province will
issue relevant policies to support the development of offshore
wind power”, 29 September 2020, https://news.bjx.com.cn/
html/20200929/1107950.shtml (using Google Translate). Shandong
set increased targets to install nearly 20 GW of offshore capacity
by 2035, from Y. Yu, “Shandong eyes 20GW to join China’s
offshore wind top-table”, Recharge, 17 July 2020, https://www.
rechargenews.com/wind/shandong-eyes-20gw-to-join-chinas-
offshore-wind-top-table/2-1-844813.
148 Republic of Korea from GWEC, op. cit. note 140. Japan’s first
offshore wind auction was launched in June 2020, and the country
launched its first auction in July for a floating wind farm that must
be at least 16.8 MW, from GWEC, op. cit. note 3, pp. 58, 59. Chinese
Taipei from B. Chuang and A. Hwang, “Taiwan becoming Asian
hub of offshore wind farms”, Digitimes, 15 January 2021, https://
www.digitimes.com/news/a20210113PD210.html. Chinese Taipei’s
capacity includes the 109 MW Changhua Domo and the 640 MW
Yulin offshore projects, which began construction offshore in 2020;
including offshore projects that began work but only onshore, the
total recorded was 2,634 MW under construction at end-2020,
from Zhao, op. cit. note 7, 27 April 2021.
149 The Republic of Korea targets 9.2 GW by 2025 and 16 GW by 2030,
with 12 GW of this from offshore wind, from GWEC, op. cit. note 1, p.
26. Complex terrain, turbulent winds and strong incumbents (both
coal in the energy sector and the fishing industry in the marine sector)
make the Republic of Korea a challenging market, from GWEC, op.
cit. note 3, p. 66. Japan targets are based on approved projects under
the current feed-in tariff and will require that at least 60% of project
equipment be sourced from domestic suppliers, from I-Ching Tseng,
“Japan plans 45GW offshore wind power by 2040”, Pinsent Mason,
23 December 2020, https://www.pinsentmasons.com/out-law/news/
japan-plans-45gw-offshore-wind-power-by-2040, and from Public-
Private Council on Enhancement of Industrial Competitiveness for
Offshore Wind Power Generation, Vision for Offshore Wind Power
Industry (1st) (Tokyo: 15 December 2020), pp. 6, 10, https://www.meti.
go.jp/shingikai/energy_environment/yojo_furyoku/pdf/002_02_
e02_01 .
150 J. S. Hill, “Ørsted signs world’s largest corporate renewable PPA
in Taiwan”, RenewEconomy, 9 July 2020, https://reneweconomy.
com.au/orsted-signs-worlds-largest-corporate-renewable-ppa-
in-taiwan-38136; J. Parnell, “Microchip giant TSMC signs ‘world’s
largest’ corporate renewables deal — for offshore wind”, Greentech
Media, 8 July 2020, https://www.greentechmedia.com/articles/
read/orsted-signs-worlds-largest-corporate-ppa. TSMC (Chinese
Taipei), the world’s largest semiconductor manufacturer and
supplier to Apple, signed the PPA with developer Ørsted, from Hill,
op. cit. this note.
151 Parnell, op. cit. note 150; J. Parnell, “What offshore wind can
bring to the corporate PPA party”, Greentech Media, 1 June
2020, https://www.greentechmedia.com/articles/read/
what-offshore-wind-can-bring-to-the-corporate-ppa-party.
152 WindEurope, Offshore Wind in Europe – Key Trends and Statistics
2020 (Brussels: February 2021), p. 7, https://windeurope.org/
data-and-analysis/product/offshore-wind-in-europe-key-trends-
and-statistics-2020. See also Parnell, op. cit. note 150; Parnell, op.
cit. note 151.
153 WindEurope, op. cit. note 152, p. 34.
154 Europe added 2,918 MW for a total of 25,013 MW, and no offshore
capacity was decommissioned during the year, fromWindEurope,
op. cit. note 6, pp. 11, 17; down 20% from WindEurope, op. cit. note
152, p. 9. At the end of 2020, Europe had a total of 5,402 grid-
connected turbines in 116 offshore wind farms, including some with
partial grid connection) across 12 countries, from WindEurope, op.
cit. note 152, pp. 7, 9.
155 The Netherlands added 1,493 MW for a total of 2,611 MW, Belgium
added 706 MW for a total of 2,261 MW, the United Kingdom added
483 MW for a total of 10,428 MW, Germany added 219 MW for a
total of 7,689 MW and Portugal added 17 MW for a total of 25 MW,
all from WindEurope, op. cit. note 6, p. 11. See also WindEurope, op.
cit. note 152, p. 10. Data from GWEC are similar with the exceptions
of the United Kingdom (483 MW added for total of 10,206 MW)
and Germany (237 MW added for total of 7,728 MW), from GWEC,
“Global Wind Statistics 2020”, op. cit. note 6.
156 The UK pipeline totalled more than 41 GW by early 2021, from
GWEC, op. cit. note 1, p. 30. The UK slowdown was a result of time
between the Contracts for Difference rounds 1 and 2, from GWEC,
op. cit. note 140.
157 Lowest in nearly a decade from WindEurope, op. cit. note 152, p.
11; no projects under construction from Deutsche WindGuard,
op. cit. note 123, p. 3; all planned projects had been installed from
Hermann, op. cit. note 118. Germany’s offshore wind tenders in
2017 and 2018 had a long period of time before commissioning
deadlines, which caused a gap in projects due to the shift from
administrative tariffs to auctions, from Komusanac, op. cit. note 13.
New law and offshore tender volumes from Die Bundesregierung,
“Mehr Rückenwind für den Strom – auch seitens der EU”, 22
January 2021, https://www.bundesregierung.de/breg-de/themen/
klimaschutz/fuer-mehr-windenergie-auf-see-1757176, viewed 27
April 2021. See also BMWi, “Altmaier: ‘Deutschland baut seine
Vorreiterrolle im Bereich Windenergie auf See weiter aus’”, 9
December 2020, https://www.bmwi.de/Redaktion/DE/Pressemi
tteilungen/2020/12/20201209-altmaier-deutschland-baut-seine-
vorreiterrolle-im-bereich-windenergie-auf-see-weiter-aus.html.
335
https://gwec.net/africa-and-middle-east-add-894mw-of-wind-energy-capacity-in-2019-market-expected-to-grow-by-over-10gw-by-2024
https://gwec.net/africa-and-middle-east-add-894mw-of-wind-energy-capacity-in-2019-market-expected-to-grow-by-over-10gw-by-2024
https://gwec.net/africa-and-middle-east-add-894mw-of-wind-energy-capacity-in-2019-market-expected-to-grow-by-over-10gw-by-2024
https://gwec.net/china-installed-half-of-new-global-offshore-wind-capacity-during-2020-in-record-year
https://gwec.net/china-installed-half-of-new-global-offshore-wind-capacity-during-2020-in-record-year
https://www.windpowermonthly.com/article/1706847/wfo-record-growth-offshore-wind-2020-despite-covid-19
https://www.windpowermonthly.com/article/1706847/wfo-record-growth-offshore-wind-2020-despite-covid-19
https://gwec.net/record-6-1-gw-of-new-offshore-wind-capacity-installed-globally-in-2019
https://gwec.net/record-6-1-gw-of-new-offshore-wind-capacity-installed-globally-in-2019
https://gwec.net/record-6-1-gw-of-new-offshore-wind-capacity-installed-globally-in-2019
https://www.windpowermonthly.com/article/1674420/vestas-leads-pack-squeezed-market-share
https://www.windpowermonthly.com/article/1674420/vestas-leads-pack-squeezed-market-share
https://www.evwind.es/2020/10/22/chinas-offshore-wind-energy-industry-post-2021/77839
https://www.evwind.es/2020/10/22/chinas-offshore-wind-energy-industry-post-2021/77839
https://news.bjx.com.cn/html/20200929/1107950.shtml
https://news.bjx.com.cn/html/20200929/1107950.shtml
https://www.rechargenews.com/wind/shandong-eyes-20gw-to-join-chinas-offshore-wind-top-table/2-1-844813
https://www.rechargenews.com/wind/shandong-eyes-20gw-to-join-chinas-offshore-wind-top-table/2-1-844813
https://www.rechargenews.com/wind/shandong-eyes-20gw-to-join-chinas-offshore-wind-top-table/2-1-844813
https://www.digitimes.com/news/a20210113PD210.html
https://www.digitimes.com/news/a20210113PD210.html
https://www.pinsentmasons.com/out-law/news/japan-plans-45gw-offshore-wind-power-by-2040
https://www.pinsentmasons.com/out-law/news/japan-plans-45gw-offshore-wind-power-by-2040
https://www.meti.go.jp/shingikai/energy_environment/yojo_furyoku/pdf/002_02_e02_01
https://www.meti.go.jp/shingikai/energy_environment/yojo_furyoku/pdf/002_02_e02_01
https://www.meti.go.jp/shingikai/energy_environment/yojo_furyoku/pdf/002_02_e02_01
https://reneweconomy.com.au/orsted-signs-worlds-largest-corporate-renewable-ppa-in-taiwan-38136
https://reneweconomy.com.au/orsted-signs-worlds-largest-corporate-renewable-ppa-in-taiwan-38136
https://reneweconomy.com.au/orsted-signs-worlds-largest-corporate-renewable-ppa-in-taiwan-38136
https://www.greentechmedia.com/articles/read/orsted-signs-worlds-largest-corporate-ppa
https://www.greentechmedia.com/articles/read/orsted-signs-worlds-largest-corporate-ppa
https://www.greentechmedia.com/articles/read/what-offshore-wind-can-bring-to-the-corporate-ppa-party
https://www.greentechmedia.com/articles/read/what-offshore-wind-can-bring-to-the-corporate-ppa-party
https://windeurope.org/data-and-analysis/product/offshore-wind-in-europe-key-trends-and-statistics-2020
https://windeurope.org/data-and-analysis/product/offshore-wind-in-europe-key-trends-and-statistics-2020
https://windeurope.org/data-and-analysis/product/offshore-wind-in-europe-key-trends-and-statistics-2020
https://www.bundesregierung.de/breg-de/themen/klimaschutz/fuer-mehr-windenergie-auf-see-1757176
https://www.bundesregierung.de/breg-de/themen/klimaschutz/fuer-mehr-windenergie-auf-see-1757176
https://www.bmwi.de/Redaktion/DE/Pressemitteilungen/2020/12/20201209-altmaier-deutschland-baut-seine-vorreiterrolle-im-bereich-windenergie-auf-see-weiter-aus.html
https://www.bmwi.de/Redaktion/DE/Pressemitteilungen/2020/12/20201209-altmaier-deutschland-baut-seine-vorreiterrolle-im-bereich-windenergie-auf-see-weiter-aus.html
https://www.bmwi.de/Redaktion/DE/Pressemitteilungen/2020/12/20201209-altmaier-deutschland-baut-seine-vorreiterrolle-im-bereich-windenergie-auf-see-weiter-aus.html
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
158 WindEurope, op. cit. note 152, p. 11.
159 Figure of 62 MW (83% of the global total) and pipeline, from
WindEurope, op. cit. note 152, pp. 20, 21. The Windfloat Atlantic
project has a total of 25 MW; in Scotland, the 50 MW Kincardine
project, which will use five 9.5 MW floating turbines, was under
construction in 2020, from idem.
160 WindEurope, op. cit. note 152, pp. 7, 14. The other countries with
offshore capacity are Sweden, Finland, Ireland, Portugal, Spain,
Norway and France, from idem.
161 Ibid., pp. 6-7, 32-33. The total includes EUR 2.1 billion (USD 2.58
billion) in offshore transmission infrastructure, from Komusanac, op.
cit. note 13.
162 United Kingdom from Government of the UK, “New plans to
make UK world leader in green energy”, 6 October 2020, https://
www.gov.uk/government/news/new-plans-to-make-uk-world-
leader-in-green-energy; C. Richard, “UK’s 40GW offshore wind
target under pressure after leasing round delay”, Windpower
Monthly, 15 October 2020, https://www.windpowermonthly.com/
article/1697347/uks-40gw-offshore-wind-target-pressure-leasing-
round-delay. Germany from Deutsche WindGuard, op. cit. note
123, p. 4, from D. Foxwell, “Germany agrees big boost to offshore
wind capacity”, Riviera, 12 May 2020, https://www.rivieramm.com/
news-content-hub/news-content-hub/germany-agrees-big-boost-
to-offshore-wind-and-green-hydrogen-plan-59322, and from V.
Petrova, “German Cabinet okays 40 GW offshore wind target”,
Renewables Now, 4 June 2020, https://renewablesnow.com/
news/german-cabinet-okays-40-gw-offshore-wind-target-701416.
Germany also set a target of 40 GW by 2040, from Deutsche
WindGuard, op. cit. note 123. Other target-related developments
in 2020 include: France increased its offshore wind tender goal
for 2028 from 4.7-5.2 GW up to 8.75 GW, and aims for 2.4 GW
with targeted commissioning by 2023, and for 5.2-6.2 GW to be
operational by 2028, from “France to become Europe’s fourth-
largest offshore wind producer in 2030”, Offshore Source, 6
May 2020, https://www.offshoresource.com/news/renewables/
france-to-become-europe-s-fourth-largest-offshore-wind-
producer-in-2030.
163 WindEurope, op. cit. note 152, p. 35. As of late 2020, the EU planned
to aim for at least 60 GW of offshore capacity by 2030 and 300
GW by 2050, from A. Frangoul, “Europe is planning a 25-fold
increase in offshore wind capacity by 2050”, CNBC, 19 November
2020, https://www.cnbc.com/2020/11/19/europe-plans-25-fold-
increase-in-offshore-wind-capacity-by-2050.html. Note that
this target could include Turkey; Turkey’s Energy and Natural
Resources Ministry has a strategic plan that envisages 10 GW of
offshore wind projects over the coming years, from Daily Sabah,
“Turkey holds 75 gigawatts of offshore wind energy potential”,
19 April 2021, https://www.dailysabah.com/business/energy/
turkey-holds-75-gigawatts-of-offshore-wind-energy-potential.
164 US states with targets as of late 2020 included: Maryland (1.2
GW by 2030), Connecticut (2 GW by 2030), Virginia (5.2 GW
by 2034), Massachusetts (3.2 GW by 2035), New Jersey (7.5
GW by 2035) and New York (2.4 GW by 2030 and 9 GW by
2035), from GWEC, op. cit. note 3, p. 21. See also T. Casey,
“Empire State blows past offshore wind limit with 1,000 (more)
MW”, CleanTechnica, 24 April 2020, https://cleantechnica.
com/2020/04/24/empire-state-blows-past-offshore-wind-limit-
with-1000-more-mw, and K. Stromsta, “Second US offshore wind
project finishes construction off Virginia”, Greentech Media, 29
June 2020, https://www.greentechmedia.com/articles/read/
second-us-offshore-wind-farm-finishes-construction-off-virginia.
165 W. Musial et al., 2019 Offshore Wind Technology Data Update (Golden,
CO: National Renewable Energy Laboratory (NREL), October 2020),
pp. 18, 22, https://www.nrel.gov/docs/fy21osti/77411 .
166 ACPA, U.S. Offshore Wind Industry: Status Update 2021
(Washington, DC: 2021), p. 1, https://cleanpower.org/wp-content/
uploads/2021/02/ACP_FactSheet-Offshore_Final ; GWEC,
op. cit. note 3, pp. 21, 53; Musial et al., op. cit. note 165, p. 23.
Another project (2.6 GW) was planned for the adjacent site, with
construction scheduled to start in 2024, from Stromsta, op. cit. note
164, and from Broehl, op. cit. note 70.
167 New York from Musial et al., op. cit. note 165, p. 19, and from
“New York launches renewable energy solicitations for 4GW
capacity”, NS Energy Business, 22 July 2020, https://www.
nsenergybusiness.com/news/new-york-state-renewable-energy-
solicitations. The winner of two additional contracts (Equinor)
for this 2.5 GW was announced in January 2021, from N. Greene,
“In 2021 it’s off to the races for offshore wind”, Natural Resources
Defense Council, 22 January 2021, https://www.nrdc.org/experts/
nathanael-greene/2021-its-races-offshore-wind. Rhode Island and
Massachusetts from ACPA, op. cit. note 58, p. 16. Icebreaker on
Lake Erie from K. M. Kowalski, “Ohio regulators OK Lake Erie wind
farm with ‘poison pill’ that may kill project”, Energy News Network,
21 May 2020, https://energynews.us/2020/05/21/midwest/ohio-
regulators-ok-lake-erie-wind-farm-with-poison-pill-that-may-kill-
project; K. Stromsta, “‘This could be final nail in coffin’ for Icebreaker
offshore wind project”, Greentech Media, 22 May 2020, https://
www.greentechmedia.com/articles/read/final-nail-in-coffin-for-
icebreaker-first-offshore-wind-project-in-great-lakes; J. Pelzer, “Plans
for Lake Erie wind farm clear a major hurdle, as ‘poison pill’ restriction
is lifted”, MSN, 17 September 2020, https://www.msn.com/en-us/
news/us/plans-for-lake-erie-wind-farm-clear-a-major-hurdle-as-
poison-pill-restriction-is-lifted/ar-BB199xys. Louisiana from Office of
the Governor, “Gov. Edwards announces renewable energy initiative
for Gulf of Mexico”, 9 November 2020, https://gov.louisiana.gov/
index.cfm/newsroom/detail/2790.
168 J. Partlow, “Interior Department approves first large-scale offshore
wind farm in the U.S.”, Washington Post, 11 May 2021, https://www.
washingtonpost.com/nation/2021/05/11/interior-department-
approves-first-large-scale-offshore-wind-farm-us.
169 Total of 18 includes Germany, Spain, the United Kingdom, France,
Sweden, Denmark, the Netherlands, Ireland, Belgium, Norway,
Finland and Portugal in Europe, from WindEurope, op. cit. note 6,
and same countries in 2019, from WindEurope, Offshore Wind in
Europe: Key Trends and Statistics 2019 (Brussels: February 2020), p.
7, https://windeurope.org/wp-content/uploads/files/about-wind/
statistics/WindEurope-Annual-Offshore-Statistics-2019 ; China,
Japan, Chinese Taipei, the Republic of Korea and Vietnam in Asia;
and the United States, all based on data from GWEC, “Global Wind
Statistics 2020”, op. cit. note 6.
170 WindEurope, op. cit. note 6, p. 11; GWEC, op. cit. note 1, p. 53;
GWEC, “Global Wind Statistics 2020”, op. cit. note 6; Yu, op. cit.
note 25. Note that data for Europe from GWEC and WindEurope
are similar with the exceptions of the United Kingdom, for which
GWEC has 10,206 MW and WindEurope has 10,428 MW, and
Germany, for which GWEC has 7,728 MW and WindEurope has
7,689 MW, from GWEC, op. cit. this note.
171 Europe share in 2020 based on data from GWEC, op. cit. note
1, p. 53, from WindEurope, op. cit. note 6, p. 11, and from Yu, op.
cit. note 25. Europe home to 75% in 2019, based on data from
GWEC, “Webcast on wind: Market update and outlook for global
offshore wind”, 19 March 2020; figures of 79% in 2018, down
from 84% in 2017 and 88% in 2016, based on data from GWEC,
Global Wind Report 2018, op. cit. note 7. Figure 36 based on
data from the following: GWEC, “Global Wind Statistics 2020”,
op. cit. note 6; GWEC, op. cit. note 1, p. 52; WindEurope, op. cit.
note 6, p. 11; WindEurope, op. cit. note 169, pp. 7, 8; WindEurope,
Offshore Wind in Europe – Key Trends and Statistics 2017 (Brussels:
February 2018), p. 6, https://windeurope.org/wp-content/uploads/
files/about-wind/statistics/WindEurope-Annual-Offshore-
Statistics-2017 ; WindEurope, The European Offshore Wind
Industry – Key Trends and Statistics 2016 (Brussels: January 2017),
p. 17, https://windeurope.org/wp-content/uploads/files/about-
wind/statistics/WindEurope-Annual-Offshore-Statistics-2016 ;
Yu, op. cit. note 25; ACPA, op. cit. note 166, p. 1; AWEA, “First US
offshore wind farm unlocks vast new ocean energy resource”, press
release (Block Island, RI: 12 December 2016), http://www.awea.
org/MediaCenter/pressreleasev2.aspx?ItemNumber=9627.
172 Musial et al., op. cit. note 165, p. 30. As of late 2020, the global
offshore pipeline was 230,174 MW, including 27,064 MW in
operation and 81,872 MW approved through regulatory processes,
reached financial close, or under construction, and 203,110 MW
announced, from idem.
173 G. Dixon, “$51bn in wind farm capital spending outstrips oil and
gas for first time”, TradeWinds, 2 February 2021, https://www.
tradewindsnews.com/offshore/-51bn-in-wind-farm-capital-
spending-outstrips-oil-and-gas-for-first-time/2-1-955552, cited in
GWEC, op. cit. note 1, p. 9.
174 Total and number of countries based on data from GWEC, “Global
Wind Statistics 2020”, op. cit. note 6.
175 WindEurope, op. cit. note 6, p. 17. For Belgium, France, Luxembourg
and the United Kingdom, decommissioned capacity amounted
to 25 MW, 15 MW, 2 MW and 0.3 MW respectively, from
idem. A total of 388 MW was fully decommissioned across
Europe in 2020, from WindEurope, “WindEurope Bulletin CEO
336
https://www.gov.uk/government/news/new-plans-to-make-uk-world-leader-in-green-energy
https://www.gov.uk/government/news/new-plans-to-make-uk-world-leader-in-green-energy
https://www.gov.uk/government/news/new-plans-to-make-uk-world-leader-in-green-energy
https://www.windpowermonthly.com/article/1697347/uks-40gw-offshore-wind-target-pressure-leasing-round-delay
https://www.windpowermonthly.com/article/1697347/uks-40gw-offshore-wind-target-pressure-leasing-round-delay
https://www.windpowermonthly.com/article/1697347/uks-40gw-offshore-wind-target-pressure-leasing-round-delay
https://www.rivieramm.com/news-content-hub/news-content-hub/germany-agrees-big-boost-to-offshore-wind-and-green-hydrogen-plan-59322
https://www.rivieramm.com/news-content-hub/news-content-hub/germany-agrees-big-boost-to-offshore-wind-and-green-hydrogen-plan-59322
https://www.rivieramm.com/news-content-hub/news-content-hub/germany-agrees-big-boost-to-offshore-wind-and-green-hydrogen-plan-59322
https://renewablesnow.com/news/german-cabinet-okays-40-gw-offshore-wind-target-701416
https://renewablesnow.com/news/german-cabinet-okays-40-gw-offshore-wind-target-701416
https://www.offshoresource.com/news/renewables/france-to-become-europe-s-fourth-largest-offshore-wind-producer-in-2030
https://www.offshoresource.com/news/renewables/france-to-become-europe-s-fourth-largest-offshore-wind-producer-in-2030
https://www.offshoresource.com/news/renewables/france-to-become-europe-s-fourth-largest-offshore-wind-producer-in-2030
https://www.cnbc.com/2020/11/19/europe-plans-25-fold-increase-in-offshore-wind-capacity-by-2050.html
https://www.cnbc.com/2020/11/19/europe-plans-25-fold-increase-in-offshore-wind-capacity-by-2050.html
https://www.dailysabah.com/business/energy/turkey-holds-75-gigawatts-of-offshore-wind-energy-potential
https://www.dailysabah.com/business/energy/turkey-holds-75-gigawatts-of-offshore-wind-energy-potential
https://cleantechnica.com/2020/04/24/empire-state-blows-past-offshore-wind-limit-with-1000-more-mw
https://cleantechnica.com/2020/04/24/empire-state-blows-past-offshore-wind-limit-with-1000-more-mw
https://cleantechnica.com/2020/04/24/empire-state-blows-past-offshore-wind-limit-with-1000-more-mw
https://www.greentechmedia.com/articles/read/second-us-offshore-wind-farm-finishes-construction-off-virginia
https://www.greentechmedia.com/articles/read/second-us-offshore-wind-farm-finishes-construction-off-virginia
https://www.nrel.gov/docs/fy21osti/77411
https://cleanpower.org/wp-content/uploads/2021/02/ACP_FactSheet-Offshore_Final
https://cleanpower.org/wp-content/uploads/2021/02/ACP_FactSheet-Offshore_Final
https://www.nsenergybusiness.com/news/new-york-state-renewable-energy-solicitations
https://www.nsenergybusiness.com/news/new-york-state-renewable-energy-solicitations
https://www.nsenergybusiness.com/news/new-york-state-renewable-energy-solicitations
https://www.nrdc.org/experts/nathanael-greene/2021-its-races-offshore-wind
https://www.nrdc.org/experts/nathanael-greene/2021-its-races-offshore-wind
https://energynews.us/2020/05/21/midwest/ohio-regulators-ok-lake-erie-wind-farm-with-poison-pill-that-may-kill-project
https://energynews.us/2020/05/21/midwest/ohio-regulators-ok-lake-erie-wind-farm-with-poison-pill-that-may-kill-project
https://energynews.us/2020/05/21/midwest/ohio-regulators-ok-lake-erie-wind-farm-with-poison-pill-that-may-kill-project
https://www.greentechmedia.com/articles/read/final-nail-in-coffin-for-icebreaker-first-offshore-wind-project-in-great-lakes
https://www.greentechmedia.com/articles/read/final-nail-in-coffin-for-icebreaker-first-offshore-wind-project-in-great-lakes
https://www.greentechmedia.com/articles/read/final-nail-in-coffin-for-icebreaker-first-offshore-wind-project-in-great-lakes
https://www.msn.com/en-us/news/us/plans-for-lake-erie-wind-farm-clear-a-major-hurdle-as-poison-pill-restriction-is-lifted/ar-BB199xys
https://www.msn.com/en-us/news/us/plans-for-lake-erie-wind-farm-clear-a-major-hurdle-as-poison-pill-restriction-is-lifted/ar-BB199xys
https://www.msn.com/en-us/news/us/plans-for-lake-erie-wind-farm-clear-a-major-hurdle-as-poison-pill-restriction-is-lifted/ar-BB199xys
https://gov.louisiana.gov/index.cfm/newsroom/detail/2790
https://gov.louisiana.gov/index.cfm/newsroom/detail/2790
https://www.washingtonpost.com/nation/2021/05/11/interior-department-approves-first-large-scale-offshore-wind-farm-us
https://www.washingtonpost.com/nation/2021/05/11/interior-department-approves-first-large-scale-offshore-wind-farm-us
https://www.washingtonpost.com/nation/2021/05/11/interior-department-approves-first-large-scale-offshore-wind-farm-us
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https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2019
https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2017
https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2017
https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2017
https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2016
https://windeurope.org/wp-content/uploads/files/about-wind/statistics/WindEurope-Annual-Offshore-Statistics-2016
http://www.awea.org/MediaCenter/pressreleasev2.aspx?ItemNumber=9627
http://www.awea.org/MediaCenter/pressreleasev2.aspx?ItemNumber=9627
https://www.tradewindsnews.com/offshore/-51bn-in-wind-farm-capital-spending-outstrips-oil-and-gas-for-first-time/2-1-955552
https://www.tradewindsnews.com/offshore/-51bn-in-wind-farm-capital-spending-outstrips-oil-and-gas-for-first-time/2-1-955552
https://www.tradewindsnews.com/offshore/-51bn-in-wind-farm-capital-spending-outstrips-oil-and-gas-for-first-time/2-1-955552
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
Foreword on release of 2020 Statistics”, press release (Brussels:
3 March 2021), https://windeurope.org/newsroom/news/
windeurope-bulletin-ceo-foreword-on-release-of-2020-statistics.
176 GWEC, “Global Wind Statistics 2020”, op. cit. note 6. Japan
decommissioned 35 MW onshore and 7 MW offshore, and the
Republic of Korea decommissioned 4.7 MW onshore, from idem.
177 WindEurope, op. cit. note 152, p. 35; IEA, “Renewable energy
market update – report extract: Technology summaries”, https://
www.iea.org/reports/renewable-energy-market-update/
technology-summaries#abstract, viewed 5 May 2021; IEA, op. cit.
note 54.
178 IEA, op. cit. note 177; IEA, op. cit. note 54.
179 Richard, “Looking back on 2020”, op. cit. note 120; IEA, op. cit. note
177; IEA, op. cit. note 54.
180 WindEurope, op. cit. note 152, p. 35; BloombergNEF, “Covid-19
wreaks havoc on the wind industry”, 1 April 2020, https://about.
bnef.com/blog/covid-19-wreaks-havoc-on-the-wind-industry; N.
Ford, “Solar, wind investors adapt PPAs for post-COVID pickup”,
Reuters Events, 6 May 2020, https://analysis.newenergyupdate.com/
pv-insider/solar-wind-investors-adapt-ppas-post-covid-pickup; C.
Bussewitz, J. Flesher and P. Whittle, “Solar, wind energy struggle
as coronavirus takes toll”, Associated Press, 2 May 2020, https://
apnews.com/e3ea11613c2ad83f05bc85f75a26181a; B. Radowitz,
“Stricter Covid-19 shutdown forces wind OEMs to close all ‘non-
essential’ plants in Spain”, Recharge, 30 March 2020, https://www.
rechargenews.com/wind/stricter-covid-19-shutdown-forces-wind-
oems-to-close-all-non-essential-plants-in-spain/2-1-783868; E.
Crouse and D. Conner, “Opinion: Distressed supply chains uniquely
impact renewable energy”, Puget Sound Business Journal, 20 April
2020, https://www.bizjournals.com/seattle/news/2020/04/20/
distressed-supply-chains-uniquely-impacts-energy.html; C. Richard,
“O&M budgets ‘slashed’ during Covid-19 pandemic”, Windpower
Monthly, 21 July 2021, https://www.windpowermonthly.com/
article/1689926/o-m-budgets-slashed-during-covid-19-pandemic;
IEA, op. cit. note 177; IEA, op. cit. note 54.
181 C. Richard, “Looking back on 2020 – how wind defied global
pandemic”, Windpower Monthly, 13 January 2021, https://www.
windpowermonthly.com/article/1704181/looking-back-2020-
%E2%80%93-part-1-wind-industry-defied-global-pandemic;
Richard, op. cit. note 180. Wind turbine manufacturers margins
have been eroded by several factors, including the introduction of
auctions, global trade tensions and pandemic-induced disruptions,
from Siemens Gamesa, Annual Report 2020 (Vizcaya: 2021), p. 16,
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/
downloads/en/investors-and-shareholders/annual-reports/2020/
siemens-gamesa-renewable-energy-annual-report-2020-en .
182 See text and sources throughout this Wind Power section. Grid
challenges from, for example, St. John, op. cit. note 73; GWEC,
op. cit. note 1; E. Holbrook, “New report shows power purchase
agreement prices rising across North America”, Environment +
Energy Leader, 21 October 2020, https://www.environmentalleader.
com/2020/10/new-report-shows-power-purchase-agreement-
prices-rising-across-north-america. Grid congestion from L.
Gorroño, Aalborg University, Denmark, presentation for “Why
community power matters in times of crisis – industrialised
countries”, WWEA, 30 April 2020, https://wwindea.org/
wwea-presents-why-community-power-matters-in-times-of-
crisis-industrialised-countries-on-30-april. Land and resources
from, for example, Gerdes, op. cit. note 72; grid congestion from
Lydersen, op. cit. note 72; China’s main wind power regions are
approaching saturation, with fewer available sites, from Baiyu, op.
cit. note 35; India is a predominantly low-wind market, from “Vestas
launches low-wind turbine in India”,enews Biz, 6 October 2020,
https://renews.biz/63578/vestas-launches-low-wind-turbine-
in-india. Lack of available land with good resources is a driver for
manufacturers’ development of turbines for low-wind sites, as well
as for development offshore.
183 See text and sources throughout this Wind Power section.
Permitting delays and public opposition from, for example,
Chamberlain and Sayles, op. cit. note 108; Schmitz, op. cit. note
120; C. Richard, “WindEurope: Permitting key hurdle to EU wind
investments”, Windpower Monthly, 13 April 2021, https://www.
windpowermonthly.com/article/1712657/windeurope-permitting-
key-hurdle-eu-wind-investments. The diversity of investors is
increasing with the shift from FITs to auctions, which is having an
indirect negative impact on social support for wind farms, with local
citizens often not identifying themselves with local wind energy
projects, from Gsänger, op. cit. note 89, 14 April and 20 April 2021.
Social acceptance has been a major challenge in many countries
and reduced social interaction (such as during the pandemic) further
increased the risk of project delays, from IEA, op. cit. note 177; in
Denmark, projects are facing increasing local opposition, from
Gorroño, op. cit. note 182. Price pressures from, for example, Gsänger,
op. cit. note 89, 14 April and 20 April 2021; GWEC, Global Wind
Report 2019, op. cit. note 11, p. 11; A. Hübner and M. Martin, “German
wind turbine maker Senvion files for insolvency”, Reuters, 9 April
2019, https://uk.reuters.com/article/us-germany-senvion/german-
wind-turbine-maker-senvion-files-for-insolvency-idUKKCN1RL271;
“Wind margin pressures shift from turbines to service market”, New
Energy Update, 7 March 2019, https://analysis.newenergyupdate.
com/wind-energy-update/wind-margin-pressures-shift-turbines-
service-market. Wind turbine manufacturers margins have been
eroded by several factors, including the introduction of auctions,
global trade tensions and pandemic-induced disruptions, from
Siemens Gamesa, op. cit. note 181, p. 16. Delays due to reassigned
staff from Komusanac, op. cit. note 13.
184 See text and sources throughout this Wind Power section. Lack
of investment and participants driving prices up in some markets,
from Gsänger, op. cit. note 89, 14 April and 20 April 2021. In the
Russian Federation, for example, the average price of onshore
wind energy is substantially higher than in the rest of Europe due
to the small size of the market and lack of competition and of local
equipment production, from Lanshina, op. cit. note 93, p. 34.
185 For example: In the United States, projects under construction but
delayed by COVID were permitted an additional year to be placed
into service and still qualify for tax credits, from Musial et al., op. cit.
note 165, p. 25; R. Frazin, “Trump administration gives renewables
more time to take advantage of tax credits”, The Hill, 27 May 2020,
https://thehill.com/policy/energy-environment/499837-trump-
administration-gives-renewables-more-time-to-take-advantage.
At the same time, however, the US government ended a two-year
rent holiday for renewable energy (wind, solar and geothermal)
projects on federal lands, and many plant owners received
large retroactive bills, from N. Groom, “Trump admin slaps solar,
wind operators with retroactive rent bills”, Reuters, 18 May 2020,
https://www.reuters.com/article/us-usa-interior-renewables/
trump-admin-slaps-solar-wind-operators-with-retroactive-rent-
bills-idUSKBN22U0FW. In France, onshore wind (and solar PV)
developers were granted extensions for installation schedules
and auction timetables were adjusted, from C. Richard, “Prices
hit new low in French onshore”, 2 April 2020, https://www.
windpowermonthly.com/article/1679192/prices-hit-new-low-
french-onshore. In Greece, the government extended licencing
and construction deadlines, from C. Richard, “Greece momentum
continues with record onshore prices”, Windpower Monthly, 9
April 2020, https://www.windpowermonthly.com/article/1679862/
greece-momentum-continues-record-onshore-prices. Germany’s
parliament enacted several measures to address the backlog in
onshore permitting, from J. Parnell, “Onshore wind compromise
averts German solar market crisis”, 18 May 2020, https://www.
greentechmedia.com/articles/read/onshore-wind-policy-dispute-
could-decimate-germanys-distributed-solar-industry, and enacted
a six-month extension to commissioning deadlines, from IEA,
op. cit. note 54. In Turkey, the main support scheme for onshore
wind power (a feed-in tariff in place since 2011) was extended by
six months, to mid-2021, to account for project delays due to the
pandemic, from WindEurope, “Turkey offers more visibility on
wind energy pipeline with new support scheme”, press release
(Brussels: 11 February 2021), https://windeurope.org/newsroom/
news/turkey-offers-more-visibility-on-wind-energy-pipeline-
with-new-support-scheme; N. Erkul, “Tariff scheme key for
investors in Turkey’s renewables”, Anadolu Agency, 1 March 2020,
https://www.aa.com.tr/en/energy/finance/tariff-scheme-key-
for-investors-in-turkey-s-renewables/28511; A. Richter, “Turkey
extends feed-in-tariff scheme for geothermal to mid-2021”, Think
GeoEnergy, 18 September 2020, https://www.thinkgeoenergy.com/
turkey-extends-feed-in-tariff-scheme-for-geothermal-to-mid-2021.
186 B. Backwell, “The three ‘Rs’ took the wind industry through
a tough year – and I can’t help feeling optimistic”, GWEC, 31
December 2020, https://gwec.net/the-three-rs-took-the-wind-
industry-through-a-tough-year; Richard, “Looking back on 2020”,
op. cit. note 181, C. Richard, “Global turbine orders rise in 2020
despite early Covid-19 slump”, Windpower Monthly, 22 January
2021, https://www.windpowermonthly.com/article/1705192/
global-turbine-orders-rise-2020-despite-early-covid-19-slump.
187 See examples and sources below in this section.
337
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https://windeurope.org/newsroom/news/windeurope-bulletin-ceo-foreword-on-release-of-2020-statistics
https://www.iea.org/reports/renewable-energy-market-update/technology-summaries#abstract
https://www.iea.org/reports/renewable-energy-market-update/technology-summaries#abstract
https://www.iea.org/reports/renewable-energy-market-update/technology-summaries#abstract
https://about.bnef.com/blog/covid-19-wreaks-havoc-on-the-wind-industry
https://about.bnef.com/blog/covid-19-wreaks-havoc-on-the-wind-industry
https://analysis.newenergyupdate.com/pv-insider/solar-wind-investors-adapt-ppas-post-covid-pickup
https://analysis.newenergyupdate.com/pv-insider/solar-wind-investors-adapt-ppas-post-covid-pickup
https://apnews.com/e3ea11613c2ad83f05bc85f75a26181a
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https://www.rechargenews.com/wind/stricter-covid-19-shutdown-forces-wind-oems-to-close-all-non-essential-plants-in-spain/2-1-783868
https://www.rechargenews.com/wind/stricter-covid-19-shutdown-forces-wind-oems-to-close-all-non-essential-plants-in-spain/2-1-783868
https://www.rechargenews.com/wind/stricter-covid-19-shutdown-forces-wind-oems-to-close-all-non-essential-plants-in-spain/2-1-783868
https://www.bizjournals.com/seattle/news/2020/04/20/distressed-supply-chains-uniquely-impacts-energy.html
https://www.bizjournals.com/seattle/news/2020/04/20/distressed-supply-chains-uniquely-impacts-energy.html
https://www.windpowermonthly.com/article/1689926/o-m-budgets-slashed-during-covid-19-pandemic
https://www.windpowermonthly.com/article/1689926/o-m-budgets-slashed-during-covid-19-pandemic
https://www.windpowermonthly.com/article/1704181/looking-back-2020-%E2%80%93-part-1-wind-industry-defied-global-pandemic
https://www.windpowermonthly.com/article/1704181/looking-back-2020-%E2%80%93-part-1-wind-industry-defied-global-pandemic
https://www.windpowermonthly.com/article/1704181/looking-back-2020-%E2%80%93-part-1-wind-industry-defied-global-pandemic
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/investors-and-shareholders/annual-reports/2020/siemens-gamesa-renewable-energy-annual-report-2020-en
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https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/investors-and-shareholders/annual-reports/2020/siemens-gamesa-renewable-energy-annual-report-2020-en
https://www.environmentalleader.com/2020/10/new-report-shows-power-purchase-agreement-prices-rising-across-north-america
https://www.environmentalleader.com/2020/10/new-report-shows-power-purchase-agreement-prices-rising-across-north-america
https://www.environmentalleader.com/2020/10/new-report-shows-power-purchase-agreement-prices-rising-across-north-america
https://wwindea.org/wwea-presents-why-community-power-matters-in-times-of-crisis-industrialised-countries-on-30-april
https://wwindea.org/wwea-presents-why-community-power-matters-in-times-of-crisis-industrialised-countries-on-30-april
https://wwindea.org/wwea-presents-why-community-power-matters-in-times-of-crisis-industrialised-countries-on-30-april
https://renews.biz/63578/vestas-launches-low-wind-turbine-in-india
https://renews.biz/63578/vestas-launches-low-wind-turbine-in-india
https://www.windpowermonthly.com/article/1712657/windeurope-permitting-key-hurdle-eu-wind-investments
https://www.windpowermonthly.com/article/1712657/windeurope-permitting-key-hurdle-eu-wind-investments
https://www.windpowermonthly.com/article/1712657/windeurope-permitting-key-hurdle-eu-wind-investments
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https://analysis.newenergyupdate.com/wind-energy-update/wind-margin-pressures-shift-turbines-service-market
https://analysis.newenergyupdate.com/wind-energy-update/wind-margin-pressures-shift-turbines-service-market
https://thehill.com/policy/energy-environment/499837-trump-administration-gives-renewables-more-time-to-take-advantage
https://thehill.com/policy/energy-environment/499837-trump-administration-gives-renewables-more-time-to-take-advantage
https://www.reuters.com/article/us-usa-interior-renewables/trump-admin-slaps-solar-wind-operators-with-retroactive-rent-bills-idUSKBN22U0FW
https://www.reuters.com/article/us-usa-interior-renewables/trump-admin-slaps-solar-wind-operators-with-retroactive-rent-bills-idUSKBN22U0FW
https://www.reuters.com/article/us-usa-interior-renewables/trump-admin-slaps-solar-wind-operators-with-retroactive-rent-bills-idUSKBN22U0FW
https://www.windpowermonthly.com/article/1679192/prices-hit-new-low-french-onshore
https://www.windpowermonthly.com/article/1679192/prices-hit-new-low-french-onshore
https://www.windpowermonthly.com/article/1679192/prices-hit-new-low-french-onshore
https://www.windpowermonthly.com/article/1679862/greece-momentum-continues-record-onshore-prices
https://www.windpowermonthly.com/article/1679862/greece-momentum-continues-record-onshore-prices
https://www.greentechmedia.com/articles/read/onshore-wind-policy-dispute-could-decimate-germanys-distributed-solar-industry
https://www.greentechmedia.com/articles/read/onshore-wind-policy-dispute-could-decimate-germanys-distributed-solar-industry
https://www.greentechmedia.com/articles/read/onshore-wind-policy-dispute-could-decimate-germanys-distributed-solar-industry
https://windeurope.org/newsroom/news/turkey-offers-more-visibility-on-wind-energy-pipeline-with-new-support-scheme
https://windeurope.org/newsroom/news/turkey-offers-more-visibility-on-wind-energy-pipeline-with-new-support-scheme
https://windeurope.org/newsroom/news/turkey-offers-more-visibility-on-wind-energy-pipeline-with-new-support-scheme
https://www.aa.com.tr/en/energy/finance/tariff-scheme-key-for-investors-in-turkey-s-renewables/28511
https://www.aa.com.tr/en/energy/finance/tariff-scheme-key-for-investors-in-turkey-s-renewables/28511
https://www.thinkgeoenergy.com/turkey-extends-feed-in-tariff-scheme-for-geothermal-to-mid-2021
https://www.thinkgeoenergy.com/turkey-extends-feed-in-tariff-scheme-for-geothermal-to-mid-2021
https://gwec.net/the-three-rs-took-the-wind-industry-through-a-tough-year
https://gwec.net/the-three-rs-took-the-wind-industry-through-a-tough-year
https://www.windpowermonthly.com/article/1705192/global-turbine-orders-rise-2020-despite-early-covid-19-slump
https://www.windpowermonthly.com/article/1705192/global-turbine-orders-rise-2020-despite-early-covid-19-slump
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188 Backwell, op. cit. note 186; GWEC, op. cit. note 1; and from
information and sources throughout this section.
189 Based on the LCOE of onshore wind energy falling from USD
48 per MWh in the second half of 2019 to USD 41 per MWh in
the second half of 2020, and the LCOE of offshore wind energy
falling from USD 80 per MWh to USD 79 per MWh during the
same period, from BloombergNEF, provided by Zhao, op. cit. note
7, 27 April 2021. LCOE continued to decline significantly in 2020
for onshore and offshore wind in China, from Q. Haiyan, CWEA,
presentation for “WWEA webinar: Wind power around the world”,
7 April 2021, https://wwindea.org/wweawebinar-wind-power-
around-the-world. In the previous year, onshore LCOE declined
10% from 2018 to 2019, to average of USD 48.5 per MWh, and
fell 28% offshore to USD 83.50 per MWh, from FS-UNEP and
BloombergNEF, op. cit. note 9, p. 28. In the United States, cost
reductions have accelerated in recent years, from Lawrence
Berkeley National Laboratory (LBNL), “Experts anticipate sustained
wind energy cost reductions and technology advancements”, fact
sheet (Berkeley, CA: 2021), https://eta-publications.lbl.gov/sites/
default/files/expert_survey_factsheet . LCOE estimates vary
widely from place to place and are influenced by several factors,
including resources and local regulatory, finance and labour cost
characteristics, upfront capital costs, project design life, capacity
factor and operating costs, from idem, and from J. Broehl, “Beating
the projections: Future wind costs 50 percent lower than predicted
five years ago”, 21 April 2021, https://cleanpower.org/blog/
beating-the-projections-future-wind-costs-50-percent-lower-than-
predicted-five-years-ago.
190 See, for example, FS-UNEP and BloombergNEF, op. cit. note 9,
p. 28; IEA, op. cit. note 54; BloombergNEF, cited in C. Richard,
“Renewables ‘cheapest option for most of the world’”, Windpower
Monthly, 29 April 2020, https://www.windpowermonthly.com/
article/1681740/renewables-cheapest-option-world; S. Evans,
“Wind and solar are 30-50% cheaper than thought, admits
UK government”, CarbonBrief, 27 August 2020, https://www.
carbonbrief.org/wind-and-solar-are-30-50-cheaper-than-thought-
admits-uk-government.
191 Figures of 26.5%, 35 GW and second highest on record, from
GWEC, “Nearly 30 GW of new wind power capacity auctioned in
H2 2020, a clear signal that growth is back on-track”, 15 February
2021,https://gwec.net/nearly-30-gw-of-new-wind-power-capacity-
auctioned-in-h2-2020-a-clear-signal-that-growth-is-back-on-
track; 33.7 GW onshore from GWEC, op. cit. note 1, p. 46. Note that
3,770 MW of this is from the hybrid auction in India, from Zhao, op.
cit. note 7, 27 April 2021.
192 Capacity reduced and postponements from GWEC, “GWEC
Market Intelligence releases Q1 2020 Wind Auctions Database”, 14
May 2020, https://gwec.net/gwec-market-intelligence-releases-
q1-2020-wind-auctions-database. Auctioned capacity was down
in the first four months of year (3.35 GW) relative to same period
in 2019 (almost 5 GW); early auctions occurred in Europe (2.1 GW)
and Asia (1.2 GW), with delays in several countries including Brazil,
China and the United States, from idem. Second half of 2020 from
GWEC, op. cit. note 191. Nearly 30 GW of new onshore capacity
awarded through auction in second half of 2020, up from 28 GW
during same period of 2019, from idem. Auctions postponed or
cancelled for 2020 in Brazil, Chile and the United States were
rescheduled for 2021, from idem.
193 China accounted for 67%, and “subsidy-free” onshore wind
projects represented 96% of China’s approved capacity, from
GWEC, op. cit. note 191.
194 Figure of 13 countries or regions based on the following: GWEC
database, provided by Zhao, op. cit. note 7, 27 April 2021; several
countries in Europe, Ecuador and India from GWEC, op. cit. note 191;
WindEurope, op. cit. note 6, p. 23; Windpower Monthly/Windpower
Intelligence, “Tender Watch”, https://www.windpowermonthly.com/
tender-watch, viewed 7 March 2021. In order of awarded capacity,
these countries were: India (2.2 GW), Germany (1.5 GW), Poland
(900 MW), the Netherlands (759 MW) Ireland (479 MW), Greece
(472 MW), France (258 MW) and Ecuador (110 MW), from GWEC,
op. cit. note 191. Italy also held several (technology-neutral) auctions
during the year, from WindEurope, op. cit. note 6, p. 23. An auction
also was held in the US state of New Jersey, based on data from
Windpower Monthly/Windpower Intelligence, op. cit. this note, and
from New Jersey Board of Public Utilities, “New Jersey offshore wind
solicitation #2”, https://njoffshorewind.com.
195 See, for example, WindEurope, op. cit. note 23, pp. 8, 21; IRENA,
Renewable Energy Auctions: Status and Trends Beyond Price (Abu
Dhabi: 2019), p. 14, https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-
trends_2019 .
196 Figures for 2020 from Komusanac, op. cit. note 13; figures for 2019
from Komusanac, op. cit. note 13, 14 April 2020.
197 Richard, “Looking back on 2020”, op. cit. note 120. See also
Richard, “Greece momentum continues with record onshore
prices”, op. cit. note 185; H. O’Brian, “Wind corners Italy’s
first joint auction”, Windpower Monthly, 29 January 2020,
https://www.windpowermonthly.com/article/1672375/wind-
corners-italys-first-joint-auction; C. Richard, “Shell advances
hydrogen plan with Eneco deal”, Windpower Monthly, 7 May
2020, https://www.windpowermonthly.com/article/1682629/
shell-advances-hydrogen-plan-eneco-deal.
198 Bid prices rose in Italy from Komusanac, op. cit. note 13. Italy’s
2020 auctions were undersubscribed due to the slow permitting
process, from WindEurope, op. cit. note 6, p. 23. Note that a total of
four auctions were held by end-2020, with the first in 2019, when
the auction was oversubscribed for group A (solar PV and wind
power), with bids for 595 MW, well above the 500 MW available
capacity, from A. Di Pardo, Gestore dei Servizi Energetici (GSE),
Italy, personal communication with REN21, 7 April 2021.
199 Gsänger, op. cit. note 89, 7 May 2020 and 14 April 2021. All
wind-specific auctions in Germany had average winning bids
above EUR 62 (USD 76.2) per MWh and around the ceiling
price and above prices from previous years, from Komusanac,
op. cit. note 13. See also BMWi, “Ausschreibungsergebnisse
Windenergie an Land”, https://www.erneuerbare-energien.
de/EE/Redaktion/DE/Downloads/ausschreibungsrunden-
windenergie-an-land-balkendiagramm , viewed 27 April 2021,
and Bundesnetzagentur, “Completed tenders”, https://www.
bundesnetzagentur.de/DE/Sachgebiete/ElektrizitaetundGas/
Unternehmen_Institutionen/Ausschreibungen/Wind_Onshore/
BeendeteAusschreibungen/BeendeteAusschreibungen_node.
html, viewed 27 August 2021. Awarded bid prices fell significantly
in the first year of auctions in Germany, but increased in 2018 and
2019, to above the statutory tariffs of the old EEG, or Germany’s
FIT, from WWEA and Landesverband Erneuerbare Energien
Nordrhein-Westfalen (LEE NRW), Community Wind Under the
Auctions Model: A Critical Appraisal (Bonn/Düsseldorf: September
2019), WWEA Policy Paper Series, pp. 7, 11, https://wwindea.org/
download/community-power-study-september-2019, and from
Gsänger, op. cit. note 89, 7 May 2020. Note that the final onshore
wind tender of 2020 was not undersubscribed, from Richard,
“German onshore wind reverses trend with successful tender”,
op. cit. note 120; but the first of 2021 was undersubscribed, with
the average winning bid price up slightly relative to the final
tender in 2020, from C. Richard, “Developers stay away from
German onshore wind tender”, Windpower Monthly, 30 April
2021, https://www.windpowermonthly.com/article/1714500/
developers-stay-away-german-onshore-wind-tender.
200 Council on Energy, Environment and Water, Centre for Energy
Finance, Clean Energy Investment Trends 2020 (New Delhi: 2020),
https://cef.ceew.in/solutions-factory/CEEW-CEF-clean-energy-
investment-trends-2020 .
201 Rise in tariffs, regulatory environment and suitable sites, all from
Prasad, op. cit. note 46; decline in participants and competition
from Gsänger, op. cit. note 89, 20 April 2021. India had a very
diverse wind power sector with dozens of small and medium
enterprises investing, but only a handful of large companies has
participated in auctions, representing a dramatic reduction in
competition and diversity of actors, from idem.
202 Government of the Netherlands, “Shell and Eneco to build third
unsubsidised Dutch offshore wind farm”, 29 July 2020, https://
www.government.nl/latest/news/2020/07/29/shell-and-eneco-to-
build-third-unsubsidised-dutch-offshore-wind-farm; WindEurope,
op. cit. note 6, p. 23; J. Parnell, “Dutch offshore wind tender
deadline passes amid concerns of depressed interest”, Greentech
Media, 1 May 2020, https://www.greentechmedia.com/articles/
read/dutch-offshore-wind-tender-closes-amid-fears-of-falling-
interest. Seabed rights from Komusanac, op. cit. note 13. The
second such tender was held in 2019, from GWEC, Global Wind
Report 2019, op. cit. note 11, p. 38; A. Lee, “Vattenfall wins 760 MW
of Dutch zero-subsidy offshore wind”, Recharge, 10 July 2019,
https://www.rechargenews.com/wind/vattenfall-wins-760mw-
of-dutch-zero-subsidy-offshore-wind/2-1-636547. The first was
338
https://wwindea.org/wweawebinar-wind-power-around-the-world
https://wwindea.org/wweawebinar-wind-power-around-the-world
https://eta-publications.lbl.gov/sites/default/files/expert_survey_factsheet
https://eta-publications.lbl.gov/sites/default/files/expert_survey_factsheet
https://cleanpower.org/blog/beating-the-projections-future-wind-costs-50-percent-lower-than-predicted-five-years-ago
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https://cleanpower.org/blog/beating-the-projections-future-wind-costs-50-percent-lower-than-predicted-five-years-ago
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https://www.windpowermonthly.com/article/1681740/renewables-cheapest-option-world
https://www.carbonbrief.org/wind-and-solar-are-30-50-cheaper-than-thought-admits-uk-government
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https://gwec.net/gwec-market-intelligence-releases-q1-2020-wind-auctions-database
https://www.windpowermonthly.com/tender-watch
https://www.windpowermonthly.com/tender-watch
https://njoffshorewind.com
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Dec/IRENA_RE-Auctions_Status-and-trends_2019
https://www.windpowermonthly.com/article/1672375/wind-corners-italys-first-joint-auction
https://www.windpowermonthly.com/article/1672375/wind-corners-italys-first-joint-auction
https://www.windpowermonthly.com/article/1682629/shell-advances-hydrogen-plan-eneco-deal
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https://www.erneuerbare-energien.de/EE/Redaktion/DE/Downloads/ausschreibungsrunden-windenergie-an-land-balkendiagramm
https://www.bundesnetzagentur.de/DE/Sachgebiete/ElektrizitaetundGas/Unternehmen_Institutionen/Ausschreibungen/Wind_Onshore/BeendeteAusschreibungen/BeendeteAusschreibungen_node.html
https://www.bundesnetzagentur.de/DE/Sachgebiete/ElektrizitaetundGas/Unternehmen_Institutionen/Ausschreibungen/Wind_Onshore/BeendeteAusschreibungen/BeendeteAusschreibungen_node.html
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held in 2018, from WindEurope, “World’s first offshore wind farm
without subsidies to be built in the Netherlands”, press release
(Brussels: 20 March 2018), https://windeurope.org/newsroom/
press-releases/worlds-first-offshore-wind-farm-without-subsidies-
to-be-built-in-the-netherlands.
203 “Shell, Eneco win Dutch offshore wind tender”,
reNEWS, 29 July 2020, https://renews.biz/62089/
shell-eneco-win-dutch-offshore-wind-tender.
204 New Jersey from Windpower Monthly / Windpower Intelligence,
op. cit. note 194, and from New Jersey Board of Public Utilities,
“New Jersey offshore wind solicitation #2”, https://njoffshorewind.
com; “France launches 1GW Normandy offshore tender”,
reNEWS Biz, 7 December 2020, https://renews.biz/64975/
france-launches-1gw-normandy-offshore-tender.
205 WWEA, op. cit. note 3.
206 Ibid.
207 Trended up from Holbrook, op. cit. note 182; down in final quarter
from H. Edwardes-Evans, “PPA prices dip in Q4 2020 as developers
absorb COVID impacts: LevelTen”, SP Global, 13 January 2021,
https://www.spglobal.com/platts/en/market-insights/latest-news/
electric-power/011321-ppa-prices-dip-in-q4-2020-as-developers-
absorb-covid-impacts-levelten.
208 Holbrook, op. cit. note 182; E. Holbrook, “Report: North American
PPA prices rose throughout 2020”, Environment + Energy Leader,
20 January 2021, https://www.environmentalleader.com/2021/01/
report-north-american-ppa-prices-rose-throughout-2020; E.
Penrod, “Renewable PPAs could see ‘sellers market’ in 2021 after
year of price increases, LevelTen finds”, Utility Dive, 21 January
2021, https://www.utilitydive.com/news/renewable-ppa-prices-
are-rising-for-the-first-time-creating-potential-sel/593708.
Windiest sites with easy grid access (so new sites often have either
less strong winds and/or more development challenges) from
Broehl, op. cit. note 70.
209 LBNL, “Wind Technologies Market Report”, https://emp.lbl.gov/
wind-technologies-market-report, viewed 15 February 2021.
210 C. Richard, “Mayflower lowers US offshore to $58/MWh”,
Windpower Monthly, 12 February 2020, https://www.
windpowermonthly.com/article/1673776/mayflower-lowers-us-
offshore-58-mwh; 13% from K. Stromsta, “Why 2020 has been a
surprisingly good year for US offshore wind”, Greentech Media, 25
September 2020, https://www.greentechmedia.com/articles/read/
why-2020-has-been-a-surprisingly-good-year-for-us-offshore-wind.
211 More than 100 suppliers from GWEC, Global Wind Report 2019, op.
cit. note 11, p. 18; down from 63 original equipment manufacturers
that reported installations in 2013, and 51 in 2015, and 33 suppliers
reported installations in 2019 (20 of these were from Asia Pacific),
also from F. Zhao, J. Lee and A. Lathigara, Global Wind Market
Development – Supply Side Data 2019 (Brussels: GWEC, May 2020),
p. 20. In 2019, 20 of the 33 turbine suppliers were from Asia Pacific,
from idem. Data for 2020 were not available by date of publication.
However, the number of turbine manufacturers installing machines
in 2020 may have been higher than in 2019 (33 total) due to the
rush of installations in China; in addition, Hyundai (Republic of
Korea) reported installations during the year, from Zhao, op. cit.
note 7, 27 April 2021.
212 Top six in 2020 from GWEC, op. cit. note 1, p. 17; 64% in 2017 based
on data from FTI Consulting, Global Wind Market Update – Demand
& Supply 2017, Part One – Supply Side Analysis (London: April
2018), pp. 6, 10, 11. In 2019 the top 10 companies captured 85.5% of
the capacity installed, from share from Zhao, op. cit. note 7, 15 May
2020, and from Zhao, Lee and Lathigara, op. cit. note 211. This was
up from 85% in 2018, from GWEC Market Intelligence, Global Wind
Market Development – Supply Side Data 2018 (Brussels: April 2019),
p. 3; 80% for 2017 from FTI Consulting, op. cit. this note, pp. 6, 10,
11; 75% in 2016 based on data from FTI Consulting, Global Wind
Market Update – Demand & Supply 2016, Part One – Supply Side
Analysis (London: 2017), p. 10.
213 GWEC, “GWEC releases Global Wind Turbine Supplier Ranking
for 2020”, 23 March 2021, https://gwec.net/gwec-releases-global-
wind-turbine-supplier-ranking-for-2020. The rankings were GE
(US), Goldwind (China), Vestas (Denmark), Envision (China),
Siemens Gamesa (Spain) and Mingyang, Shanghai Electric,
Windey, CRRC and Sany (all China), and the top four accounted
for 55% of the machines deployed in 2020, from BloombergNEF,
op. cit. note 1. Rankings were Vestas, Goldwind (moved to second
from fourth place in 2019), GE, Envision (up from fifth place in
2019), Siemens Gamesa (down from second), Mingyang, SEwind
(China), Nordex (Germany), Windey and CRRC, with Chinese
manufacturers taking 10 of the top 15 places, from S. Barla,
“Global wind turbine market: State of play”, Wood Mackenzie,
14 April 2021, https://www.woodmac.com/news/opinion/
global-wind-turbine-market-state-of-play.
214 Top five from GWEC, op. cit. note 213. Mingyang was in sixth place
with around 6 GW of new installations, from Zhao, op. cit. note 7, 13
May 2021. GE, 2020 Annual Report (Boston: 2020), https://www.
ge.com/sites/default/files/GE_AR20_AnnualReport .
215 Barla, op. cit. note 213.
216 Enercon, for example, saw its sales in Germany fall from 1,282
MW in 2018 to 378 MW in 2019, from S. Knight, “Enercon looks
to exports for recovery – analysis”, Windpower Monthly, 9 June
2020, https://www.windpowermonthly.com/article/1685675/
enercon-looks-exports-recovery-%E2%80%94-analysis. After
filing for insolvency in 2019, Senvion sold its Indian manufacturing
operations, exiting the local market, and continued selling
other assets (including a blade factory in Portugal) to Siemens
Gamesa, from the following: Hübner and Martin, op. cit. note 183,
E. de Vries, “The rise and fall of Senvion”, Windpower Monthly,
18 September 2019, https://www.windpowermonthly.com/
article/1654013/rise-fall-senvion. Indian operations and market,
from V. Petrova, “Senvion agrees to shed Indian subsidiary”,
Renewables Now, 9 April 2020, https://renewablesnow.com/
news/senvion-agrees-to-shed-indian-subsidiary-694422. Sale of
assets to Siemens Gamesa from, for example, C. Richard, “SGRE
completes Senvion purchase”, Windpower Monthly, 9 January
2020, https://www.windpowermonthly.com/article/1670368/
sgre-completes-senvion-purchase; D. Weston, “Factory sale
finalizes SGRE-Senvion Deal”, Windpower Monthly, 1 May 2020,
https://www.windpowermonthly.com/article/1681997/factory-
sale-finalises-sgre-senvion-deal. Enercon reached a EUR 1.15
billion (USD 1.41 billion) agreement with banks mid-year to extend
loans and help secure projects overseas and, in September,
announced plans to streamline its domestic manufacturing
(including cutting about 3,000 jobs), and to shift production
overseas to reduce costs; the company will target international
markets while awaiting a rebound in the German market, from the
following: Agreement with banks, from Knight, op. cit. this note.
The agreement includes EUR 550 million loan extension and EUR
600 million new guarantee facility that will help secure projects
overseas, from idem. Streamline, cut jobs and shift production
overseas from C. Richard, “Energy restructures manufacturing
setup”, Windpower Monthly, September 2020, pp. 10-11, https://
www.windpowermonthly.com/article/1692957/read-windpower-
monthly-online. Suzlon was relying largely on long-term service
agreements after struggling to compete at home with a growing
number of foreign turbine manufacturers following India’s shift
to auctions, from Saurabh, “Financial lifeline for troubled indian
wind company Suzlon Energy approved”, CleanTechnica, 12 April
2020, https://cleantechnica.com/2020/04/12/financial-lifeline-
for-troubled-indian-wind-company-suzlon-energy-approved;
R. Ranjan, “Suzlon completes restructuring of debt with capital
infusion of ₹3.92 billion”, Mercom India, 3 July 2020, https://
mercomindia.com/suzlon-completes-restructuring-debt.
Suzlon’s losses continued to mount early in 2020 due in part
to the pandemic’s impact on sales, but it completed debt
restructuring mid-year, from idem; N. T. Prasad, “Suzlon’s net
losses rose to ₹26.92 billion in FY 2020 amid historically low
installations”, Mercom India, 8 July 2020, https://mercomindia.com/
suzlons-losses-rose-historically-low-installations.
217 For example, Vestas cut jobs and discontinued a range of products
due in part to uncertainty about impact of the pandemic, from
J. Parnell, “Vestas cuts 400 jobs as coronavirus slams global
renewables sector”, Greentech Media, 20 April 2020, https://
www.greentechmedia.com/articles/read/vestas-makes-400-
job-cuts-as-coronavirus-impact-bites. Vestas produced and
shipped 35% more turbines (based on capacity) than in 2019,
meaning higher revenues, but profits were squeezed by higher
costs associated with the pandemic and a highly competitive
market, from C. Richard, “Vestas sees profits fall despite higher
revenues in 2020”, Windpower Monthly, 10 February 2021, https://
www.windpowermonthly.com/article/1706953/vestas-sees-
profits-fall-despite-higher-revenues-2020. GE’s LM Glasfiber
closed plants in Denmark to reduce costs, from B. Radowitz,
“Cost cuts prompts GE’s LM Wind Power to shut Danish blade
plants”, Recharge, 27 February 2020, https://www.rechargenews.
com/wind/cost-cutting-prompts-ge-s-lm-wind-to-shut-danish-
plants/2-1-763424; “Wind turbine manufacturing plant in Arkansas
339
https://windeurope.org/newsroom/press-releases/worlds-first-offshore-wind-farm-without-subsidies-to-be-built-in-the-netherlands
https://windeurope.org/newsroom/press-releases/worlds-first-offshore-wind-farm-without-subsidies-to-be-built-in-the-netherlands
https://windeurope.org/newsroom/press-releases/worlds-first-offshore-wind-farm-without-subsidies-to-be-built-in-the-netherlands
https://renews.biz/62089/shell-eneco-win-dutch-offshore-wind-tender
https://renews.biz/62089/shell-eneco-win-dutch-offshore-wind-tender
https://njoffshorewind.com
https://njoffshorewind.com
https://renews.biz/64975/france-launches-1gw-normandy-offshore-tender
https://renews.biz/64975/france-launches-1gw-normandy-offshore-tender
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/011321-ppa-prices-dip-in-q4-2020-as-developers-absorb-covid-impacts-levelten
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/011321-ppa-prices-dip-in-q4-2020-as-developers-absorb-covid-impacts-levelten
https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/011321-ppa-prices-dip-in-q4-2020-as-developers-absorb-covid-impacts-levelten
https://www.environmentalleader.com/2021/01/report-north-american-ppa-prices-rose-throughout-2020
https://www.environmentalleader.com/2021/01/report-north-american-ppa-prices-rose-throughout-2020
https://www.utilitydive.com/news/renewable-ppa-prices-are-rising-for-the-first-time-creating-potential-sel/593708
https://www.utilitydive.com/news/renewable-ppa-prices-are-rising-for-the-first-time-creating-potential-sel/593708
https://emp.lbl.gov/wind-technologies-market-report
https://emp.lbl.gov/wind-technologies-market-report
https://www.windpowermonthly.com/article/1673776/mayflower-lowers-us-offshore-58-mwh
https://www.windpowermonthly.com/article/1673776/mayflower-lowers-us-offshore-58-mwh
https://www.windpowermonthly.com/article/1673776/mayflower-lowers-us-offshore-58-mwh
https://www.greentechmedia.com/articles/read/why-2020-has-been-a-surprisingly-good-year-for-us-offshore-wind
https://www.greentechmedia.com/articles/read/why-2020-has-been-a-surprisingly-good-year-for-us-offshore-wind
https://gwec.net/gwec-releases-global-wind-turbine-supplier-ranking-for-2020
https://gwec.net/gwec-releases-global-wind-turbine-supplier-ranking-for-2020
https://www.woodmac.com/news/opinion/global-wind-turbine-market-state-of-play
https://www.woodmac.com/news/opinion/global-wind-turbine-market-state-of-play
https://www.ge.com/sites/default/files/GE_AR20_AnnualReport
https://www.ge.com/sites/default/files/GE_AR20_AnnualReport
https://www.windpowermonthly.com/article/1685675/enercon-looks-exports-recovery-%E2%80%94-analysis
https://www.windpowermonthly.com/article/1685675/enercon-looks-exports-recovery-%E2%80%94-analysis
https://www.windpowermonthly.com/article/1654013/rise-fall-senvion
https://www.windpowermonthly.com/article/1654013/rise-fall-senvion
https://renewablesnow.com/news/senvion-agrees-to-shed-indian-subsidiary-694422
https://renewablesnow.com/news/senvion-agrees-to-shed-indian-subsidiary-694422
https://www.windpowermonthly.com/article/1670368/sgre-completes-senvion-purchase
https://www.windpowermonthly.com/article/1670368/sgre-completes-senvion-purchase
https://www.windpowermonthly.com/article/1681997/factory-sale-finalises-sgre-senvion-deal
https://www.windpowermonthly.com/article/1681997/factory-sale-finalises-sgre-senvion-deal
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://cleantechnica.com/2020/04/12/financial-lifeline-for-troubled-indian-wind-company-suzlon-energy-approved
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https://mercomindia.com/suzlon-completes-restructuring-debt
https://mercomindia.com/suzlon-completes-restructuring-debt
https://mercomindia.com/suzlons-losses-rose-historically-low-installations
https://mercomindia.com/suzlons-losses-rose-historically-low-installations
https://www.greentechmedia.com/articles/read/vestas-makes-400-job-cuts-as-coronavirus-impact-bites
https://www.greentechmedia.com/articles/read/vestas-makes-400-job-cuts-as-coronavirus-impact-bites
https://www.greentechmedia.com/articles/read/vestas-makes-400-job-cuts-as-coronavirus-impact-bites
https://www.windpowermonthly.com/article/1706953/vestas-sees-profits-fall-despite-higher-revenues-2020
https://www.windpowermonthly.com/article/1706953/vestas-sees-profits-fall-despite-higher-revenues-2020
https://www.windpowermonthly.com/article/1706953/vestas-sees-profits-fall-despite-higher-revenues-2020
https://www.rechargenews.com/wind/cost-cutting-prompts-ge-s-lm-wind-to-shut-danish-plants/2-1-763424
https://www.rechargenews.com/wind/cost-cutting-prompts-ge-s-lm-wind-to-shut-danish-plants/2-1-763424
https://www.rechargenews.com/wind/cost-cutting-prompts-ge-s-lm-wind-to-shut-danish-plants/2-1-763424
03
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
to close”, Associated Press, 14 April 2020, https://apnews.com/
a0d44432268a249271ba25ff208005e4. GE restructured some
of its debts to strengthen its financial condition, from “General
Electric (GE) announces debt-restructuring actions”, Nasdaq, 7
May 2020, https://www.nasdaq.com/articles/general-electric-
ge-announces-debt-restructuring-actions-2020-05-07. GE ended
the year with a record order backlog and full-year revenues
were up 2% over 2019 (due mainly to improved pricing and
project execution), but the company recorded a loss for the year
(although less than the 2019 loss), from C. Richard, “GE Renewable
Energy narrows losses in 2020”, Windpower Monthly, 26 January
2021, https://www.windpowermonthly.com/article/1705583/
ge-renewable-energy-narrows-losses-2020. Siemens Gamesa
restructured operations in Spain in response to project delays due
mainly to the pandemic, from M. McGovern, “SGRE temporarily
cuts jobs at Spanish plant”, Windpower Monthly, 17 September
2020, https://www.windpowermonthly.com/article/1694735/
sgre-temporarily-cuts-jobs-spanish-plant; Parnell, op. cit. this note.
The company doubled its orders for offshore turbines, but onshore
orders declined in 2020, from C. Richard, “Coronavirus pandemic
sends Siemens Gamesa to €900 million full-year loss”, Windpower
Monthly, 5 November 2020, https://www.windpowermonthly.
com/article/1699242/coronavirus-pandemic-sends-siemens-
gamesa-%E2%82%AC900-million-full-year-loss. Siemens
Gamesa reported a net loss for its 2020 fiscal year, with revenues
down because of pandemic-induced project delays and reduced
commercial activity, from idem. Wind turbine manufacturers
margins have been eroded by several factors, including the
introduction of auctions, global trade tensions and pandemic-
induced disruptions, from Siemens Gamesa, op. cit. note 181, p. 16.
218 Orders were down 3% for both companies, from Richard, “Vestas
sees profits fall despite higher revenues in 2020”, op. cit. note 217.
Richard, “GE Renewable Energy narrows losses in 2020”, op. cit.
note 217. Order intakes for Vestas were 17,977 MW in 2019, from
Vestas, “Wind turbine orders announced in 2019”, https://www.
vestas.com/en/investor/company%20announcements#!turbine-
orders-2019, viewed 27 April 2021, and 17,249 MW in 2020, from
Vestas, “Company announcements”, https://www.vestas.com/
en/investor/company%20announcements#!2020, viewed 27 April
2021. Orders were up to record levels for Siemens Gamesa, but
2020 was a challenging year financially, from Siemens Gamesa, op.
cit. note 181, p. 18.
219 C. Richard, “How SGRE and GE’s escalating legal battle could
backfire”, Windpower Monthly, 9 October 2020, https://www.
windpowermonthly.com/article/1696818/sgre-ges-escalating-legal-
battle-backfire; I. Shumkov, “GE files IP infringement complaint
against Siemens Gamesa”, Renewables Now, 4 August 2020, https://
renewablesnow.com/news/ge-files-ip-infringement-complaint-
against-siemens-gamesa-708760; T. Pieffers, “Siemens Gamesa
challenges GE with new 14MW offshore turbine”, 19 May 2020,
https://www.projectcargojournal.com/equipment/2020/05/19/
siemens-gamesa-challenges-ge-with-new-14mw-offshore-turbine;
M. Spector, “GE alleges Siemens Energy used stolen trade secrets
to rig contract bids”, Reuters, 14 January 2021, https://www.reuters.
com/article/us-ge-siemens-lawsuit-idUKKBN29J2N2.
220 E. F. Merchant, “5 wind energy giants embracing solar power”,
Greentech Media, 19 May 2020, https://www.greentechmedia.
com/articles/read/five-large-scale-wind-developers-pivoting-
to-solar; “Hybrid power plants are growing rapidly: are they a
good idea?” Electricity Markets & Policy, 13 March 2020, https://
emp.lbl.gov/news/hybrid-power-plants-are-growing-rapidly-
are; “Vattenfall’s largest hybrid energy park is taking shape
in the Netherlands”, NS Energy, 30 July 2020, https://www.
nsenergybusiness.com/news/vattenfalls-largest-hybrid-energy-
park-is-taking-shape-in-the-netherlands.
221 “Orsted to unleash 430MW solar project in Texas”, reNEWS Biz, 2
December 2020, https://www.renews.biz/64876/orsted-to-proceed-
with-430mwac-solar-project-in-texas. Note that the capacity (430
MW) of the project in Texas is in alternating current, but the source
does not specify if the total capacity provided (1.1 GW) is in AC or DC.
222 J. Agyepong-Parsons, “Double hit for Chinese OEMs as market
shrinks amid falling turbine prices”, Windpower Monthly, 18 June
2020, https://www.windpowermonthly.com/article/1686943/double-
hit-chinese-oems-market-shrinks-amid-falling-turbine-prices.
223 E. Vries, “Turbines of the Year 2020: Winners against
all odds”, Windpower Monthly, 11 January 2021, https://
www.windpowermonthly.com/article/1704030/
turbines-year-2020-winners-against-odds.
224 Jörg Scholle, Enercon, cited in E. de Vries, “Exclusive: Enercon
fires-up first E-160 prototype”, Windpower Monthly, 23 July 2020,
https://www.windpowermonthly.com/article/1690157/exclusive-
enercon-fires-up-first-e-160-prototype. See also GWEC, “Pressures
to reduce costs are transforming the global wind blade supply
chain”, 16 December 2020, https://gwec.net/pressures-to-reduce-
costs-are-transforming-the-global-wind-blade-supply-chain.
225 M. Bolinger et al., Opportunities for and Challenges to Further
Reductions in the “Specific Power” Rating of Wind Turbines Installed
in the United States (Berkeley, CA: LBNL, January 2020), https://
eta-publications.lbl.gov/sites/default/files/wind_engineering_
accepted_manuscript_w_disclaimer_copyright ; R. Wiser et
al., “The hidden value of large-rotor, tall-tower wind turbines in
the United States”, Wind Engineering, July 2020, pp. 1-15, cited in
D. Milborrow, “How lower specific ratings translate into cheaper
power”, Windpower Monthly, September 2020, pp. 33-34, https://
www.windpowermonthly.com/article/1692957/read-windpower-
monthly-online; R. Wiser et al., “Interactive: Wind turbines are
getting more powerful as ‘specific power’ declines”, Utility Dive,
23 August 2018, https://www.utilitydive.com/news/a-big-wind-
power-trend-you-may-have-never-heard-of-declining-specific-
pow/530811.
226 E. Holbrook, “5 trends shaping the wind energy
industry”, Environmental Leader, 29 September
2020, https://www.environmentalleader.
com/2020/09/5-trends-shaping-the-wind-energy-industry.
227 C. Richard, “Looking back on 2020 – Part 3: Turbine ratings and
rotor sizes continue to go up”, Windpower Monthly, 15 January
2021, https://www.windpowermonthly.com/article/1704255/
looking-back-2020-%E2%80%93-part-3-turbine-ratings-rotor-
sizes-continue-go; GE’s 6 MW Cypress onshore turbine will be
available by 2022, from C. Richard, “GE launches 6MW onshore
wind turbine”, Windpower Monthly, 30 November 2020, https://
www.windpowermonthly.com/article/1701374/ge-launches-6mw-
onshore-wind-turbine; A. McCorkell, “Nordex pushes N149/5.X
prototype to 5.7MW”, Windpower Monthly, 14 September 2020,
https://www.windpowermonthly.com/article/1694291/nordex-
pushes-n149-5x-prototype-57mw; Siemens Gamesa from E.
de Vries, “SGRE uses offshore experience to take 5.X onshore
platform past 6MW”, Windpower Monthly, 1 June 2020, https://
www.windpowermonthly.com/article/1684754/sgre-uses-
offshore-experience-5x-onshore-platform-past-6mw, and from
E. Pearcey, “Onshore turbine capacities smash 6 MW, pressuring
logistics“, Reuters Events, 6 May 2020, https://www.reutersevents.
com/renewables/wind-energy-update/onshore-turbine-
capacities-smash-6-mw-pressuring-logistics; C. Richard, “Vestas
tests new V162-6.0MW prototype wind turbine”, Windpower
Monthly, 8 October 2020, https://www.windpowermonthly.com/
article/1696691/vestas-tests-new-v162-60mw-prototype-wind-
turbine; C. Richard, “MingYang unveils new 6.25MW onshore
turbine”, Windpower Monthly, 16 October 2020, https://www.
windpowermonthly.com/article/1697454/mingyang-unveils-new-
625mw-onshore-turbine; Mingyang also launched a new 5.2
MW onshore turbine, from “MingYang unveils 5.2MW onshore
turbine”, reNEWS Biz, 28 July 2020, https://renews.biz/62013/
mingyang-unveils-52mw-onshore-turbine.
228 For example, D. Weston, “Enercon installs debut EP3 E2
prototype”, Windpower Monthly, 30 March 2020, https://www.
windpowermonthly.com/article/1678684/enercon-installs-
debut-ep3-e2-prototype; Richard, “Looking back on 2020”, op.
cit. note 227; C. Richard, “Goldwind unveils onshore turbines at
conference amid pandemic”, Windpower Monthly, 19 October
2020, https://www.windpowermonthly.com/article/1697610/
goldwind-unveils-onshore-turbines-conference-amid-pandemic.
For specific markets, Siemens Gamesa launched a turbine that
operates between 4 and 5 MW with low noise output to make it
suitable for locations with strict noise restrictions, from C. Richard,
“Siemens Gamesa unveils new low-wind turbine”, Windpower
Monthly, 12 November 2020, https://www.windpowermonthly.
com/article/1699928/siemens-gamesa-unveils-new-low-wind-
turbine; a new turbine by Vestas is specifically for low-wind
sites in China, from C. Richard, “First orders for Vestas low-wind
turbine”, Windpower Monthly, 4 March 2020, https://www.
windpowermonthly.com/article/1675887/first-orders-vestas-low-
wind-turbine; Siemens Gamesa Renewable Energy launched
a turbine for the Indian market, from “Indian prime minister
inaugurates 750MW solar project”, Power Technology, 10 July
2020, https://www.power-technology.com/news/narendra-modi-
inaugurates-750mw-solar-project-india, and K. Chandrasekaran,
340
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https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.windpowermonthly.com/article/1692957/read-windpower-monthly-online
https://www.utilitydive.com/news/a-big-wind-power-trend-you-may-have-never-heard-of-declining-specific-pow/530811
https://www.utilitydive.com/news/a-big-wind-power-trend-you-may-have-never-heard-of-declining-specific-pow/530811
https://www.utilitydive.com/news/a-big-wind-power-trend-you-may-have-never-heard-of-declining-specific-pow/530811
https://www.environmentalleader.com/2020/09/5-trends-shaping-the-wind-energy-industry
https://www.environmentalleader.com/2020/09/5-trends-shaping-the-wind-energy-industry
https://www.windpowermonthly.com/article/1704255/looking-back-2020-%E2%80%93-part-3-turbine-ratings-rotor-sizes-continue-go
https://www.windpowermonthly.com/article/1704255/looking-back-2020-%E2%80%93-part-3-turbine-ratings-rotor-sizes-continue-go
https://www.windpowermonthly.com/article/1704255/looking-back-2020-%E2%80%93-part-3-turbine-ratings-rotor-sizes-continue-go
https://www.windpowermonthly.com/article/1701374/ge-launches-6mw-onshore-wind-turbine
https://www.windpowermonthly.com/article/1701374/ge-launches-6mw-onshore-wind-turbine
https://www.windpowermonthly.com/article/1701374/ge-launches-6mw-onshore-wind-turbine
https://www.windpowermonthly.com/article/1694291/nordex-pushes-n149-5x-prototype-57mw
https://www.windpowermonthly.com/article/1694291/nordex-pushes-n149-5x-prototype-57mw
https://www.windpowermonthly.com/article/1684754/sgre-uses-offshore-experience-5x-onshore-platform-past-6mw
https://www.windpowermonthly.com/article/1684754/sgre-uses-offshore-experience-5x-onshore-platform-past-6mw
https://www.windpowermonthly.com/article/1684754/sgre-uses-offshore-experience-5x-onshore-platform-past-6mw
https://www.reutersevents.com/renewables/wind-energy-update/onshore-turbine-capacities-smash-6-mw-pressuring-logistics
https://www.reutersevents.com/renewables/wind-energy-update/onshore-turbine-capacities-smash-6-mw-pressuring-logistics
https://www.reutersevents.com/renewables/wind-energy-update/onshore-turbine-capacities-smash-6-mw-pressuring-logistics
https://www.windpowermonthly.com/article/1696691/vestas-tests-new-v162-60mw-prototype-wind-turbine
https://www.windpowermonthly.com/article/1696691/vestas-tests-new-v162-60mw-prototype-wind-turbine
https://www.windpowermonthly.com/article/1696691/vestas-tests-new-v162-60mw-prototype-wind-turbine
https://www.windpowermonthly.com/article/1697454/mingyang-unveils-new-625mw-onshore-turbine
https://www.windpowermonthly.com/article/1697454/mingyang-unveils-new-625mw-onshore-turbine
https://www.windpowermonthly.com/article/1697454/mingyang-unveils-new-625mw-onshore-turbine
https://renews.biz/62013/mingyang-unveils-52mw-onshore-turbine
https://renews.biz/62013/mingyang-unveils-52mw-onshore-turbine
https://www.windpowermonthly.com/article/1678684/enercon-installs-debut-ep3-e2-prototype
https://www.windpowermonthly.com/article/1678684/enercon-installs-debut-ep3-e2-prototype
https://www.windpowermonthly.com/article/1678684/enercon-installs-debut-ep3-e2-prototype
https://www.windpowermonthly.com/article/1697610/goldwind-unveils-onshore-turbines-conference-amid-pandemic
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https://www.windpowermonthly.com/article/1699928/siemens-gamesa-unveils-new-low-wind-turbine
https://www.windpowermonthly.com/article/1699928/siemens-gamesa-unveils-new-low-wind-turbine
https://www.windpowermonthly.com/article/1699928/siemens-gamesa-unveils-new-low-wind-turbine
https://www.windpowermonthly.com/article/1675887/first-orders-vestas-low-wind-turbine
https://www.windpowermonthly.com/article/1675887/first-orders-vestas-low-wind-turbine
https://www.windpowermonthly.com/article/1675887/first-orders-vestas-low-wind-turbine
https://www.power-technology.com/news/narendra-modi-inaugurates-750mw-solar-project-india
https://www.power-technology.com/news/narendra-modi-inaugurates-750mw-solar-project-india
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
“Siemens Gamesa wary of cut-throat projects of wind energy”,
Economic Times, 10 July 2020, https://economictimes.indiatimes.
com/industry/energy/power/siemens-gamesa-wary-of-cut-throat-
projects-of-wind-energy/articleshow/76895363.cms.
229 E. de Vries, “Goldwind prioritises larger rotors over higher
ratings to reduce LCoE”, Windpower Monthly, 20 November
2020, https://www.windpowermonthly.com/article/1700741/
goldwind-prioritises-larger-rotors-higher-ratings-reduce-lcoe.
230 See, for example, Pearcey, op. cit. note 227; P. Day,
“Inflatable blades, airships could leapfrog transport
barriers”, Reuters Events, 4 December 2019, https://www.
reutersevents.com/renewables/wind-energy-update/
inflatable-blades-airships-could-leapfrog-transport-barriers.
231 “Nordex starts up Spanish tower factory”, reNEWS Biz,
1 December 2020, https://www.renews.biz/64828/
nordex-starts-up-spanish-concrete-wind-tower-factory.
232 J. Calma, “GE will make taller wind turbines using
3D-printing”, The Verge, 17 June 2020, https://www.theverge.
com/2020/6/17/21293456/ge-200-meter-onshore-taller-wind-
turbines-3d-printing. Also in the United States, US-based Keystone
Tower Systems is developing an on-site spiral welding process that
should enable hub heights in excess of 180 metres, and Keystone
has received funding from the US DOE to demonstrate the
technology, from Pearcey, op. cit. note 227.
233 C. Richard, “World’s longest wind turbine blade gets
engineers’ approval”, Windpower Monthly, 10 November
2020, https://www.windpowermonthly.com/article/1699714/
worlds-longest-wind-turbine-blade-gets-engineers-approval.
234 GWEC, op. cit. note 224.
235 Ibid. The same has been true with gearbox suppliers, from GWEC,
op. cit. note 1, pp. 17-18.
236 “Wind turbine manufacturing plant in Arkansas to close”,
Associated Press, 14 April 2020, https://apnews.com/a0d444322
68a249271ba25ff208005e4; J. Parnell, “Siemens Gamesa cuts 266
jobs as onshore wind restructuring continues”, 14 January 2021,
https://www.greentechmedia.com/articles/read/siemens-gamesa-
cuts-266-jobs-as-onshore-rejig-continues; C. Richard, “Siemens
Gamesa slashes jobs at US blade factory”, Windpower Monthly,
15 September 2020, https://www.windpowermonthly.com/
article/1694512/siemens-gamesa-slashes-jobs-us-blade-factory.
See also B. Radowitz, “Cost cuts prompts GE’s LM Wind Power to
shut Danish blade plants”, Recharge, 27 February 2020, https://
www.rechargenews.com/wind/cost-cutting-prompts-ge-s-lm-
wind-to-shut-danish-plants/2-1-763424.
237 Average rated capacity of turbines delivered to market worldwide
in 2019 was 2,755 kW (averages of 2,603 kW onshore and 5,653
kW offshore), from Zhao, Lee and Lathigara , op. cit. note 211, and
2020 averages from Zhao, op. cit. note 7, 27 April 2021; figure of 2%
based on 2019 data from idem., both sources. Onshore, the largest
country averages were seen in Finland (4.5 MW), Chile (4.26 MW)
and Norway (4.2 MW), with averages exceeding 2.5 MW in all
other established markets – including China; offshore, the highest
average power ratings were in Belgium (8.71 MW), the Netherlands
(8.68 MW) and Portugal (8.4 MW). Across Europe, the average
per unit capacity of newly installed turbines in 2020 was 3.3 MW
onshore (with the most powerful in Finland, at 4.5 MW), and rose to
8.2 MW offshore, up from 7.2 MW in 2019. The average offshore in
China was 4.7 MW. All from Zhao, op. cit. note 7, 27 April 2021, and
China data are preliminary.
238 MHI Vestas, “Final turbine installed at Borssele III/IV in spite
of COVID-19”, 27 November 2020, https://mhivestasoffshore.
com/final-turbine-installed-at-borssele-iii-iv-in-spite-of-
covid-19. MHI Vestas was reacquired by Vestas and reintegrated
in late 2020, from Vestas, “Vestas and Mitsubishi Heavy
Industries close partnership agreement, and senior leaders
from joint venture take on new roles in Vestas”, 14 December
2020, https://www.vestas.com/en/media/company%20
news?l=62&n=3850009#!NewsView.
239 GWEC, op. cit. note 3, p. 7. The wind farms were Vindeby (total of
4.95 MW) and Tunø Knob (5 MW).
240 C. Richard, “GE upgrades Haliade-X prototype to 13MW”,
Windpower Monthly, 22 October 2020, https://www.
windpowermonthly.com/article/1698085/ge-upgrades-
haliade-x-prototype-13mw; M. Bates, “GE Renewable Energy
upgrades the Haliade-X wind turbine”, North American
Wind Power, 22 October 2020, https://nawindpower.com/
ge-upgrades-the-haliade-x-wind-turbine; C. Richard, “GE boosts
Haliade-X to 14MW for third Dogger Bank site”, Windpower
Monthly, 18 December 2020, https://www.windpowermonthly.com/
article/1703196/ge-boosts-haliade-x-14mw-third-dogger-bank-
site. GE Renewable Energy began building a factory in China to
produce Haliade-X 12 MW turbines starting in the second half of
2021, from GWEC, op. cit. note 3, p. 53. The 13 MW machine will be
248 metres tall with 107 metre blades, from GE Renewable Energy,
“Meet the Haliade-X 13 MW”, https://www.ge.com/news/sites/
default/files/2020-09/ge_haliade_x_horizontal_9_21_2020_0.
pdf, viewed 27 April 2021. GE received full certification for both the
12- and 13-MW Haliade-X in 2020, from GE, op. cit. note 214.
241 GWEC, op. cit. note 3, p. 81; Musial et al., op. cit. note 165, p. 61;
E. de Vries, “How SGRE upped the offshore stakes with 14MW+
turbine and 222m rotor”, Windpower Monthly, 19 May 2020,
https://www.windpowermonthly.com/article/1683570/sgre-
upped-offshore-stakes-14mw+-turbine-222m-rotor; A. Frangoul,
“Details released of a huge offshore wind turbine that can power
18,000 homes per year”, CNBC, 19 May 2020, https://www.cnbc.
com/2020/05/19/siemens-gamesa-releases-details-of-huge-
offshore-wind-turbine.html.
242 As of mid-2020, six Chinese turbine manufacturers had introduced
offshore models of 8 MW or larger, from GWEC, op. cit. note
3, p. 53; S. Campbell, “Dongfang due to install China’s first
10MW turbine”, Windpower Monthly, 25 June 2020, https://
www.windpowermonthly.com/article/1687749/dongfang-due-
install-chinas-first-10mw-turbine; C. Richard, “MingYang unveils
11MW turbine”, Windpower Monthly, 7 July 2020, https://www.
windpowermonthly.com/article/1688770/mingyang-unveils-11mw-
turbine; E. de Vries, “MingYang scale-up hybrid-drive technology to
supersize class”, Windpower Monthly, 2 September 2020. https://
www.windpowermonthly.com/article/1693241/mingyang-scales-
up-hybrid-drive-technology-supersize-class. Mingyang also aims
to develop a 10 MW floating model, from Y. Yu, “China’s Ming
Yang eyes 15MW offshore wind turbine after $850m fundraising”,
Recharge, 17 April 2020, https://www.rechargenews.com/wind/
chinas-ming-yang-eyes-15mw-offshore-wind-turbine-after-850m-
fundraising/2-1-793243.
243 E. De Vries, “Exclusive: How Vestas beat rivals to launch first 15MW
offshore turbine”, Windpower Monthly, 10 February 2021, https://
www.windpowermonthly.com/article/1706924/exclusive-vestas-
beat-rivals-launch-first-15mw-offshore-turbine. Vestas aims to
install prototype by mid-2022, from idem. Upgradeable from Zhao,
op. cit. note 7, 27 April 2021.
244 See, for example, K. Stromsta, “GE lands first orders for 12MW
offshore wind turbine, and they’re huge”, Greentech Media, 19
September 2019, https://www.greentechmedia.com/articles/read/
ge-wins-lands-first-big-deals-for-12mw-offshore-wind-turbine;
“The largest offshore wind project In the United States will use
Siemens Gamesa turbines”, Maritime Herald, 27 May 2020, https://
www.maritimeherald.com/2020/the-largest-offshore-wind-
project-in-the-united-states-will-use-siemens-gamesa-turbines;
GE, “GE Renewable Energy confirmed as preferred turbine supplier
for 1.2 GW third phase of Dogger Bank Wind Farm in the UK”,
18 December 2020, https://www.ge.com/news/press-releases/
ge-renewable-energy-confirmed-preferred-turbine-supplier-for-
third-phase-dogger-bank-wind-farm-uk; J. Murray, “More than
$16bn of wind turbine capacity ordered in second quarter of 2020”,
NS Energy, 14 October 2020, https://www.nsenergybusiness.com/
news/wind-turbine-capacity-2020.
245 B. Backwell, GWEC, “Take offshore wind global”, presentation for
Renewable Energy Institute, REvision – Webinar, 4 March 2020,
slide 10, https://www.renewable-ei.org/pdfdownload/activities/11_
BenBackwell ; WindEurope, Brussels, personal communication
with REN21, 29 March 2018; “Offshore wind operators use scale,
analytics to cut vessel trips”, New Energy Update, 7 March
2019, http://www.newenergyupdate.com/wind-energy-update/
offshore-wind-operators-use-scale-analytics-cut-vessel-trips;
Sawyer, op. cit. note 10, 30 March 2019; lower grid-connection
costs from P. Pragkos, E3 Modelling, personal communication
with REN21, 7 April 2019. For example, Vestas has said that using
its new V236-15.0 (15 MW) unit for a 900 MW wind plant, instead
of its previous V174-9.5 (9.5 MW) turbine, would increase annual
energy production by 5% with 34 fewer wind turbines, and without
the corresponding foundations and complicated offshore wind
construction, from Broehl, op. cit. note 70.
246 J. Parnell, “Total and Macquarie invest in 2.3GW portfolio of
floating wind projects in South Korea”, Greentech Media,
341
https://economictimes.indiatimes.com/industry/energy/power/siemens-gamesa-wary-of-cut-throat-projects-of-wind-energy/articleshow/76895363.cms
https://economictimes.indiatimes.com/industry/energy/power/siemens-gamesa-wary-of-cut-throat-projects-of-wind-energy/articleshow/76895363.cms
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https://www.windpowermonthly.com/article/1698085/ge-upgrades-haliade-x-prototype-13mw
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
1 September 2020, https://www.greentechmedia.com/articles/
read/total-and-macquarie-partner-on-worlds-first-full-scale-
floating-wind-projects; M. J. Coren, “Floating wind farms just
became a serious business”, Quartz, 22 June 2019, https://
qz.com/1650433/hywind-scotland-makes-floating-wind-farms-
a-serious-business; viable and economically attractive from
WindEurope, “Floating offshore wind vision statement” (Brussels:
June 2017), https://windeurope.org/wp-content/uploads/files/
about-wind/reports/Floating-offshore-statement ; stronger
and more consistent from Statoil, “World class performance by
world’s first floating wind farm”, press release (Stavanger, Norway:
15 February 2018), https://www.statoil.com/en/news/15feb2018-
world-class-performance.html; best winds rather than suitable
topography from Sawyer, op. cit. note 10, 20 April 2018.
247 GWEC, op. cit. note 3, pp. 22, 90.
248 A. McCorkell, “MHI Vestas installs ‘most powerful’ floating offshore
wind turbine”, Windpower Monthly, 11 November 2020, https://
www.windpowermonthly.com/article/1699782/mhi-vestas-installs-
most-powerful-floating-offshore-wind-turbine; MHI Vestas, “First
ever V164-9.5 MW turbine installed on a floating wind project”, 11
November 2020, https://mhivestasoffshore.com/first-ever-v164-
9-5-mw-turbine-installed-on-a-floating-wind-project. It was the
first of five at the 50 MW Kincardine Offshore Windfarm, from idem,
both sources. There are three main types of bases, all derived from
experience in the oil and gas industry, but efforts continued to
develop a common platform that can host ocean energy, solar PV
and power-to-x generation technologies as well as wind turbines,
from GWEC, op. cit. note 3, p. 87.
249 For example, Ørsted was leading a group of Danish companies to
develop a hydrogen production facility, from D. Weston, “Industry’s
hydrogen experiment steps up a gear”, Windpower Monthly, 26
May 2020, https://www.windpowermonthly.com/article/1684230/
industrys-hydrogen-experiment-steps-gear. Vattenfall, RWE,
Equinor and Enel unveiled plans in 2020 for research or to
develop projects to use electricity to produce other fuels (energy
carriers), from Richard, “Looking back on 2020”, op. cit. note 120;
A. McCorkell, “RWE and Equinor back ‘groundbreaking’ NortH2
green hydrogen project”, Windpower Monthly, 7 December 2020,
https://www.windpowermonthly.com/article/1702060/rwe-
equinor-back-groundbreaking-north2-green-hydrogen-project; H.
O’Brian, “Enel prepares to produce green hydrogen”, Windpower
Monthly, 15 June 2020, https://www.windpowermonthly.com/
article/1686321/enel-prepares-produce-green-hydrogen. The
NortH2 project off the coast of the Netherlands aims to power
electrolysis of seawater into hydrogen to be used in industry, from
“Japan and EU race to develop ‘green hydrogen’”, Nikkei Asia, 11
January 2021, https://asia.nikkei.com/Spotlight/Environment/
Climate-Change/Japan-and-EU-race-to-develop-green-
hydrogen2. In addition, as of early 2020, discussions were under
way between countries in northern Africa and the European
Commission about using wind energy for industrial purposes,
including the production of ammonia in Morocco to manufacture
fertiliser using local phosphates, from K. Benhamou, Sahara Wind,
presentation for WWEA, “Webinar: Wind power markets around
the world”, 16 April 2020, https://wwindea.org/blog/2020/04/08/
webinar-wind-power-markets-around-the-world.
250 Siemens Energy and Siemens Gamesa, “Joint press release from
Siemens Gamesa and Siemens Energy”, press release (Vizcaya,
Spain: 13 January 2021), https://www.siemensgamesa.com/en-int/-/
media/siemensgamesa/downloads/en/newsroom/2021/01/
siemens-gamesa-press-release-agreement-siemens-energy-green-
hydrogen-en ; C. Steitz, T. Käckenhoff and V. Eckert, “Exclusive:
Siemens spin-offs tap hydrogen boom in wind alliance”, Reuters, 13
January 2021, https://www.reuters.com/article/us-siemens-gamesa-
r-siemens-energ-windpo/exclusive-siemens-gamesa-siemens-
energy-tap-hydrogen-boom-in-wind-alliance-idUSKBN29I12Z.
251 See, for example, J. Parnell, “Shell’s latest offshore wind bid
would power a huge green hydrogen cluster”, Greentech Media,
7 May 2020, https://www.greentechmedia.com/articles/read/
latest-shell-offshore-wind-bid-would-power-green-hydrogen-
cluster; B. Radowitz, “Dutch zero-subsidy offshore wind tender
on despite coronavirus”, Recharge, 17 March 2020, https://www.
rechargenews.com/wind/dutch-zero-subsidy-offshore-wind-
tender-on-despite-coronavirus/2-1-775751; Westwood Global
Energy Group, “Scaling Rrnewables: The converging world of
oil & gas and the clean energy supermajors”, 15 February 2021,
https://www.westwoodenergy.com/news/westwood-insight/
scaling-renewables.
252 Significant investment in the sector from Backwell and Mullin,
op. cit. note 3; knowledge and skills transfer from Westwood
Global Energy Group, op. cit. note 251, and V. Kretzschmar,
Wood Mackenzie, “Why are oil majors investing in offshore
wind?” Forbes, 6 April 2021, https://www.forbes.com/sites/
woodmackenzie/2021/04/06/why-are-oil-majors-investing-
in-offshore-wind. See also GWEC, op. cit. note 3, pp. 88-89;
J. Parnell, “Equinor: Floating wind farms a natural fit for oil
and gas companies”, Greentech Media, 6 February 2020,
https://www.greentechmedia.com/articles/read/floating-
wind-is-cutting-costs-faster-than-regular-offshore-wind;
B. Magill, “Oil industry eyed as catalyst for floating offshore
wind”, Bloomberg Environment, 13 June 2019, https://news.
bloombergenvironment.com/environment-and-energy/
oil-industry-eyed-as-catalyst-for-floating-offshore-wind.
253 S. Lassen, N. Valentine and V. Kretzschmar, “How Big Oil is
set to transform the offshore wind sector”, Wood Mackenzie,
5 April 2021, https://www.woodmac.com/news/opinion/
how-big-oil-is-set-to-transform-the-offshore-wind-sector.
254 Ibid.
255 Total from J. Parnell, “Germany and France, Europe’s economic
giants, bulk up offshore wind ambitions”, Greentech Media, 4
June 2020, https://www.greentechmedia.com/articles/read/
europes-heavy-hitters-bulk-up-their-offshore-wind-arsenals; M.
Holder, “Total wades into UK floating wind sector with Simply
Blue Energy partnership”, Business Green, 19 March 2020, https://
www.businessgreen.com/news/4012737/total-wades-uk-floating-
wind-sector-simply-blue-energy-partnership; Total, “Renewables:
Total enters floating offshore wind with a first project in the UK”,
20 March 2020, https://www.total.uk/renewables-total-enters-
floating-offshore-wind-first-project-uk, Parnell, op. cit. note 246;
Eni, “Eni enters the UK offshore wind market”, press release (Rome:
4 December 2020), https://www.eni.com/en-IT/media/press-
release/2020/12/eni-enteres-uk-offshore-wind-market.html.
256 “Offshore wind energy potential in Brazil attracts Equinor and
Neoenergia”, Brazil Energy Insight, 25 November 2020, https://
brazilenergyinsight.com/2020/11/25/offshore-wind-energy-
potential-in-brazil-attracts-equinor-and-neoenergia; J. Parnell,
“BP makes offshore wind debut, partnering with Equinor in US
market”, Greentech Media, 10 September 2020, https://www.
greentechmedia.com/articles/read/bp-and-equinor-partner-
up-for-us-offshore-wind; “BP and Equinor cement US offshore
wind partnership”, reNEWS Biz, 29 January 2021, https://renews.
biz/66134/bp-and-equinor-cement-us-offshore-wind-partnership.
257 Shell partnering in projects from, for example, J. Parnell, “Super-
Hybrid: Dutch offshore wind farm to include floating solar, batteries
and hydrogen”, Greentech Media, 29 July 2020, https://www.
greentechmedia.com/articles/read/shell-jv-wins-dutch-offshore-
wind-tender-with-continuous-power-hybrid-project; “Shell joins
floating wind project offshore Ireland”, Offshore Engineer, 29
January 2021, https://www.oedigital.com/news/484925-shell-
joins-floating-wind-project-offshore-ireland. Shell and TetraSpar,
from W. Mathis, “Inventor of wind turbine is trying to harness
unlimited power”, BNN Bloomberg, 5 June 2020, https://www.
bnnbloomberg.ca/inventor-of-wind-turbine-is-trying-to-harness-
unlimited-power-1.1446122. Benefits of TetraSpar foundation
from Shell, “Wind power”, https://www.shell.com/energy-and-
innovation/new-energies/wind.html, viewed 14 March 2021.
258 M. Mazengarb, “Huge 1,100MW offshore wind farm proposed in
W.A. by oil explorer”, RenewEconomy, 4 September 2020, https://
reneweconomy.com.au/huge-1100mw-offshore-wind-farm-
proposed-in-w-a-by-oil-explorer-55055.
259 Some Chinese utility companies are moving into offshore wind,
from GWEC, op. cit. note 3, pp. 88-89. Japan’s TEPCO signed a
memorandum of understanding with developer Ørsted to work
jointly on offshore wind projects in Japan and elsewhere, from
idem, p. 61. Partnerships also were launched between Kyushu
Electric Power Company (Japan) and RWE, J Power (Japan) and
Engie, and Tokyo Gas Company and Principle Power (US) to focus
on offshore wind, from idem, p. 62. In Europe, examples include
RWE Renewables (Germany), Iberdrola (Spain), EDF (France),
EnBW (Germany), EDP (Portugal) and ENGIE (France), from idem,
pp. 88-89. In the United States, RWE and Mitsubishi acquired
a floating demonstration project off the coast of Maine, from K.
Stromsta, “Maine’s $100M floating offshore wind project finds major
backers: RWE and Mitsubishi”, Greentech Media, 5 August 2020,
https://www.greentechmedia.com/articles/read/maines-floating-
offshore-wind-project-scores-major-backers-rwe-and-mitsubishi.
342
https://www.greentechmedia.com/articles/read/total-and-macquarie-partner-on-worlds-first-full-scale-floating-wind-projects
https://www.greentechmedia.com/articles/read/total-and-macquarie-partner-on-worlds-first-full-scale-floating-wind-projects
https://www.greentechmedia.com/articles/read/total-and-macquarie-partner-on-worlds-first-full-scale-floating-wind-projects
https://qz.com/1650433/hywind-scotland-makes-floating-wind-farms-a-serious-business
https://qz.com/1650433/hywind-scotland-makes-floating-wind-farms-a-serious-business
https://qz.com/1650433/hywind-scotland-makes-floating-wind-farms-a-serious-business
https://windeurope.org/wp-content/uploads/files/about-wind/reports/Floating-offshore-statement
https://windeurope.org/wp-content/uploads/files/about-wind/reports/Floating-offshore-statement
https://www.statoil.com/en/news/15feb2018-world-class-performance.html
https://www.statoil.com/en/news/15feb2018-world-class-performance.html
https://www.windpowermonthly.com/article/1699782/mhi-vestas-installs-most-powerful-floating-offshore-wind-turbine
https://www.windpowermonthly.com/article/1699782/mhi-vestas-installs-most-powerful-floating-offshore-wind-turbine
https://www.windpowermonthly.com/article/1699782/mhi-vestas-installs-most-powerful-floating-offshore-wind-turbine
https://mhivestasoffshore.com/first-ever-v164-9-5-mw-turbine-installed-on-a-floating-wind-project
https://mhivestasoffshore.com/first-ever-v164-9-5-mw-turbine-installed-on-a-floating-wind-project
https://www.windpowermonthly.com/article/1684230/industrys-hydrogen-experiment-steps-gear
https://www.windpowermonthly.com/article/1684230/industrys-hydrogen-experiment-steps-gear
https://www.windpowermonthly.com/article/1702060/rwe-equinor-back-groundbreaking-north2-green-hydrogen-project
https://www.windpowermonthly.com/article/1702060/rwe-equinor-back-groundbreaking-north2-green-hydrogen-project
https://www.windpowermonthly.com/article/1686321/enel-prepares-produce-green-hydrogen
https://www.windpowermonthly.com/article/1686321/enel-prepares-produce-green-hydrogen
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/Japan-and-EU-race-to-develop-green-hydrogen2
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/Japan-and-EU-race-to-develop-green-hydrogen2
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/Japan-and-EU-race-to-develop-green-hydrogen2
https://wwindea.org/blog/2020/04/08/webinar-wind-power-markets-around-the-world
https://wwindea.org/blog/2020/04/08/webinar-wind-power-markets-around-the-world
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/newsroom/2021/01/siemens-gamesa-press-release-agreement-siemens-energy-green-hydrogen-en
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/newsroom/2021/01/siemens-gamesa-press-release-agreement-siemens-energy-green-hydrogen-en
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/newsroom/2021/01/siemens-gamesa-press-release-agreement-siemens-energy-green-hydrogen-en
https://www.siemensgamesa.com/en-int/-/media/siemensgamesa/downloads/en/newsroom/2021/01/siemens-gamesa-press-release-agreement-siemens-energy-green-hydrogen-en
https://www.reuters.com/article/us-siemens-gamesa-r-siemens-energ-windpo/exclusive-siemens-gamesa-siemens-energy-tap-hydrogen-boom-in-wind-alliance-idUSKBN29I12Z
https://www.reuters.com/article/us-siemens-gamesa-r-siemens-energ-windpo/exclusive-siemens-gamesa-siemens-energy-tap-hydrogen-boom-in-wind-alliance-idUSKBN29I12Z
https://www.reuters.com/article/us-siemens-gamesa-r-siemens-energ-windpo/exclusive-siemens-gamesa-siemens-energy-tap-hydrogen-boom-in-wind-alliance-idUSKBN29I12Z
https://www.greentechmedia.com/articles/read/latest-shell-offshore-wind-bid-would-power-green-hydrogen-cluster
https://www.greentechmedia.com/articles/read/latest-shell-offshore-wind-bid-would-power-green-hydrogen-cluster
https://www.greentechmedia.com/articles/read/latest-shell-offshore-wind-bid-would-power-green-hydrogen-cluster
https://www.rechargenews.com/wind/dutch-zero-subsidy-offshore-wind-tender-on-despite-coronavirus/2-1-775751
https://www.rechargenews.com/wind/dutch-zero-subsidy-offshore-wind-tender-on-despite-coronavirus/2-1-775751
https://www.rechargenews.com/wind/dutch-zero-subsidy-offshore-wind-tender-on-despite-coronavirus/2-1-775751
https://www.westwoodenergy.com/news/westwood-insight/scaling-renewables
https://www.westwoodenergy.com/news/westwood-insight/scaling-renewables
https://www.forbes.com/sites/woodmackenzie/2021/04/06/why-are-oil-majors-investing-in-offshore-wind
https://www.forbes.com/sites/woodmackenzie/2021/04/06/why-are-oil-majors-investing-in-offshore-wind
https://www.forbes.com/sites/woodmackenzie/2021/04/06/why-are-oil-majors-investing-in-offshore-wind
https://www.greentechmedia.com/articles/read/floating-wind-is-cutting-costs-faster-than-regular-offshore-wind
https://www.greentechmedia.com/articles/read/floating-wind-is-cutting-costs-faster-than-regular-offshore-wind
https://news.bloombergenvironment.com/environment-and-energy/oil-industry-eyed-as-catalyst-for-floating-offshore-wind
https://news.bloombergenvironment.com/environment-and-energy/oil-industry-eyed-as-catalyst-for-floating-offshore-wind
https://news.bloombergenvironment.com/environment-and-energy/oil-industry-eyed-as-catalyst-for-floating-offshore-wind
https://www.woodmac.com/news/opinion/how-big-oil-is-set-to-transform-the-offshore-wind-sector
https://www.woodmac.com/news/opinion/how-big-oil-is-set-to-transform-the-offshore-wind-sector
https://www.greentechmedia.com/articles/read/europes-heavy-hitters-bulk-up-their-offshore-wind-arsenals
https://www.greentechmedia.com/articles/read/europes-heavy-hitters-bulk-up-their-offshore-wind-arsenals
https://www.businessgreen.com/news/4012737/total-wades-uk-floating-wind-sector-simply-blue-energy-partnership
https://www.businessgreen.com/news/4012737/total-wades-uk-floating-wind-sector-simply-blue-energy-partnership
https://www.businessgreen.com/news/4012737/total-wades-uk-floating-wind-sector-simply-blue-energy-partnership
https://www.total.uk/renewables-total-enters-floating-offshore-wind-first-project-uk
https://www.total.uk/renewables-total-enters-floating-offshore-wind-first-project-uk
https://www.eni.com/en-IT/media/press-release/2020/12/eni-enteres-uk-offshore-wind-market.html
https://www.eni.com/en-IT/media/press-release/2020/12/eni-enteres-uk-offshore-wind-market.html
https://brazilenergyinsight.com/2020/11/25/offshore-wind-energy-potential-in-brazil-attracts-equinor-and-neoenergia
https://brazilenergyinsight.com/2020/11/25/offshore-wind-energy-potential-in-brazil-attracts-equinor-and-neoenergia
https://brazilenergyinsight.com/2020/11/25/offshore-wind-energy-potential-in-brazil-attracts-equinor-and-neoenergia
https://www.greentechmedia.com/articles/read/bp-and-equinor-partner-up-for-us-offshore-wind
https://www.greentechmedia.com/articles/read/bp-and-equinor-partner-up-for-us-offshore-wind
https://www.greentechmedia.com/articles/read/bp-and-equinor-partner-up-for-us-offshore-wind
https://renews.biz/66134/bp-and-equinor-cement-us-offshore-wind-partnership
https://renews.biz/66134/bp-and-equinor-cement-us-offshore-wind-partnership
https://www.greentechmedia.com/articles/read/shell-jv-wins-dutch-offshore-wind-tender-with-continuous-power-hybrid-project
https://www.greentechmedia.com/articles/read/shell-jv-wins-dutch-offshore-wind-tender-with-continuous-power-hybrid-project
https://www.greentechmedia.com/articles/read/shell-jv-wins-dutch-offshore-wind-tender-with-continuous-power-hybrid-project
https://www.oedigital.com/news/484925-shell-joins-floating-wind-project-offshore-ireland
https://www.oedigital.com/news/484925-shell-joins-floating-wind-project-offshore-ireland
https://www.bnnbloomberg.ca/inventor-of-wind-turbine-is-trying-to-harness-unlimited-power-1.1446122
https://www.bnnbloomberg.ca/inventor-of-wind-turbine-is-trying-to-harness-unlimited-power-1.1446122
https://www.bnnbloomberg.ca/inventor-of-wind-turbine-is-trying-to-harness-unlimited-power-1.1446122
https://www.shell.com/energy-and-innovation/new-energies/wind.html
https://www.shell.com/energy-and-innovation/new-energies/wind.html
https://reneweconomy.com.au/huge-1100mw-offshore-wind-farm-proposed-in-w-a-by-oil-explorer-55055
https://reneweconomy.com.au/huge-1100mw-offshore-wind-farm-proposed-in-w-a-by-oil-explorer-55055
https://reneweconomy.com.au/huge-1100mw-offshore-wind-farm-proposed-in-w-a-by-oil-explorer-55055
https://www.greentechmedia.com/articles/read/maines-floating-offshore-wind-project-scores-major-backers-rwe-and-mitsubishi
https://www.greentechmedia.com/articles/read/maines-floating-offshore-wind-project-scores-major-backers-rwe-and-mitsubishi
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ENDNOTES · MARKE T AND INDUSTRY TRENDS · WIND POWER
260 India from C. Richard, “India energy giants to form renewables JV”,
Windpower Monthly, 22 May 2020, https://www.windpowermonthly.
com/article/1684088/indian-energy-giants-form-renewables-jv.
The companies are India’s Oil and Natural Gas Corporation
and utility National Thermal Power Corporation, from idem. For
additional examples, see W. Mathis, “Inventor of wind turbine is
trying to harness unlimited power”, Bloomberg News, 5 June 2020,
https://www.bnnbloomberg.ca/inventor-of-wind-turbine-is-trying-
to-harness-unlimited-power-1.1446122; D. McPhee, “Balmoral
plots move into floating offshore wind market”, Energy Voice, 2
March 2020, https://www.energyvoice.com/otherenergy/225772/
balmoral-plots-move-into-floating-offshore-wind-market.
261 A. Lee, “Five big problems for offshore wind: Angry birds, grumpy
neighbours and more”, Recharge, 7 September 2020, https://
www.rechargenews.com/wind/five-big-problems-for-offshore-
wind-angry-birds-grumpy-neighbours-and-more/2-1-870639;
A. McCorkell, “Warning over heavy lift vessel ‘bottleneck’
for offshore wind”, Windpower Monthly, 26 November 2020,
https://www.windpowermonthly.com/article/1701220/
warning-heavy-lift-vessel-bottleneck-offshore-wind; J. Calma,
“The US offshore wind boom will depend on these ships”, The
Verge, 23 Feb 2021, https://www.theverge.com/22296979/
us-offshore-ships-wind-boom-installation-vessels.
262 McCorkell, op. cit. note 261.
263 GWEC, op. cit. note 3, pp. 21, 27, 42, 73, 79; GWEC, Global Wind
Report 2019, op. cit. note 11, p. 60; N. Ford, “Orsted deal with US utility
sets up offshore growth surge”, New Energy Update, 20 February
2019, http://www.newenergyupdate.com/wind-energy-update/
orsted-deal-us-utility-sets-offshore-growth-surge.
264 Stromsta, op. cit. note 210; K. Stromsta, ”New York issues second
offshore wind solicitation, overcoming coronavirus delays”,
Greentech Media, 21 July 2020, https://www.greentechmedia.com/
articles/read/new-york-fights-through-coronavirus-delays-to-
issue-second-offshore-wind-solicitation; K. Stromsta, “New Jersey
to build nation’s largest offshore wind port”, Greentech Media, 16
June 2020, https://www.greentechmedia.com/articles/read/new-
jersey-announces-plans-for-nations-largest-offshore-wind-port; T.
Bergeron, “N.J. announced $250M manufacturing facility for wind
energy components at Paulsboro Marine Terminal”, ROI-NJ, 22
December 2020, https://www.roi-nj.com/2020/12/22/industry/
energy-utilities/n-j-announces-250m-manufacturing-facility-for-
wind-energy-components-at-paulsboro-marine-terminal. States
include Connecticut, Maryland, New York, New Jersey, Virginia,
Massachusetts, from idem, all sources. Worker training from,
for example, “NJ spending $6M for wind and other clean energy
projects”, Associated Press News, 9 September 2020, https://
apnews.com/bd4d238a3e5ad681fea3bb5f59ee4efd. For more
on challenges in the United States, also see “U.S. offshore wind
vessel demand set to soar”, Marine Link, 2 March 2021, https://
www.marinelink.com/news/abs-us-offshore-wind-vessel-demand-
set-485668; IEA, op. cit. note 54.
265 See other endnotes for this paragraph. Repowering explanation in
footnote based on information from WindEurope, Decommissioning
of Onshore Wind Turbines: Industry Guidance Document (Brussels:
November 2020), p. 7, https://windeurope.org/data-and-analysis/
product/decommissioning-of-onshore-wind-turbines, and from H.
K. Trabish, “Zombie wind and solar? How repowering old facilities
helps renewables keep cutting costs”, Utility Dive, 26 October 2016,
https://www.utilitydive.com/news/zombie-wind-and-solar-how-
repowering-old-facilities-helps-renewables-keep/429047.
266 See, for example, CanWEA, “Decommissioning/
Repowering a wind farm”, https://canwea.ca/communities/
decommissioningrepowering-wind-farm, viewed 9 May 2020; GE
Renewable Energy, “Upgrades and refurbishment for your onshore
wind assets: Repowering and life extension for older onshore wind
turbines”, https://www.ge.com/renewableenergy/wind-energy/
onshore-wind/services/upgrades-refurbishment, viewed 9 May
2020; K. Centera, “Six factors to consider before repowering a wind
site”, Windpower Engineering & Development, 25 February 2019,
https://www.windpowerengineering.com/business-news-projects/
six-factors-to-consider-before-repowering-a-wind-site.
267 K. Blunt, “Utilities cash in on green energy subsidy for bigger wind
farms”, Wall Street Journal, 16 August 2020, https://www.wsj.com/
articles/utilities-cash-in-on-green-energy-subsidy-for-bigger-wind-
farms-11597579201; F. Jossi, “Wind developers are retrofitting newer
projects with bigger, better blades”, Wall Street Journal, 4 February
2021, https://energynews.us/2021/02/04/midwest/wind-developers-
are-retrofitting-newer-projects-with-bigger-better-blades.
268 ACPA, op. cit. note 58, pp. 4, 8. Partial repowering totalled 2,899 MW
in 2020, 3,008 MW in 2019, 1,269 MW in 2018 and 2,077 MW in 2017,
from idem.
269 Blunt, op. cit. note 267; Jossi, op. cit. note 267.
270 Germany from Deutsche WindGuard, op. cit. note 120, p. 4; all
Europe data also from WindEurope, op. cit. note 6, p. 17.
271 Komusanac, op. cit. note 13; Reve, “Wind energy in China,
repowering with larger wind turbines”, Evwind, 17 December
2019, https://www.evwind.es/2019/12/17/wind-energy-in-china-
repowering-with-larger-wind-turbines/72555.
272 Most blades are made of resin and fibreglass, from C. Stella,
“As wind energy thrives, so does its waste problem”, NET News
and Harvest Public Media, 31 August 2019, http://netnebraska.
org/article/news/1188411/wind-energy-thrives-so-does-its-
waste-problem; difficult and expensive from NREL, “Greening
industry: Building recyclable, next-generation turbine blades”,
21 April 2020, https://www.nrel.gov/news/program/2020/
greening-industry.html; C. Richard, “Blade recycling remains
challenges, says WindEurope”, Windpower Monthly, 27 May
2020, https://www.windpowermonthly.com/article/1684326/
blade-recycling-remains-challenge-says-windeurope. About
85-90% of dismantled turbines can be recycled – towers,
foundations, generators and gearboxes can be broken down
into concrete, steel, cast iron and recycled – but not blades,
from J. Agyepong-Parsons, “GE signs deal to use old turbine
blades in cement production”, Windpower Monthly, 8 December
2020, https://www.windpowermonthly.com/article/1702248/
ge-signs-deal-use-old-turbine-blades-cement-production.
273 Sound barriers from “Sharpening-up blade recycling”, Windpower
Monthly, 4 February 2020, https://www.windpowermonthly.com/
article/1672913/sharpening-up-blade-recycling; Richard, op. cit.
note 272; “GE and Veolia team up to provide wind turbine blade
recycling”, Renewable Energy World, 12 August 2020, https://www.
renewableenergyworld.com/wind-power/ge-and-veolia-team-
up-to-provide-wind-turbine-blade-recycling; Agyepong-Parsons,
op. cit. note 272; different materials from C. Richard, “Cross-sector
group developing ‘100% recyclable’ blade”, Windpower Monthly,
23 September 2020, https://www.windpowermonthly.com/
article/1695250/cross-sector-group-developing-100-recyclable-
blade. See also NREL, “NREL advanced manufacturing research
moves wind turbine blades toward recyclability”, press release
(Golden, CO: 17 November 2020), https://www.nrel.gov/news/
press/2020/nrel-advanced-manufacturing-research-moves-wind-
turbine-blades-toward-recyclability.html.
274 “GE and Veolia team up to provide wind turbine blade recycling”,
Renewable Energy World, 12 August 2020, https://www.
renewableenergyworld.com/wind-power/ge-and-veolia-team-up-
to-provide-wind-turbine-blade-recycling; Agyepong-Parsons, op.
cit. note 272. One turbine blade that weighs about 7 tonnes and
is recycled through this process enables Veolia’s cement kiln to
avoid consuming almost 5 tonnes of coal, about 2.5 tonnes of silica,
nearly 2 tonnes of limestone and almost 1 tonne of other mineral-
based raw materials, from idem. Innovationsfonden, “DecomBlades
consortium awarded funding for a large, cross-sector wind turbine
blade recycling project”, https://innovationsfonden.dk/da/nyheder-
presse-og-job/decomblades-consortium-awarded-funding-
large-cross-sector-wind-turbine-blade, viewed 4 May 2021;
Vestas, “DecomBlades consortium awarded funding for a large,
cross-sector wind turbine blade recycling project”, press release
(Aarhus: 25 January 2021), https://www.vestas.com/en/media/
blog/sustainability/20210125_decomblades; IRT Jules Verne,
“L’IRT Jules Verne et un consortium d’acteurs industriels lancent
le projet ZEBRA dédiéaudéveloppementde paleséoliennesen
matériauxcomposites 100% recyclables”, press release (Nantes:
23 September 2020), https://www.irt-jules-verne.fr/wp-content/
uploads/06_IRT-JULES-VERNE_CP-ZEBRA_FR_vfinale ;
Richard, op. cit. note 273; NREL, “Advanced thermoplastic resins
for manufacturing wind turbine blades”, https://www.nrel.gov/
manufacturing/comet-wind-blade-resin.html, viewed 26 April 2021;
J. S. Hill, “US research identifies new resin material to make wind
turbine recycling easier”, RenewEconomy, 25 November 2020,
https://reneweconomy.com.au/us-research-identifies-new-resin-
material-to-make-wind-turbine-recycling-easier-76316.
275 T. Gualtieri and L. M. Lombrana, “Making wind turbines greener
could also make them more expensive”, Bloomberg, 11 February 2021,
https://www.bloomberg.com/news/articles/2021-02-11/making-
wind-turbines-greener-could-also-make-them-more-expensive.
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https://www.bloomberg.com/news/articles/2021-02-11/making-wind-turbines-greener-could-also-make-them-more-expensive
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276 Siemens Gamesa Renewable Energy (SGRE), “Achieving a
better future – committed to sustainable development”, https://
www.siemensgamesa.com/sustainability, viewed 4 May 2020;
SGRE, “DecomBlades consortium awarded funding for a large,
cross sector wind turbine blade recycling project”, press release
(Madrid: 25 January 2021), https://www.siemensgamesa.com/
en-int/newsroom/2021/01/210125-siemens-gamsa-press-release-
decomblades-launched; SGRE, Consolidated Non-Financial
Statement 2019 (former Sustainability Report) (Vizcaya, Spain: 2019),
p. 3, https://www.siemensgamesa.com/-/media/siemensgamesa/
downloads/en/sustainability/siemens-gamesa-consolidated-non-
financial-statement-2019-en . See also D. Snieckus, “Siemens
Gamesa tackles wind supply chain emissions in net-zero strategy
step-up”, Recharge, 23 April 2020, https://www.rechargenews.
com/transition/siemens-gamesa-tackles-wind-supply-chain-
emissions-in-net-zero-strategy-step-up/2-1-796565.
277 RE100, “Vestas”, http://there100.org/vestas, viewed 13 May 2020;
A. Lee, “Wind power giant Vestas sets 2030 carbon-neutral
goal”, Recharge, 6 January 2020, https://www.rechargenews.
com/wind/wind-power-giant-vestas-sets-2030-carbon-neutral-
goal/2-1-732261; WindEurope, “Circular economy: Blade recycling
is a top priority for the wind industry”, 12 February 2020, https://
windeurope.org/newsroom/news/blade-recycling-a-top-priority-for-
the-wind-industry; C. Richard, “Vestas plans ‘zero-waste turbines’
by 2040”, 20 January 2020, https://www.windpowermonthly.com/
article/1671285/vestas-plans-zero-waste-turbines-2040.
278 Envision, “Envision promises to be operation-level carbon neutral
by 2022, value chain carbon neutral by 2028: Envision’s first carbon
neutrality report”, press release (Shanghai: 23 April 2021), https://
markets.businessinsider.com/news/stocks/envision-promises-to-be-
operation-level-carbon-neutral-by-2022-value-chain-carbon-neutral-
by-2028-envision-s-first-carbon-neutrality-report-1030338427.
279 Box 7 based on the following sources: uses of small-scale
turbines from WWEA, 2017 Small Wind World Report Summary
(Bonn: June 2017), p. 5, from A. Orrell et al., 2016 Distributed
Wind Market Report (Richland, WA: Pacific Northwest National
Laboratory (PNNL), August 2017), p. i, https://energy.gov/sites/
prod/files/2017/08/f35/2016-Distributed-Wind-Market-Report.
pdf, from US DOE, “Small wind electric systems”, https://www.
energy.gov/energysaver/save-electricity-and-fuel/buying-
and-making-electricity/small-wind-electric-systems, viewed
19 April 2021, from G. McKay and W. Mathis, “In a world of big
wind, there’s still a place for tiny turbines”, Bloomberg, 2 April
2021, https://www.bloomberg.com/news/articles/2021-04-02/
in-a-world-of-big-wind-there-s-still-a-place-for-tiny-turbines,
and from Australian Renewable Energy Agency (ARENA), “Small
wind turbines solving big problems”, 19 November 2020, https://
arena.gov.au/blog/small-wind-turbines-solving-big-problems.
Small-scale wind power descriptions and capacity limits in
footnote from WWEA, op. cit. this note, and from US DOE, Office
of Energy Efficiency & Renewable Energy (EERE), 2018 Offshore
Wind Technologies Market Report (Washington, DC: August
2019), p. 1, https://www.energy.gov/sites/prod/files/2019/09/
f66/2018%20Offshore%20Wind%20Technologies%20Market%20
Report . Market shrinkage from information and sources
throughout this box; inconsistent policy support and local
permitting laws (also perceived noise and aesthetic impacts)
from A. Orrell, PNNL, cited in J. Gerdes, “Struggling distributed
wind sector eyes role in microgrids market”, Greentech Media,
28 April 2020, https://www.greentechmedia.com/articles/read/
distributed-wind; planning laws also from P. Crossley, University
of Sydney, Sydney, personal communication with REN21, 9 April
2021; competition from solar PV from McKay and Mathis, op. cit.
this note, and from Gerdes, op. cit. this note; 42.5 MW added in
six countries in 2019 from J-D. Pitteloud, WWEA, Bonn, personal
communication with REN21, April 2021; 47 MW in 2018 from US
DOE, EERE, 2018 Distributed Wind Market Report, p. iv; the 114
MW in 2017 was installed in a documented 10 countries, from US
DOE, EERE, 2017 Distributed Wind Market Report (Washington,
DC: 2018), p. 9, https://www.energy.gov/sites/prod/files/2018/09/
f55/2017-DWMR-091918-final . Lack of data and no off-grid
systems included from Pitteloud, op. cit. this note. The WWEA
estimates that more than 1 million small-scale turbines were in
operation at the end of 2019, totalling at least 3 GW of capacity,
but data are difficult to estimate and official numbers from Italy,
Japan, United Kingdom and the United States include only
grid-connected capacity, from Pitteloud, op. cit. this note; total
global small-scale wind power capacity was estimated to be at
least 1.7 GW at end-2018, from US DOE, EERE, 2018 Distributed
Wind Market Report (Washington, DC: 2019), p. 12, https://www.
energy.gov/sites/prod/files/2019/08/f65/2018%20Distributed%20
Wind%20Market%20Report , and more recent data are not
available from this source. Data for China, Denmark, Germany,
Japan and the United Kingdom from Pitteloud, op. cit. this note.
China saw a slight annual increase in 2018, but installations were
down substantially relative to previous year, from CWEA, cited in
US DOE, EERE, 2018 Distributed Wind Market Report, op. cit. this
note, p. 13. US capacity additions in 2019 and retrofits from A. Orrell
et al., 2019 Distributed Wind Data Summary (Richland, WA: PNNL,
August 2020), pp. 3, 20, https://www.pnnl.gov/sites/default/
files/media/file/2019%20Distributed%20Wind%20Data%20
Summary-10Aug20 . The United States added 2,167 units in
2019, from PNNL, “2019 Distributed Wind Data Summary”, Excel
Data Tables, 6 August 2020, Figure 14, https://www.pnnl.gov/
distributed-wind, viewed 19 April 2021. US installations in 2019
were down from 1.5 MW (2,661 units) in 2018, 1.7 MW (3,269 units)
in 2017, 2.4 MW in 2016, and 4.3 MW in 2015, from US DOE, EERE,
2017 Distributed Wind Market Report, op. cit. this note, pp. iv, 8, 9.
However, per unit sales of units <1 kW continued to increase in the
United States during 2019, from idem, p. 21. Japan projects under
FIT, from Japan Small Wind Turbines Association, https://www.
meti.go.jp/shingikai/sankoshin/hoan_shohi/denryoku_anzen/
newenergy_hatsuden_wg/pdf/018_01_03 (in Japanese), with
data provided by Pitteloud, op. cit. this note. Shrinking markets
and sharp decline in number of producers in China and United
States, from PNNL, “2019 Distributed Wind Data Summary”, Excel
Data Tables, op. cit. this note, and see past coverage of small-scale
wind in previous editions of the GSR for longer-term trends. US
exports in 2019 totalled 475 kW, down steadily from 2015, when
exports totaled 21,446 kW; exports were 937 kW in 2018, 5,541
kW in 2017, and 10,322 kW in 2016, from PNNL, “2019 Distributed
Wind Data Summary”, Excel Data Tables, op. cit. this note. Key
markets dried up, from A. Orrell et al., 2019 Distributed Wind Data
Summary, op. cit. this note, p. 9. US domestic sales from PNNL,
“2019 Distributed Wind Data Summary”, Excel Data Tables, op.
cit. this note. Sales early in the decade were, for example, 19.2 MW
in 2010 and 15.2 MW in 2011, from idem. Looking up and role of
tax credit and US R&D efforts from Gerdes, op. cit. this note, and
from US DOE, EERE, “Microgrids, Infrastructure Resilience, and
Advanced Controls Launchpad”, February 2020, https://www.
energy.gov/sites/prod/files/2020/03/f72/miracl-fact-sheet-v2.
pdf. See also US DOE, EERE, “Distributed wind competitiveness
improvement project helps manufacturers develop, certify next-gen
technologies”, 19 November 2019, https://www.energy.gov/eere/
articles/distributed-wind-competitiveness-improvement-project-
helps-manufacturers-develop. US R&D on plug-and-play, from US
DOE, EERE, “Microgrids, Infrastructure Resilience, and Advanced
Controls Launchpad”, op. cit. this note. Italy FIT incentive and
market data, from Pitteloud, op. cit. this note. The incentive offers
a tariff of EUR 150 (USD 184.3) per MWh for 20 years and uses
a registry and quota system. The main difference from previous
policies is that small-scale wind and solar PV must compete for
the 770 MW available, from idem. For further details, see GSE,
“Accesso agli incentivi”, https://www.gse.it/servizi-per-te/fonti-
rinnovabili/fer-elettriche/incentivi-dm-04-07-2019, viewed 27
April 2021 (in Italian); and GSE, “Tariffe incentivanti di riferimento,
vita utile e premi stabiliti dal DM 2019”,https://www.gse.it/servizi-
per-te_site/fonti-rinnovabili_site/fer-elettriche_site/Documents/
TAB1_dmfer2019 , viewed 27 April 2021 (in Italian). Start-up
companies from, for example: McKay and Mathis, op. cit. this note;
Diffuse Energy, “Smarter wind generation”, https://www.diffuse-
energy.com, viewed 27 April 2021; Alpha 311, “Local renewable
energy for the world”, https://alpha-311.com/, viewed 27 April 2021.
New uses from ARENA, op. cit. this note.
280 Sidebar 6 and Figure 37 based on IRENA, Renewable Electricity
Generation Costs in 2020 (Abu Dhabi: 2021) and IRENA, personal
communication with REN21, May 2021.
344
https://www.siemensgamesa.com/sustainability
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https://www.siemensgamesa.com/-/media/siemensgamesa/downloads/en/sustainability/siemens-gamesa-consolidated-non-financial-statement-2019-en
https://www.siemensgamesa.com/-/media/siemensgamesa/downloads/en/sustainability/siemens-gamesa-consolidated-non-financial-statement-2019-en
https://www.siemensgamesa.com/-/media/siemensgamesa/downloads/en/sustainability/siemens-gamesa-consolidated-non-financial-statement-2019-en
https://www.rechargenews.com/transition/siemens-gamesa-tackles-wind-supply-chain-emissions-in-net-zero-strategy-step-up/2-1-796565
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https://www.rechargenews.com/transition/siemens-gamesa-tackles-wind-supply-chain-emissions-in-net-zero-strategy-step-up/2-1-796565
http://there100.org/vestas
https://www.rechargenews.com/wind/wind-power-giant-vestas-sets-2030-carbon-neutral-goal/2-1-732261
https://www.rechargenews.com/wind/wind-power-giant-vestas-sets-2030-carbon-neutral-goal/2-1-732261
https://www.rechargenews.com/wind/wind-power-giant-vestas-sets-2030-carbon-neutral-goal/2-1-732261
https://windeurope.org/newsroom/news/blade-recycling-a-top-priority-for-the-wind-industry
https://windeurope.org/newsroom/news/blade-recycling-a-top-priority-for-the-wind-industry
https://windeurope.org/newsroom/news/blade-recycling-a-top-priority-for-the-wind-industry
https://www.windpowermonthly.com/article/1671285/vestas-plans-zero-waste-turbines-2040
https://www.windpowermonthly.com/article/1671285/vestas-plans-zero-waste-turbines-2040
https://markets.businessinsider.com/news/stocks/envision-promises-to-be-operation-level-carbon-neutral-by-2022-value-chain-carbon-neutral-by-2028-envision-s-first-carbon-neutrality-report-1030338427
https://markets.businessinsider.com/news/stocks/envision-promises-to-be-operation-level-carbon-neutral-by-2022-value-chain-carbon-neutral-by-2028-envision-s-first-carbon-neutrality-report-1030338427
https://markets.businessinsider.com/news/stocks/envision-promises-to-be-operation-level-carbon-neutral-by-2022-value-chain-carbon-neutral-by-2028-envision-s-first-carbon-neutrality-report-1030338427
https://markets.businessinsider.com/news/stocks/envision-promises-to-be-operation-level-carbon-neutral-by-2022-value-chain-carbon-neutral-by-2028-envision-s-first-carbon-neutrality-report-1030338427
https://energy.gov/sites/prod/files/2017/08/f35/2016-Distributed-Wind-Market-Report
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https://www.energy.gov/energysaver/save-electricity-and-fuel/buying-and-making-electricity/small-wind-electric-systems
https://www.energy.gov/energysaver/save-electricity-and-fuel/buying-and-making-electricity/small-wind-electric-systems
https://www.energy.gov/energysaver/save-electricity-and-fuel/buying-and-making-electricity/small-wind-electric-systems
https://www.bloomberg.com/news/articles/2021-04-02/in-a-world-of-big-wind-there-s-still-a-place-for-tiny-turbines
https://www.bloomberg.com/news/articles/2021-04-02/in-a-world-of-big-wind-there-s-still-a-place-for-tiny-turbines
https://arena.gov.au/blog/small-wind-turbines-solving-big-problems
https://arena.gov.au/blog/small-wind-turbines-solving-big-problems
https://www.energy.gov/sites/prod/files/2019/09/f66/2018%20Offshore%20Wind%20Technologies%20Market%20Report
https://www.energy.gov/sites/prod/files/2019/09/f66/2018%20Offshore%20Wind%20Technologies%20Market%20Report
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https://www.greentechmedia.com/articles/read/distributed-wind
https://www.greentechmedia.com/articles/read/distributed-wind
https://www.energy.gov/sites/prod/files/2018/09/f55/2017-DWMR-091918-final
https://www.energy.gov/sites/prod/files/2018/09/f55/2017-DWMR-091918-final
https://www.energy.gov/sites/prod/files/2019/08/f65/2018%20Distributed%20Wind%20Market%20Report
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https://www.energy.gov/sites/prod/files/2019/08/f65/2018%20Distributed%20Wind%20Market%20Report
https://www.pnnl.gov/sites/default/files/media/file/2019%20Distributed%20Wind%20Data%20Summary-10Aug20
https://www.pnnl.gov/sites/default/files/media/file/2019%20Distributed%20Wind%20Data%20Summary-10Aug20
https://www.pnnl.gov/sites/default/files/media/file/2019%20Distributed%20Wind%20Data%20Summary-10Aug20
https://www.pnnl.gov/distributed-wind
https://www.pnnl.gov/distributed-wind
https://www.meti.go.jp/shingikai/sankoshin/hoan_shohi/denryoku_anzen/newenergy_hatsuden_wg/pdf/018_01_03
https://www.meti.go.jp/shingikai/sankoshin/hoan_shohi/denryoku_anzen/newenergy_hatsuden_wg/pdf/018_01_03
https://www.meti.go.jp/shingikai/sankoshin/hoan_shohi/denryoku_anzen/newenergy_hatsuden_wg/pdf/018_01_03
https://www.energy.gov/sites/prod/files/2020/03/f72/miracl-fact-sheet-v2
https://www.energy.gov/sites/prod/files/2020/03/f72/miracl-fact-sheet-v2
https://www.energy.gov/sites/prod/files/2020/03/f72/miracl-fact-sheet-v2
https://www.energy.gov/eere/articles/distributed-wind-competitiveness-improvement-project-helps-manufacturers-develop
https://www.energy.gov/eere/articles/distributed-wind-competitiveness-improvement-project-helps-manufacturers-develop
https://www.energy.gov/eere/articles/distributed-wind-competitiveness-improvement-project-helps-manufacturers-develop
https://www.gse.it/servizi-per-te/fonti-rinnovabili/fer-elettriche/incentivi-dm-04-07-2019
https://www.gse.it/servizi-per-te/fonti-rinnovabili/fer-elettriche/incentivi-dm-04-07-2019
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https://www.diffuse-energy.com
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ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
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1 Figure 38 from International Energy Agency (IEA) et al., Tracking
SDG 7: The Energy Progress Report (World Bank, Washington,
DC: 2021), https://trackingsdg7.esmap.org/downloads, and from
A. Whiteman, International Renewable Energy Agency (IRENA),
personal communication with Renewable Energy Policy Network
for the 21st Century (REN21), 31 March 2021.
2 World Health Organization (WHO), “Household air pollution”, 8
May 2018, https://www.who.int/news-room/fact-sheets/detail/
household-air-pollution-and-health.
3 IRENA, IEA and REN21, Renewable Energy Policies in a Time of
Transition: Heating and Cooling (Abu Dhabi and Paris: 2020),
https://www.ren21.net/wp-content/uploads/2019/05/IRENA_
IEA_REN21-Policies_HC_2020_Full_Report .
4 Ibid.
5 Sustainable Energy for All (SEforALL), Chilling Prospects: Tracking
Sustainable Cooling for All 2020 (Vienna: 2020), https://www.
seforall.org/system/files/2020-07/CP-2020-SEforALL .
6 Ibid.
7 A. Pozzer et al., “Regional and global contributions of air pollution
to risk of death from COVID-19”, Cardiovascular Research, vol. 116,
no. 14 (2020), pp. 2247-53, https://doi.org/10.1093/cvr/cvaa288.
While this study looked at urban air pollution, the findings should
equally (if not more) apply to indoor air pollution as it is also
caused by particulate matter.
8 Box 8 from the following sources: 4 million deaths from WHO,
op. cit. note 2, and from US Centers for Disease Control and
Prevention, “Covid-19 – people with certain medical conditions”,
1 December 2020, https://www.cdc.gov/coronavirus/2019-ncov/
need-extra-precautions/people-with-medical-conditions.
html; 60% of healthcare facilities from R. Cronk and J. Bartram,
“Environmental conditions in health care facilities in low-
and middle-income countries: Coverage and inequalities”,
International Journal of Hygiene and Environmental Health,
vol. 221, no. 3 (2018), pp. 409-22, https://doi.org/10.1016/j.
ijheh.2018.01.004; rural sub-Saharan Africa from IEA et al.,
Tracking SDG 7: The Energy Progress Report (Washington, DC:
2020), https://trackingsdg7.esmap.org/downloads; T. Peters and
B. Hartley, “Sustainable cold chains needed for equitable COVID-
19 distribution”, SEforALL, 12 November 2020, https://www.
seforall.org/news/sustainable-cold-chains-needed-for-equitable-
covid-19-vaccine-distribution; WHO, “Direct-drive solar vaccine
refrigerators – a new choice for vaccine storage” (Geneva: May
2013), https://www.who.int/immunization/programmes_systems/
supply_chain/optimize/direct_drive_solar_vaccine_refrigerator.
pdf; Efficiency for Access, “An interview with Dr. Karan Sagar
from Gavi, the vaccine alliance”, 30 June 2020, https://medium.
com/efficiency-for-access/an-interview-with-dr-karan-sagar-
from-gavi-the-vaccine-alliance-fe01b45d5a68; N. Lewis, “How
solar tech could help distribute Covid-19 vaccines in Africa”,
CNN, 15 January 2021, https://edition.cnn.com/2021/01/14/africa/
africa-covid-vaccine-cold-chain-spc-intl/index.html; US Agency
for International Development (USAID), “Power Africa Covid-19
response”, https://www.usaid.gov/powerafrica/coronavirus,
viewed 4 March 2021.
9 V. Castán Broto and J. Kirshner, “Energy access is needed
to maintain health during pandemics”, Nature Energy, vol. 5
(2020), pp. 419-21, https://www.nature.com/articles/s41560-
020-0625-6; B. Ieri and W. Mathai, “Energy access is key to
sub-Saharan Africa’s economic recovery”, World Resources
Institute, 3 February 2021, https://www.wri.org/insights/
energy-access-key-sub-saharan-africas-economic-recovery.
10 IEA et al., op. cit. note 1.
11 IEA, “Access to electricity”, https://www.iea.org/reports/sdg7-
data-and-projections/access-to-electricity#abstract, viewed 6
December 2020.
12 IEA, “The Covid-19 crisis is reversing progress on energy access
in Africa”, 20 November 2020, https://www.iea.org/articles/the-
covid-19-crisis-is-reversing-progress-on-energy-access-in-africa.
13 IEA, op. cit. note 11.
14 Ibid.
15 IEA et al., op. cit. note 8.
16 Ibid.
17 Ibid.
18 Ibid.
19 Ibid.
20 IEA, “Defining energy access: 2020 methodology”, https://www.
iea.org/articles/defining-energy-access-2020-methodology,
viewed 4 December 2020.
21 Ibid.
22 Energy Sector Management Assistance Program (ESMAP), The
State of Access to Modern Cooking Energy Services (Washington,
DC: World Bank, 2020), http://documents.worldbank.org/curated/
en/937141600195758792/The-State-of-Access-to-Modern-
Energy-Cooking-Services. The report looked at six dimensions:
availability, affordability, exposure, efficiency, convenience and
safety, based on the World Bank’s Multi-Tier Framework. Tier 4
(on a scale of 0 to 5) is considered as having reached access to
modern energy cooking services.
23 Ibid.
24 Figure 39 from Ibid.
25 IEA et al., op. cit. note 1.
26 Ibid.
27 Ibid.
28 IEA, “Electricity access database”, https://iea.blob.core.windows.
net/assets/93fd1a56-5c8f-4209-ba6e-7f6ff9fffb19/WEO2020-
Electricityaccessdatabase.xlsx, viewed 6 December 2020.
29 Ibid.
30 Ibid.
31 Ibid.
32 Ibid.
33 Ibid.
34 Ibid.
35 Ibid.
36 Ibid.
37 IEA et al., op. cit. note 8.
38 IEA, “Data and statistics: Electricity generation by fuel Indonesia”,
https://www.iea.org/data-and-statistics?country=INDONESIA&
fuel=Energy%20supply&indicator=ElecGenByFuel, viewed
8 November 2020.
39 IEA, “Data and statistics: Electricity generation by fuel India”, https://
www.iea.org/data-and-statistics?country=INDIA&fuel=Electricity
%20and%20heat&indicator=ElecGenByFuel, viewed 5 April 2021.
40 IEA, “Data and statistics: Electricity generation by fuel Bangladesh”,
https://www.iea.org/data-and-statistics?country=BANGLADESH&
fuel=Electricity%20and%20heat&indicator=ElecGenByFuel, viewed
28 April 2021.
41 IEA, “Data and statistics: Electricity generation by fuel Cambodia”,
https://www.iea.org/data-and-statistics?country=CAMBODIA&
fuel=Energy%20supply&indicator=ElecGenByFuel, viewed
8 November 2020; IEA, “SDG7: Data and projections, access to
electricity”, https://www.iea.org/reports/sdg7-data-and-projections/
access-to-electricity#abstract, viewed 28 April 2021.
42 IEA, “Data and statistics: Electricity generation by fuel Ethiopia”, https://
www.iea.org/data-and-statistics?country=ETHIOPIA&fuel=Energy%20
supply&indicator=ElecGenByFuel, viewed 8 November 2020.
43 IEA, “Data and statistics: Electricity generation by fuel Kenya”, https://
www.iea.org/data-and-statistics?country=KENYA&fuel=Energy%20
supply&indicator=ElecGenByFuel, viewed 8 November 2020.
44 Whiteman, op. cit. note 1.
45 Energy for Growth Hub, “Raising global energy ambitions: The
1000 kWh modern energy minimum”, 26 January 2021, https://
www.energyforgrowth.org/report/modern-energy-minimum.
46 Afrobarometer, “Progress toward ‘reliable energy for all’ stalls
across Africa, Afrobarometer survey finds”, press release (Accra:
5 December 2019),https://afrobarometer.org/sites/default/files/
publications/Dispatches/ab_r6_dispatchno75_electricity_in_
africa_eng1 .
47 Populations at “high risk” are characterised by no access to
electricity, low incomes and other factors, from the framework
developed in SEforALL, op. cit. note 5.
48 Ibid.
49 Ibid.
345
https://trackingsdg7.esmap.org/downloads
https://www.who.int/news-room/fact-sheets/detail/household-air-pollution-and-health
https://www.who.int/news-room/fact-sheets/detail/household-air-pollution-and-health
https://www.ren21.net/wp-content/uploads/2019/05/IRENA_IEA_REN21-Policies_HC_2020_Full_Report
https://www.ren21.net/wp-content/uploads/2019/05/IRENA_IEA_REN21-Policies_HC_2020_Full_Report
https://www.seforall.org/system/files/2020-07/CP-2020-SEforALL
https://www.seforall.org/system/files/2020-07/CP-2020-SEforALL
https://doi.org/10.1093/cvr/cvaa288
https://www.cdc.gov/coronavirus/2019-ncov/need-extra-precautions/people-with-medical-conditions.html
https://www.cdc.gov/coronavirus/2019-ncov/need-extra-precautions/people-with-medical-conditions.html
https://www.cdc.gov/coronavirus/2019-ncov/need-extra-precautions/people-with-medical-conditions.html
https://doi.org/10.1016/j.ijheh.2018.01.004
https://doi.org/10.1016/j.ijheh.2018.01.004
https://trackingsdg7.esmap.org/downloads
https://www.seforall.org/news/sustainable-cold-chains-needed-for-equitable-covid-19-vaccine-distribution
https://www.seforall.org/news/sustainable-cold-chains-needed-for-equitable-covid-19-vaccine-distribution
https://www.seforall.org/news/sustainable-cold-chains-needed-for-equitable-covid-19-vaccine-distribution
https://www.who.int/immunization/programmes_systems/supply_chain/optimize/direct_drive_solar_vaccine_refrigerator
https://www.who.int/immunization/programmes_systems/supply_chain/optimize/direct_drive_solar_vaccine_refrigerator
https://www.who.int/immunization/programmes_systems/supply_chain/optimize/direct_drive_solar_vaccine_refrigerator
https://medium.com/efficiency-for-access/an-interview-with-dr-karan-sagar-from-gavi-the-vaccine-alliance-fe01b45d5a68
https://medium.com/efficiency-for-access/an-interview-with-dr-karan-sagar-from-gavi-the-vaccine-alliance-fe01b45d5a68
https://medium.com/efficiency-for-access/an-interview-with-dr-karan-sagar-from-gavi-the-vaccine-alliance-fe01b45d5a68
https://edition.cnn.com/2021/01/14/africa/africa-covid-vaccine-cold-chain-spc-intl/index.html
https://edition.cnn.com/2021/01/14/africa/africa-covid-vaccine-cold-chain-spc-intl/index.html
https://www.usaid.gov/powerafrica/coronavirus
https://www.nature.com/articles/s41560-020-0625-6
https://www.nature.com/articles/s41560-020-0625-6
https://www.wri.org/insights/energy-access-key-sub-saharan-africas-economic-recovery
https://www.wri.org/insights/energy-access-key-sub-saharan-africas-economic-recovery
https://www.iea.org/reports/sdg7-data-and-projections/access-to-electricity#abstract
https://www.iea.org/reports/sdg7-data-and-projections/access-to-electricity#abstract
https://www.iea.org/articles/the-covid-19-crisis-is-reversing-progress-on-energy-access-in-africa
https://www.iea.org/articles/the-covid-19-crisis-is-reversing-progress-on-energy-access-in-africa
https://www.iea.org/articles/defining-energy-access-2020-methodology
https://www.iea.org/articles/defining-energy-access-2020-methodology
http://documents.worldbank.org/curated/en/937141600195758792/The-State-of-Access-to-Modern-Energy-Cooking-Services
http://documents.worldbank.org/curated/en/937141600195758792/The-State-of-Access-to-Modern-Energy-Cooking-Services
http://documents.worldbank.org/curated/en/937141600195758792/The-State-of-Access-to-Modern-Energy-Cooking-Services
https://iea.blob.core.windows.net/assets/93fd1a56-5c8f-4209-ba6e-7f6ff9fffb19/WEO2020-Electricityaccessdatabase.xlsx
https://iea.blob.core.windows.net/assets/93fd1a56-5c8f-4209-ba6e-7f6ff9fffb19/WEO2020-Electricityaccessdatabase.xlsx
https://iea.blob.core.windows.net/assets/93fd1a56-5c8f-4209-ba6e-7f6ff9fffb19/WEO2020-Electricityaccessdatabase.xlsx
https://www.iea.org/data-and-statistics?country=INDONESIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=INDONESIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=INDIA&fuel=Electricity%20and%20heat&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=INDIA&fuel=Electricity%20and%20heat&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=INDIA&fuel=Electricity%20and%20heat&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=BANGLADESH&fuel=Electricity%20and%20heat&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=BANGLADESH&fuel=Electricity%20and%20heat&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=CAMBODIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=CAMBODIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/reports/sdg7-data-and-projections/access-to-electricity#abstract
https://www.iea.org/reports/sdg7-data-and-projections/access-to-electricity#abstract
https://www.iea.org/data-and-statistics?country=ETHIOPIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=ETHIOPIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=ETHIOPIA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=KENYA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=KENYA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.iea.org/data-and-statistics?country=KENYA&fuel=Energy%20supply&indicator=ElecGenByFuel
https://www.energyforgrowth.org/report/modern-energy-minimum
https://www.energyforgrowth.org/report/modern-energy-minimum
https://afrobarometer.org/sites/default/files/publications/Dispatches/ab_r6_dispatchno75_electricity_in_africa_eng1
https://afrobarometer.org/sites/default/files/publications/Dispatches/ab_r6_dispatchno75_electricity_in_africa_eng1
https://afrobarometer.org/sites/default/files/publications/Dispatches/ab_r6_dispatchno75_electricity_in_africa_eng1
ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
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S50 SEforAll, op. cit. note 5.
51 Ibid.
52 Ibid.
53 Ibid.
54 IRENA, Off-Grid Renewable Energy Solutions to Expand Electricity
Access (Abu Dhabi: 2019), https://www.irena.org/-/media/Files/
IRENA/Agency/Publication/2019/Jan/IRENA_Off-grid_RE_
Access_2019 .
55 REN21, Renewables Global Status Report 2020 (Paris: 2020),
http://ren21.net/gsr-2020.
56 Energising Development (EnDev), “COVID-19 Energy Access
Industry Barometer – presentation of results in a webinar hosted
by EnDev”, 7 August 2020, https://endev.info/covid-19-energy-
access-industry-barometer-presentation-of-results-in-a-webinar-
hosted-by-endev.
57 Ibid.
58 Ibid.
59 D. Corbyn and L. Fortes, “2020: Off-grid solar investment remains
robust during Covid-19 pandemic”, GOGLA, 21 March 2021,
https://www.gogla.org/about-us/blogs/2020-off-grid-solar-
investment-remains-robust-during-covid-19-pandemic.
60 ESMAP, op. cit. note 22.
61 Ibid.
62 Ibid.
63 Ibid.
64 Ibid.
65 World Bank, Household Cookstoves, Environment, Health and
Climate Change (Washington, DC: 2011), https://openknowledge.
worldbank.org/handle/10986/27589.
66 WHO, Burning Opportunity: Clean Household Energy for
Health, Sustainable Development, and Wellbeing of Women and
Children (Geneva: 2016), https://apps.who.int/iris/bitstream/
handle/10665/204717/9789241565233_eng .
67 Infrastructure Development Company Limited (IDCOL),
“Improved cookstove program”, https://idcol.org/home/ics,
viewed 26 March 2021.
68 EnDev, Accelerating Uptake of Pico PV Systems and High Tier
Cookstoves in Kenya Through Results-Based Financing (Eschborn,
Germany: 2020), https://endev.info/wp-content/uploads/2021/01/
pico-PV_systems_and_high_tier_cookstoves_in_Kenya_through_
RBF_report .
69 EnDev, “SNV EnDev Cookstoves RBF facility”, fact sheet
(Eschborn, Germany: 2020), https://snv.org/cms/sites/default/
files/explore/download/endev_kenya_stoves_rbf_factsheet_
aug_2020 .
70 IRENA, Biogas for Domestic Cooking: Technology Brief (Abu
Dhabi: 2017), https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2017/Dec/IRENA_Biogas_for_domestic_
cooking_2017 .
71 Whiteman, op. cit. note 1.
72 Figure 40 from Ibid; population data from World Bank, DataBank,
"Population estimates and projections", https://databank.
worldbank.org/source/population-estimates-and-projections/
Type/TABLE/preview/on#, viewed 7 May 2021.
73 Ibid.
74 H. Clemens, Hivos, personal communication with REN21, 15
February 2021.
75 Fair and Sustainable Consulting, African Biogas Partnership
Programme Phase 2 Effect Evaluation, Final Report (Louvain-La-
Neuve, Belgium: 2019),https://www.government.nl/binaries/
government/documents/reports/2019/05/13/africa-biogas-
partnership-programme-abpp-phase-2---effect-evaluation/
Africa+Biogas+Partnership+Programme .
76 Clemens, op. cit. note 74.
77 ESMAP, Cooking with Electricity: A Cost Perspective, Report Summary
(Washington, DC: World Bank, 2020), http://documents1.worldbank.
org/curated/en/121371601050459132/pdf/Report-Summary .
78 H. Blair, “Accelerating the uptake of electric pressure cookers on
mini-grids in Tanzania”, CLASP, 8 June 2020, https://clasp.ngo/
updates/2020/accelerating-the-uptake-of-electric-pressure-
cookers-on-mini-grids-in-tanzania; ESMAP, op. cit. note 77.
79 ESMAP, op. cit. note 77.
80 Efficiency for Access Coalition, 2021 Appliance Data Trends
(January 2021), https://storage.googleapis.com/e4a-website-
assets/2021-ApplianceDataTrends .
81 Global Leap Awards, “Electric pressure cookers”, https://globalleap
awards.org/electric-pressure-cookers, viewed 7 March 2021.
82 Solar Cookers International, “Distribution of solar cookers”,
https://www.solarcookers.org/partners/distribution-solar-
cookers, viewed 7 March 2021.
83 GOGLA, Global Off-Grid Solar Market Report Semi-Annual Sales
and Impact Data, January – June 2020 (Amsterdam: 2020),
https://www.gogla.org/sites/default/files/resource_docs/
global_off_grid_solar_market_report_h1_2020 .
84 GOGLA, Global Off-Grid Solar Market Report Semi-Annual Sales
and Impact Data, July – December 2020 (Amsterdam: 2020),
https://www.gogla.org/sites/default/files/resource_docs/
global_off-grid_solar_market_report_h2_2020 .
85 Ibid.
86 REN21, op. cit. note 55.
87 GOGLA, op. cit. note 84.
88 Ibid.
89 Ibid.
90 Ibid.
91 Ibid.
92 Ibid.
93 Ibid.
94 Ibid.
95 Ibid.
96 Ibid.
97 Ibid.
98 Ibid.
99 Figure 41 from Ibid.
100 Ibid.
101 REN21, op. cit. note 55.
102 GOGLA, op. cit. note 84.
103 REN21, op. cit. note 55.
104 ESMAP, Mini-Grids for Half a Billion People (Washington, DC: World
Bank, 2019), https://esmap.org/mini_grids_for_half_a_billion_people.
105 Mini-Grids Partnership, State of the Global Mini-Grids Market
2020 (London: BloombergNEF and SEforALL, 2020), https://
minigrids.org/market-report-2020.
106 Figure 42 from Ibid.
107 Ibid.
108 Africa Minigrid Developers Association (AMDA), Benchmarking
Africa’s Mini-Grids (Nairobi: 2020), https://africamda.org/
wp-content/uploads/2020/11/AMDA-Benchmarking-2020- .
109 Ibid.
110 Ibid.
111 Husk Power Systems, “Husk Power Systems – first minigrid
company to cover 100 communities & 5,000 small business
customers”, press release (Fort Collins, CO: 10 December 2020),
https://huskpowersystems.com/husk-power-systems-first-
minigrid-company-to-power-100-communities-5000-small-
business-customers.
112 Mini-Grids Partnership, op. cit. note 105.
113 Ibid.
114 Africa Solar Industry Association, Africa Solar Outlook 2021
(Kigali: February 2021), http://afsiasolar.com/wp-content/
uploads/2021/02/AFSIA-Africa-Solar-Outlook-2021-final-2 .
115 Ibid.
116 Rural Electrification Agency (REA), “Nigeria electrification project
(NEP) solar hybrid mini grids component”, http://rea.gov.ng/
minigrids, viewed 18 February 2021.
117 Ibid.
118 J. M. Takouleu, “Nigeria: Renewvia connects two solar
mini-hybrid grids in Bayelsa State”, Afrik21, 4 June 2020,
https://www.afrik21.africa/en/nigeria-renewvia-connects-
two-solar-mini-hybrid-grids-in-bayelsa-state; REA,
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https://www.gogla.org/about-us/blogs/2020-off-grid-solar-investment-remains-robust-during-covid-19-pandemic
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http://documents1.worldbank.org/curated/en/121371601050459132/pdf/Report-Summary
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https://clasp.ngo/updates/2020/accelerating-the-uptake-of-electric-pressure-cookers-on-mini-grids-in-tanzania
https://clasp.ngo/updates/2020/accelerating-the-uptake-of-electric-pressure-cookers-on-mini-grids-in-tanzania
https://clasp.ngo/updates/2020/accelerating-the-uptake-of-electric-pressure-cookers-on-mini-grids-in-tanzania
https://storage.googleapis.com/e4a-website-assets/2021-ApplianceDataTrends
https://storage.googleapis.com/e4a-website-assets/2021-ApplianceDataTrends
https://globalleapawards.org/electric-pressure-cookers
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https://www.solarcookers.org/partners/distribution-solar-cookers
https://www.solarcookers.org/partners/distribution-solar-cookers
https://www.gogla.org/sites/default/files/resource_docs/global_off_grid_solar_market_report_h1_2020
https://www.gogla.org/sites/default/files/resource_docs/global_off_grid_solar_market_report_h1_2020
https://www.gogla.org/sites/default/files/resource_docs/global_off-grid_solar_market_report_h2_2020
https://www.gogla.org/sites/default/files/resource_docs/global_off-grid_solar_market_report_h2_2020
https://esmap.org/mini_grids_for_half_a_billion_people
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http://rea.gov.ng/minigrids
http://rea.gov.ng/minigrids
https://www.afrik21.africa/en/nigeria-renewvia-connects-two-solar-mini-hybrid-grids-in-bayelsa-state
https://www.afrik21.africa/en/nigeria-renewvia-connects-two-solar-mini-hybrid-grids-in-bayelsa-state
ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
DI
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D
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W
AB
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FO
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EN
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GY
A
CC
ES
S“Shimankar Community welcomes solar electricity”, press
release (Lagos: 3 December 2020), https://rea.gov.ng/
press-release-shimankar-community-welcomes-solar-electricity.
119 REA, “Solar power Naija”, e-news, December 2020, https://
mailchi.mp/rea.gov.ng/enews-dec2020.
120 USAID, “Power Africa Covid-19 response”, https://www.usaid.
gov/powerafrica/coronavirus, viewed 24 March 2021.
121 Nextier Power, “SustainSolar to install 7 containerised mini-grids
for OnePower in Lesotho”, Nigeria Electricity, 4 November 2020,
https://www.nigeriaelectricityhub.com/2020/11/04/sustainsolar-to-
install-7-containerised-solar-mini-grids-for-onepower-in-lesotho.
122 J. M. Takouleu, “Benin: 11 companies selected for 8 mini solar grids
projects in rural areas”, Afrik21, 16 July 2020, https://www.afrik21.
africa/en/benin-11-companies-selected-for-8-mini-solar-grids-
projects-in-rural-areas.
123 I. Magoum, “Togo: 129 localities soon to be electrified via
mini-grids”, Afrik21, 5 February 2021, https://www.afrik21.africa/
en/togo-129-localities-soon-to-be-electrified-via-mini-grids;
“Senegal’s ASER launches a call for tenders for 133 solar mini
grids in rural areas”, Energy Mix Report, 11 January 2021, https://
www.energymixreport.com/senegals-aser-launches-a-call-for-
tenders-for-133-solar-mini-grids-in-rural-areas.
124 AMDA, op. cit. note 108.
125 J. M. Takouleu, “Kenya: Renewvia commissions 3 mini-grids in
Turkana and Marsabit countries”, Afrik21, 11 June 2020, https://
www.afrik21.africa/en/kenya-renewvia-commissions-3-mini-
grids-in-turkana-and-marsabit-counties.
126 J. M. Takouleu, “Kenya: Kenya Power wants to hybridise 23 mini
diesel grids with solar and wind power”, Afrik21, 8 February 2021,
https://www.afrik21.africa/en/kenya-kenya-power-wants-to-
hybridise-23-mini-diesel-grids-with-solar-and-wind-power.
127 J. M. Takouleu, “DRC: Nuru connects 1.3 MW solar off-grid hybrid
in Goma”, Afrik21, 8 February 2020, https://www.afrik21.africa/en/
drc-nuru-connects-1-3-mw-solar-off-grid-hybrid-in-goma.
128 Sustainable and Renewable Energy Development Authority
(SREDA), “National database of renewable energy”, https://ndre.
sreda.gov.bd/index.php?id=1&i=5, viewed 18 February 2021.
129 Ibid.
130 S. Maradona, “La energía del sol llevará luz a dos parajes
inhóspitos de la estepa”, Rio Negro, 11 October 2020, https://
www.rionegro.com.ar/la-energia-del-sol-llevara-luz-a-dos-
parajes-inhospitos-de-la-estepa-1531673.
131 IRENA, Innovation Landscape Brief: Pay-As-You-Go (Abu Dhabi:
2020), https://www.irena.org/-/media/Files/IRENA/Agency/
Publication/2020/Jul/IRENA_Pay-as-you-go_models_2020 .
132 GOGLA, op. cit. note 84.
133 M-Kopa, “Products”, https://m-kopa.com/products, viewed 14
November 2020.
134 J. M. Takouleu, “AFRICA: Bboxx and Canal+ sign agreement for
solar-powered television”, Afrik21, 28 July 2020, https://www.
afrik21.africa/en/africa-bboxx-and-canal-sign-agreement-for-
solar-powered-television.
135 Bboxx, “Bboxx launches the new bpower20 products”, press
release (London: 25 August 2020), https://www.bboxx.com/
press-releases/bboxx-launches-the-new-bpower20-product.
136 Ibid.
137 GOGLA, op. cit. note 84.
138 J. M. Takouleu, “Rwanda: Engie and OffGridBox provide green
energy, water and Wi-Fi in Kigali”, Afrik21, 21 October 2020,
https://www.afrik21.africa/en/rwanda-engie-and-offgridbox-
provide-green-energy-water-and-wi-fi-in-kigali.
139 Ibid.
140 Ibid.
141 “Bboxx, EDF, and SunCulture to accelerate access to solar-
powered farming in Togo”, African Review, 18 December 2020,
https://www.africanreview.com/energy-a-power/power-
generation/togo-government-partners-bboxx-edf-and-sunculture-
to-accelerate-access-to-sustainable-solar-powered-farming.
142 Ibid.
143 Dalberg, “Cleaning up cooking in urban Kenya with LPG and
bio-ethanol”, 28 June 2018, http://dalberg.com/our-ideas/
cleaning-cooking-urban-kenya-lpg-and-bio-ethanol.
144 Ibid.
145 Ibid.
146 KOKO Networks, “50,000th Nairobi household switches to
KOKO fuel”, 25 August 2020, https://kokonetworks.com/
news/50000th-nairobi-household-switches-to-koko-fuel.
147 RVO, “Access to energy: SDG 7 selects 12 new projects”, https://
english.rvo.nl/news/access-energy-sdg-7-selects-12-new-
projects, viewed 29 November 2020.
148 My PR, “Engie Africa partners with PayGas to provide affordable
clean cooking to 20000 beneficiaries in South Africa”, 17 July 2020,
https://mypr.co.za/engie-africa-partners-with-paygas-to-provide-
affordable-clean-cooking-to-20000-beneficiaries-in-south-africa.
149 Ibid.
150 Clean Cooking Alliance (CCA), “Cooking industry catalysts”,
https://www.cleancookingalliance.org/cooking-industry-catalyst,
viewed 14 November 2020.
151 Mini-Grids Partnership, op. cit. note 105.
152 Ibid.; ESI Africa, “Mini-grids can electrify thousands of health
centres in sub-Saharan Africa”, 2 June 2020, https://www.esi-
africa.com/news/mini-grids-can-electrify-thousands-of-health-
centres-in-sub-saharan-africa.
153 AMDA, op. cit. note 108.
154 Energy and Environment Partnership Trust Fund (EEP Africa),
“East Africa Power (EAP): Bihonora Multi-Purpose Hydropower
Project”, https://eepafrica.org/Portfolio/east-african-power,
viewed 29 April 2021.
155 EEP Africa, “Engie Equatorial: Rural Economic Agro Labs Through
Mini-grids (REALM)”, https://eepafrica.org/Portfolio/engie-
equatorial, viewed 29 April 2021.
156 Ibid.
157 Sunkofa, “Sunkofa and PowerGen awarded 40 mini-grids on the
Benin mini-grid call for proposals”, press release (Paris: 25 June
2020), https://www.linkedin.com/posts/sunkofa-energy_press-
release-activity-6683288136736481281-_blX.
158 Ibid.
159 SEforALL, Energizing Finance: Understanding the Landscape 2020
(Washington, DC: 2020),https://www.seforall.org/publications/
energizing-finance-understanding-the-landscape-2020.
160 Ibid.
161 Ibid.
162 Ibid.
163 Ibid.
164 Ibid.
165 Ibid.
166 Ibid.
167 Ibid.
168 IRENA and Climate Policy Initiative (CPI), Global Landscape of
Renewable Energy Finance 2020 (Abu Dhabi: 2020), https://www.
irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/
IRENA_CPI_Global_finance_2020 .
169 Ibid.
170 Figure 43 from Ibid.
171 B. Attia, “Session I – Status quo of the DRE sector in Sub-Saharan
Africa (SSA) and Asia-Pacific (APAC): Global investment trends in
the sector”, presentation, Alliance for Rural Electrification (ARE) and
Energy Catalyst Rural Electrification Masterclass, 8 March 2021.
172 Acumen, “Acumen and Green Climate Fund boost COVID-19 relief
in off-grid energy access”, 12 November 2020, https://acumen.
org/blog/acumen-and-green-climate-fund-boost-covid-19-relief-
in-off-grid-energy-access.
173 African Development Bank (AfDB), ”The African Development
Bank launches $50 million facility to support energy access
companies through and beyond the COVID-19 pandemic”, press
release (Abidjan: 4 December 2020), https://www.afdb.org/en/
news-and-events/press-releases/african-development-bank-
launches-50-million-facility-support-energy-access-companies-
through-and-beyond-covid-19-pandemic-39746.
347
https://rea.gov.ng/press-release-shimankar-community-welcomes-solar-electricity
https://rea.gov.ng/press-release-shimankar-community-welcomes-solar-electricity
https://mailchi.mp/rea.gov.ng/enews-dec2020
https://mailchi.mp/rea.gov.ng/enews-dec2020
https://www.usaid.gov/powerafrica/coronavirus
https://www.usaid.gov/powerafrica/coronavirus
https://www.nigeriaelectricityhub.com/2020/11/04/sustainsolar-to-install-7-containerised-solar-mini-grids-for-onepower-in-lesotho
https://www.nigeriaelectricityhub.com/2020/11/04/sustainsolar-to-install-7-containerised-solar-mini-grids-for-onepower-in-lesotho
https://www.afrik21.africa/en/benin-11-companies-selected-for-8-mini-solar-grids-projects-in-rural-areas
https://www.afrik21.africa/en/benin-11-companies-selected-for-8-mini-solar-grids-projects-in-rural-areas
https://www.afrik21.africa/en/benin-11-companies-selected-for-8-mini-solar-grids-projects-in-rural-areas
https://www.afrik21.africa/en/togo-129-localities-soon-to-be-electrified-via-mini-grids
https://www.afrik21.africa/en/togo-129-localities-soon-to-be-electrified-via-mini-grids
https://www.energymixreport.com/senegals-aser-launches-a-call-for-tenders-for-133-solar-mini-grids-in-rural-areas
https://www.energymixreport.com/senegals-aser-launches-a-call-for-tenders-for-133-solar-mini-grids-in-rural-areas
https://www.energymixreport.com/senegals-aser-launches-a-call-for-tenders-for-133-solar-mini-grids-in-rural-areas
https://www.afrik21.africa/en/kenya-renewvia-commissions-3-mini-grids-in-turkana-and-marsabit-counties
https://www.afrik21.africa/en/kenya-renewvia-commissions-3-mini-grids-in-turkana-and-marsabit-counties
https://www.afrik21.africa/en/kenya-renewvia-commissions-3-mini-grids-in-turkana-and-marsabit-counties
https://www.afrik21.africa/en/kenya-kenya-power-wants-to-hybridise-23-mini-diesel-grids-with-solar-and-wind-power
https://www.afrik21.africa/en/kenya-kenya-power-wants-to-hybridise-23-mini-diesel-grids-with-solar-and-wind-power
https://www.afrik21.africa/en/drc-nuru-connects-1-3-mw-solar-off-grid-hybrid-in-goma
https://www.afrik21.africa/en/drc-nuru-connects-1-3-mw-solar-off-grid-hybrid-in-goma
https://ndre.sreda.gov.bd/index.php?id=1&i=5
https://ndre.sreda.gov.bd/index.php?id=1&i=5
https://www.rionegro.com.ar/la-energia-del-sol-llevara-luz-a-dos-parajes-inhospitos-de-la-estepa-1531673
https://www.rionegro.com.ar/la-energia-del-sol-llevara-luz-a-dos-parajes-inhospitos-de-la-estepa-1531673
https://www.rionegro.com.ar/la-energia-del-sol-llevara-luz-a-dos-parajes-inhospitos-de-la-estepa-1531673
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Jul/IRENA_Pay-as-you-go_models_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Jul/IRENA_Pay-as-you-go_models_2020
https://m-kopa.com/products
https://www.afrik21.africa/en/africa-bboxx-and-canal-sign-agreement-for-solar-powered-television
https://www.afrik21.africa/en/africa-bboxx-and-canal-sign-agreement-for-solar-powered-television
https://www.afrik21.africa/en/africa-bboxx-and-canal-sign-agreement-for-solar-powered-television
https://www.bboxx.com/press-releases/bboxx-launches-the-new-bpower20-product
https://www.bboxx.com/press-releases/bboxx-launches-the-new-bpower20-product
https://www.afrik21.africa/en/rwanda-engie-and-offgridbox-provide-green-energy-water-and-wi-fi-in-kigali
https://www.afrik21.africa/en/rwanda-engie-and-offgridbox-provide-green-energy-water-and-wi-fi-in-kigali
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
http://dalberg.com/our-ideas/cleaning-cooking-urban-kenya-lpg-and-bio-ethanol
http://dalberg.com/our-ideas/cleaning-cooking-urban-kenya-lpg-and-bio-ethanol
https://kokonetworks.com/news/50000th-nairobi-household-switches-to-koko-fuel
https://kokonetworks.com/news/50000th-nairobi-household-switches-to-koko-fuel
https://english.rvo.nl/news/access-energy-sdg-7-selects-12-new-projects
https://english.rvo.nl/news/access-energy-sdg-7-selects-12-new-projects
https://english.rvo.nl/news/access-energy-sdg-7-selects-12-new-projects
https://mypr.co.za/engie-africa-partners-with-paygas-to-provide-affordable-clean-cooking-to-20000-beneficiaries-in-south-africa
https://mypr.co.za/engie-africa-partners-with-paygas-to-provide-affordable-clean-cooking-to-20000-beneficiaries-in-south-africa
https://www.cleancookingalliance.org/cooking-industry-catalyst
https://www.esi-africa.com/news/mini-grids-can-electrify-thousands-of-health-centres-in-sub-saharan-africa
https://www.esi-africa.com/news/mini-grids-can-electrify-thousands-of-health-centres-in-sub-saharan-africa
https://www.esi-africa.com/news/mini-grids-can-electrify-thousands-of-health-centres-in-sub-saharan-africa
https://eepafrica.org/Portfolio/east-african-power
https://eepafrica.org/Portfolio/engie-equatorial
https://eepafrica.org/Portfolio/engie-equatorial
https://www.linkedin.com/posts/sunkofa-energy_press-release-activity-6683288136736481281-_blX
https://www.linkedin.com/posts/sunkofa-energy_press-release-activity-6683288136736481281-_blX
https://www.seforall.org/publications/energizing-finance-understanding-the-landscape-2020
https://www.seforall.org/publications/energizing-finance-understanding-the-landscape-2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_CPI_Global_finance_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_CPI_Global_finance_2020
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2020/Nov/IRENA_CPI_Global_finance_2020
https://acumen.org/blog/acumen-and-green-climate-fund-boost-covid-19-relief-in-off-grid-energy-access
https://acumen.org/blog/acumen-and-green-climate-fund-boost-covid-19-relief-in-off-grid-energy-access
https://acumen.org/blog/acumen-and-green-climate-fund-boost-covid-19-relief-in-off-grid-energy-access
https://www.afdb.org/en/news-and-events/press-releases/african-development-bank-launches-50-million-facility-support-energy-access-companies-through-and-beyond-covid-19-pandemic-39746
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ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
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S174 Shine, “Covid-19 Recovery Fund Grant”, https://www.shineinvest.
org/covid-19, viewed 7 March 2021.
175 CCA, 2021 Clean Cooking Industry Snapshot (Washington, DC:
2021), https://www.cleancookingalliance.org/binary-data/
RESOURCE/file/000/000/620-1 .
176 Ibid.
177 Burn, “BurninNews October 2020 Newsletter”, 15 October 2020,
https://burnstoves.com/media/newsletter/post?s=2020-
burninnews-october-2020-newsletter.
178 Betterinvest, “Biomasse-Briketts für Kenia“, https://www.bettervest.
com/de/project/sanergy-2-projektprofil, viewed 7 March 2021.
179 FMO, “Buen Manejo del Campo S.A. De CV’’, https://www.fmo.nl/
project-detail/59373, viewed 10 February 2020.
180 CCA, op. cit. note 175.
181 Ibid.
182 Ibid.
183 GOGLA, “Total capital raised”, https://infogram.com/1p9yk05mkv
773df7ze1d01m9yji3gjk2gm5?live-%20, viewed 22 March 2021.
184 SEforALL, op. cit. note 159.
185 GOGLA, “Type of debt investment per year”, https://infogram.
com/1p9yk05mkv773df7ze1d01m9yji3gjk2gm5?live-%20, viewed
23 March 2021.
186 Figure 44 from GOGLA, “Financing blend”, https://infogram.
com/1p9yk05mkv773df7ze1d01m9yji3gjk2gm5?live-%20, viewed
22 March 2021.
187 I. Shumkov, “Lumos obtains USD 35m in financing for solar
expansion in Nigeria”, Renewables Now, 15 September 2020,
https://renewablesnow.com/news/lumos-obtains-usd-35m-in-
financing-for-solar-expansion-in-nigeria-713653.
188 J. M. Takouleu, “DRC EIF OGEF lends $4m to Bboxx for
electrification via solar home systems”, Afrik21, 24 November
2020, https://www.afrik21.africa/en/drc-eif-ogef-lends-4m-to-
bboxx-for-electrification-via-solar-home-systems.
189 Oolu, “Oolu, a West Africa-based solar pay-as-you-go
distributor, raises $8.5 million in Series B round with RP
Global as lead investor”, press release (Dakar: 2 December
2020), https://oolusolar.com/pressarticles/2020/12/14/
mky7th4cd1xlizlaysdbtscbxh3e3f.
190 EDFI Electrify, “UpOwa raises €3m from EDFI ElectriFI to
accelerate expansion in Cameroon”, 7 September 2020, https://
www.electrifi.eu/news/upowa-raises-e3m-from-edfi-electrifi-to-
accelerate-expansion-in-cameroon.
191 Easy Solar, “Easy Solar raises $5M in Series A equity and debt
funding to scale operations in West Africa”, 29 September 2020,
https://medium.com/@easysolar/easy-solar-raises-5m-in-series-
a-equity-and-debt-funding-to-scale-operations-in-west-africa-
99e6a86581f5.
192 European Investment Bank, “Uganda: 1.4 million Ugandans to
access reliable and affordable energy under new EIB – ENGIE
initiative”, press release (Luxembourg: 28 July 2020), https://www.
eib.org/en/press/all/2020-207-14-million-ugandans-to-access-
reliable-and-affordable-energy-under-new-eib-engie-initiative.
193 Energy+, “ENERGY+ secures funding from Venturebuilder,
CORDAID, and USADF”, press release (Bamako: 12 August 2020),
https://eplusmali.com/documentation/energy-secures-funding.
194 Angaza, “SIMA Angaza Distributor Finance Fund announces first
three investments”, press release (San Francisco, New York and
Nairobi: 13 October 2020), https://www.angaza.com/2020/10/13/
sima-angaza-distributor-finance-fund-announces-first-three-
investments.
195 ARE, “ARE member Sunculture raises USD 14 million Series
A funding”, press release (Nairobi: 7 December 2020),
http://www.ruralelec.org/news-from-are/are-member-
sunculture-raises-usd-14-million-series-funding.
196 GOGLA, Off-Grid Solar Investment Trends (Amsterdam: 2020),
https://www.gogla.org/sites/default/files/resource_docs/off-
grid_solar_investment_trends_2019-2020 .
197 Energise Africa, “Investments”, https://www.energiseafrica.
com/investments, viewed 28 February 2021; Energise Africa,
“Energising off-grid solar access in Africa – back to business
(almost) as usual”, 12 October 2020, https://www.energiseafrica.
com/news/energising-off-grid-solar-access-in-africa-back-to-
business-almost-as-usual.
198 Energise Africa, “Investments”, op. cit. note 197.
199 Attia, op. cit. note 171.
200 Husk Power Systems, “Dutch Development Bank FMO spotlights
Husk Power as ‘energy disruptors’; invested USD 5 million in
minigrid developer”, press release (Fort Collins, CO: 5 October
2020), https://huskpowersystems.com/dutch-development-bank-
fmo-spotlights-husk-power-as-energy-disruptors-invested-us-5-
million-in-minigrid-developer.
201 J. M. Takouleu, “Africa: Winch energy obtains $16 million to
finance 49 mini-grids in two countries”, Afrik21, 16 February 2021,
https://www.afrik21.africa/en/africa-winch-energy-obtains-16-
million-to-finance-49-mini-grids-in-two-countries.
202 Ibid.
203 J. M. Takouleu, “Nigeria: NDIF invests $4.6m in Havenhill for 22 solar
mini-grids”, Afrik21, 11 March 2021, https://www.afrik21.africa/en/
nigeria-ndif-invests-4-6m-in-havenhill-for-22-solar-mini-grids.
204 Angaza, “Angaza raises $13.5 million in Series B financing”, press
release (San Francisco: 27 October 2020), https://www.angaza.
com/2020/10/27/angaza-raises-13-5-million-in-series-b-financing.
205 ARE, “ARE member Sparkmeter completes USD 12 million
Series A financing”, press release (Washington, DC: 25
August 2020), https://www.ruralelec.org/news-from-are/
are-member-sparkmeter-completes-12-million-series-financing.
206 Acumen, “Our latest investment: Solaris Off-grid”, 17 April 2020,
https://acumen.org/blog/new-investment-solaris.
207 T. McManan-Smith, “Platform to create a global market for
distributed renewable energy”, The Energyst, 21 January 2021,
https://theenergyst.com/innovative-platform-creates-a-global-
market-for-distributed-renewable-energy.
208 Ibid.
209 SEforALL, op. cit. note 159.
210 BloombergNEF, “4Q 2019 off-grid and mini-grid market outlook”,
Climatescope 2020, 10 January 2020, https://global-climatescope.
org/library/off-grid/4q-2019.
211 SEforALL, op. cit. note 159.
212 World Bank, “World Bank project to boost household access
to affordable energy”, press release (Washington, DC: 17
September 2020), https://www.worldbank.org/en/news/press-
release/2020/09/17/world-bank-project-to-boost-household-
access-to-affordable-energy.
213 Ibid.
214 Ibid.
215 Ibid.
216 World Bank, “Burundi to improve access to services and
opportunities for the poor in rural areas”, press release
(Washington, DC: 28 February 2020), https://www.worldbank.org/
en/news/press-release/2020/02/28/burundi-to-improve-access-
to-services-and-opportunities-for-the-poor-in-rural-areas.
217 World Bank, “New World Bank funding to boost Lesotho’s efforts
to improve electricity to thousands of Basotho”, press release
(Washington, DC: 30 January 2020), https://www.worldbank.org/
en/news/press-release/2020/01/30/new-world-bank-funding-
to-boost-lesothos-efforts-to-improve-electricity-access-to-
thousands-of-basotho.
218 World Bank, “World Bank supports sustainable renewable energy
for priority healthcare facilities responding to COVID-19 in Haiti”,
press release (Washington, DC: 30 September 2020), https://
www.worldbank.org/en/news/press-release/2020/09/30/
world-bank-supports-sustainable-renewable-energy-for-priority-
healthcare-facilities-responding-to-covid-19.
219 AfDB, “African Development Bank invests in pioneering SPARK+
Africa Fund to deliver clean cooking solutions”, press release (Abidjan:
30 November 2020), https://www.afdb.org/en/news-and-events/
press-releases/african-development-bank-invests-pioneering-
spark-africa-fund-deliver-clean-cooking-solutions-39574.
220 Ibid.
221 AfDB, “African Development Bank’s Facility for Energy Inclusion
attracts $160 million in commitments for small-scale renewable
energy”, 16 March 2020, https://www.afdb.org/en/news-and-events/
african-development-banks-facility-energy-inclusion-attracts-160m-
commitments-small-scale-renewable-energy-34792.
222 AfDB, “African Development Bank approves $7 million in SEFA
technical assistance to transform mini-grid investment in Africa”,
348
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https://www.cleancookingalliance.org/binary-data/RESOURCE/file/000/000/620-1
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https://www.worldbank.org/en/news/press-release/2020/02/28/burundi-to-improve-access-to-services-and-opportunities-for-the-poor-in-rural-areas
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https://www.worldbank.org/en/news/press-release/2020/01/30/new-world-bank-funding-to-boost-lesothos-efforts-to-improve-electricity-access-to-thousands-of-basotho
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https://www.afdb.org/en/news-and-events/african-development-banks-facility-energy-inclusion-attracts-160m-commitments-small-scale-renewable-energy-34792
https://www.afdb.org/en/news-and-events/african-development-banks-facility-energy-inclusion-attracts-160m-commitments-small-scale-renewable-energy-34792
ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
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Spress release (Abidjan: 18 December 2020), https://www.afdb.
org/en/news-and-events/press-releases/african-development-
bank-approves-7-million-sefa-technical-assistance-transform-
mini-grid-investment-africa-39965.
223 European Commission, “Team Europe: EU seals agreements
to generate €10 billion in investment in Africa and the EU
Neighbourhood and stimulate global recovery”, press release
(Brussels: 12 November 2020), https://ec.europa.eu/commission/
presscorner/detail/en/ip_20_2076.
224 Ibid.
225 Ibid.
226 Renewable Energy & Energy Efficiency Partnership (REEP),
“Beyond the Grid Fund for Africa expands to Uganda”, 6 May
2020, https://www.reeep.org/news/%E2%80%98beyond-grid-
fund-africa%E2%80%99-expands-uganda.
227 Ibid.
228 Beyond the Grid Fund for Africa, “BGFA, Sweden and NEFCO kick-
off new initiative on clean cooking financing solutions”, 11 September
2020, https://beyondthegrid.africa/news/sweden-and-nefco-kick-
off-new-initiative-on-clean-cooking-financing-solutions.
229 Green Climate Fund (GCF), “SAP013 Scaling smart, solar, energy
access minigrids in Haiti”, https://www.greenclimate.fund/project/
sap013, viewed 29 November 2020; GCF, “FP138 ASER solar rural
electrification project”, https://www.greenclimate.fund/project/
fp138, viewed 29 November 2020; GCF, “FP 129 Afghanistan rural
energy market transformation initiative”, https://www.greenclimate.
fund/project/fp129, viewed 29 November 2020.
230 Ibid., all references.
231 GCF, “FP148 Participation in energy access relief facility”, https://
www.greenclimate.fund/project/fp148, viewed 29 November 2020.
232 Rockefeller Foundation, “The Rockefeller Foundation commits USD1
billion to catalyse a green recovery from pandemic”, press release
(New York: 26 October 2020), https://www.rockefellerfoundation.
org/news/the-rockefeller-foundation-commits-usd1-billion-to-
catalyze-a-green-recovery-from-pandemic.
233 Ibid.
234 Carbon Trust, “The Carbon Trust awarded €5 million IKEA
foundation funding to realise the potential of energy access in
sub-Saharan Africa”, 24 June 2020, https://www.carbontrust.
com/news-and-events/news/the-carbon-trust-awarded-eu5-
million-ikea-foundation-funding-to-realise-the.
235 Ibid.
236 SEforALL, “Universal Energy Facility opens for mini-grid projects
in Benin”, 28 January 2021, https://www.seforall.org/news/
universal-energy-facility-opens-for-mini-grid-projects-in-benin.
237 Ashden, “Fair Cooling fund pledges $580,000 to protect the most
vulnerable”, 11 November 2020, https://ashden.org/news/fair-
cooling-fund-pledges-580000-to-protect-the-most-vulnerable.
238 Engineers Without Borders USA, “In the News: Awardees
announced in Engineers Without Borders-USA’s ‘Chill Challenge’”,
21 May 2020, https://www.ewb-usa.org/in-the-news-awardees-
announced-in-engineers-without-borders-usas-chill-challenge.
239 MECS, “MECS Eco competition funds 14 projects to the value
of £826,000 to facilitate greater uptake and understanding of
opportunities for the use of efficient electric cooking appliances”,
19 August 2020, https://mecs.org.uk/mecs-eco-competition-
funds-14-projects-to-the-value-of-826000-to-facilitate-greater-
uptake-and-understanding-of-opportunities-for-the-use-of-
efficient-electric-cooking-appliances.
240 Ibid.
241 Table 7 and Table 8 are intended to be only indicative of the overall
landscape of distributed renewables for energy access policy
activity and are not a definitive reference. Generally, listed policies
are those that have been enacted by legislative bodies. Some of
the listed policies may not yet be implemented, or are awaiting
detailed implementing regulations. It is difficult to capture every
policy change, so some policies may be unintentionally omitted or
incorrectly listed. This report does not cover policies and activities
related to technology transfer, capacity building, carbon finance
and Clean Development Mechanism projects, nor does it attempt
to provide a comprehensive list of broader framework and strategic
policies – all of which are still important to renewables-based
energy access progress. For the most part, this report also does
not cover policies that are still under discussion or formulation.
Information on electricity access policies comes from a wide
variety of sources, including the World Bank Regulatory Indicators
for Sustainable Energy (RISE), IRENA, the Global Renewable
Energy Policies and Measures Database, press reports and
announcements from ministries, rural electrification agencies and
energy regulators, and submissions from REN21 regional- and
country-specific contributors and reviewers. Information on
clean cooking access policies comes from a variety of sources,
including Clean Cooking Alliance Policy Database; A. Towfiq,
CCA, Washington, DC, personal communication with REN21, 2
April 2021, and submissions from REN21 regional- and country-
specific contributors and reviewers.
242 Ibid.
243 Ibid.
244 REA, “Solar Power Naija – enabling 5 million new connections”,
https://rea.gov.ng/solar-power-naija, viewed 28 February 2021.
245 Ibid.
246 ESMAP, Regulatory Indicators for Sustainable Energy (RISE):
Sustaining the Momentum (Washington, DC: World Bank, 2020),
https://rise.esmap.org/data/files/reports/2020-full-report/
RiseReport-010421 .
247 Figure 45 from RISE, “Analytics”, https://rise.esmap.org/
analytics, viewed 7 March 2021.
248 H. Gebreamlak, “Law arrives to govern off-grid electricity systems”,
Addis Fortune, 7 November 2020, https://addisfortune.news/
law-arrives-to-govern-off-grid-electricity-systems.
249 E. Bellini, “Benin introduces VAT exemption on imports of PV
panels”, pv magazine, 27 January 2020, https://www.pv-magazine.
com/2020/01/27/benin-introduces-vat-exemption-on-imports-
of-pv-panels. J. Spaes, “Mali exempts solar from VAT, import
duties”, pv magazine, 7 April 2020, https://www.pv-magazine.
com/2020/04/07/mali-exempts-solar-from-vat-import-duties.
250 GOGLA, “Policy alert: Kenya introduces VAT on off-grid
solar products”, 26 June 2020, https://www.gogla.org/
news/policy-alert-kenya-introduces-vat-on-off-grid-solar-
products; F. Sunday, “Treasury to scrap VAT on renewable
energy products”, The Standard, 24 April 2021, https://
www.standardmedia.co.ke/business/article/2001410696/
treasury-to-scrap-vat-on-renewable-energy-products.
251 C. Pronami, “PM KUSUM Yojana: Govt is offering 90% discount
on solar pumps; earn in Lakhs and get these benefits”, Krishi
Jagran, 5 January 2021, https://krishijagran.com/agriculture-
world/pm-kusum-yojana-govt-is-offering-90-discount-on-solar-
pumps-earn-in-lakhs-and-get-these-benefits.
252 “Bboxx, EDF, and SunCulture to accelerate access to solar-
powered farming in Togo”, African Review, 18 December 2020,
https://www.africanreview.com/energy-a-power/power-
generation/togo-government-partners-bboxx-edf-and-sunculture-
to-accelerate-access-to-sustainable-solar-powered-farming.
253 Global Environment Facility, “Opening doors to greater
electricity access”, 23 June 2020, https://www.thegef.org/news/
opening-doors-greater-electricity-access.
254 Ibid.
255 ESMAP, op. cit. note 246.
256 Ibid.
257 Ibid.
258 See endnote 241.
259 C. K. Mandal, “Nepal submits its second Nationally
Determined Contribution document to UN”, Kathmandu Post,
10 December 2020, https://kathmandupost.com/climate-
environment/2020/12/10/nepal-submits-its-second-nationally-
determined-contribution-document-to-un.
260 Ibid.
261 “Government prepares RS 1b subsidy to promote use of induction
stoves”, Republica Nepal, 27 March 2020, https://myrepublica.
nagariknetwork.com/news/govt-prepares-rs-1b-subsidy-to-
promote-use-of-induction-stove.
262 Shivani, “Union budget 2021: Ujjwala scheme to be
extended to 1 crore more beneficiaries, announces finance
minister Sitharaman”, Hindustan Times, 1 February 2021,
https://www.hindustantimes.com/budget/union-budget-
2021-ujjwala-scheme-to-be-extended-to-1-crore-more-
beneficiaries-announces-finance-minister-nirmala-
sitharaman-101612162680636.html.
349
https://www.afdb.org/en/news-and-events/press-releases/african-development-bank-approves-7-million-sefa-technical-assistance-transform-mini-grid-investment-africa-39965
https://www.afdb.org/en/news-and-events/press-releases/african-development-bank-approves-7-million-sefa-technical-assistance-transform-mini-grid-investment-africa-39965
https://www.afdb.org/en/news-and-events/press-releases/african-development-bank-approves-7-million-sefa-technical-assistance-transform-mini-grid-investment-africa-39965
https://www.afdb.org/en/news-and-events/press-releases/african-development-bank-approves-7-million-sefa-technical-assistance-transform-mini-grid-investment-africa-39965
https://ec.europa.eu/commission/presscorner/detail/en/ip_20_2076
https://ec.europa.eu/commission/presscorner/detail/en/ip_20_2076
https://www.reeep.org/news/%E2%80%98beyond-grid-fund-africa%E2%80%99-expands-uganda
https://www.reeep.org/news/%E2%80%98beyond-grid-fund-africa%E2%80%99-expands-uganda
https://beyondthegrid.africa/news/sweden-and-nefco-kick-off-new-initiative-on-clean-cooking-financing-solutions
https://beyondthegrid.africa/news/sweden-and-nefco-kick-off-new-initiative-on-clean-cooking-financing-solutions
https://www.greenclimate.fund/project/sap013
https://www.greenclimate.fund/project/sap013
https://www.greenclimate.fund/project/fp138
https://www.greenclimate.fund/project/fp138
https://www.greenclimate.fund/project/fp129
https://www.greenclimate.fund/project/fp129
https://www.greenclimate.fund/project/fp148
https://www.greenclimate.fund/project/fp148
https://www.rockefellerfoundation.org/news/the-rockefeller-foundation-commits-usd1-billion-to-catalyze-a-green-recovery-from-pandemic
https://www.rockefellerfoundation.org/news/the-rockefeller-foundation-commits-usd1-billion-to-catalyze-a-green-recovery-from-pandemic
https://www.rockefellerfoundation.org/news/the-rockefeller-foundation-commits-usd1-billion-to-catalyze-a-green-recovery-from-pandemic
https://www.carbontrust.com/news-and-events/news/the-carbon-trust-awarded-eu5-million-ikea-foundation-funding-to-realise-the
https://www.carbontrust.com/news-and-events/news/the-carbon-trust-awarded-eu5-million-ikea-foundation-funding-to-realise-the
https://www.carbontrust.com/news-and-events/news/the-carbon-trust-awarded-eu5-million-ikea-foundation-funding-to-realise-the
https://www.seforall.org/news/universal-energy-facility-opens-for-mini-grid-projects-in-benin
https://www.seforall.org/news/universal-energy-facility-opens-for-mini-grid-projects-in-benin
https://ashden.org/news/fair-cooling-fund-pledges-580000-to-protect-the-most-vulnerable
https://ashden.org/news/fair-cooling-fund-pledges-580000-to-protect-the-most-vulnerable
https://www.ewb-usa.org/in-the-news-awardees-announced-in-engineers-without-borders-usas-chill-challenge
https://www.ewb-usa.org/in-the-news-awardees-announced-in-engineers-without-borders-usas-chill-challenge
https://mecs.org.uk/mecs-eco-competition-funds-14-projects-to-the-value-of-826000-to-facilitate-greater-uptake-and-understanding-of-opportunities-for-the-use-of-efficient-electric-cooking-appliances
https://mecs.org.uk/mecs-eco-competition-funds-14-projects-to-the-value-of-826000-to-facilitate-greater-uptake-and-understanding-of-opportunities-for-the-use-of-efficient-electric-cooking-appliances
https://mecs.org.uk/mecs-eco-competition-funds-14-projects-to-the-value-of-826000-to-facilitate-greater-uptake-and-understanding-of-opportunities-for-the-use-of-efficient-electric-cooking-appliances
https://mecs.org.uk/mecs-eco-competition-funds-14-projects-to-the-value-of-826000-to-facilitate-greater-uptake-and-understanding-of-opportunities-for-the-use-of-efficient-electric-cooking-appliances
https://rea.gov.ng/solar-power-naija
https://rise.esmap.org/data/files/reports/2020-full-report/RiseReport-010421
https://rise.esmap.org/data/files/reports/2020-full-report/RiseReport-010421
https://rise.esmap.org/analytics
https://rise.esmap.org/analytics
https://addisfortune.news/law-arrives-to-govern-off-grid-electricity-systems
https://addisfortune.news/law-arrives-to-govern-off-grid-electricity-systems
https://www.pv-magazine.com/2020/01/27/benin-introduces-vat-exemption-on-imports-of-pv-panels
https://www.pv-magazine.com/2020/01/27/benin-introduces-vat-exemption-on-imports-of-pv-panels
https://www.pv-magazine.com/2020/01/27/benin-introduces-vat-exemption-on-imports-of-pv-panels
https://www.pv-magazine.com/2020/04/07/mali-exempts-solar-from-vat-import-duties
https://www.pv-magazine.com/2020/04/07/mali-exempts-solar-from-vat-import-duties
https://www.gogla.org/news/policy-alert-kenya-introduces-vat-on-off-grid-solar-products
https://www.gogla.org/news/policy-alert-kenya-introduces-vat-on-off-grid-solar-products
https://www.gogla.org/news/policy-alert-kenya-introduces-vat-on-off-grid-solar-products
https://www.standardmedia.co.ke/business/article/2001410696/treasury-to-scrap-vat-on-renewable-energy-products
https://www.standardmedia.co.ke/business/article/2001410696/treasury-to-scrap-vat-on-renewable-energy-products
https://www.standardmedia.co.ke/business/article/2001410696/treasury-to-scrap-vat-on-renewable-energy-products
https://krishijagran.com/agriculture-world/pm-kusum-yojana-govt-is-offering-90-discount-on-solar-pumps-earn-in-lakhs-and-get-these-benefits
https://krishijagran.com/agriculture-world/pm-kusum-yojana-govt-is-offering-90-discount-on-solar-pumps-earn-in-lakhs-and-get-these-benefits
https://krishijagran.com/agriculture-world/pm-kusum-yojana-govt-is-offering-90-discount-on-solar-pumps-earn-in-lakhs-and-get-these-benefits
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
https://www.africanreview.com/energy-a-power/power-generation/togo-government-partners-bboxx-edf-and-sunculture-to-accelerate-access-to-sustainable-solar-powered-farming
https://www.thegef.org/news/opening-doors-greater-electricity-access
https://www.thegef.org/news/opening-doors-greater-electricity-access
https://kathmandupost.com/climate-environment/2020/12/10/nepal-submits-its-second-nationally-determined-contribution-document-to-un
https://kathmandupost.com/climate-environment/2020/12/10/nepal-submits-its-second-nationally-determined-contribution-document-to-un
https://kathmandupost.com/climate-environment/2020/12/10/nepal-submits-its-second-nationally-determined-contribution-document-to-un
https://myrepublica.nagariknetwork.com/news/govt-prepares-rs-1b-subsidy-to-promote-use-of-induction-stove
https://myrepublica.nagariknetwork.com/news/govt-prepares-rs-1b-subsidy-to-promote-use-of-induction-stove
https://myrepublica.nagariknetwork.com/news/govt-prepares-rs-1b-subsidy-to-promote-use-of-induction-stove
https://www.hindustantimes.com/budget/union-budget-2021-ujjwala-scheme-to-be-extended-to-1-crore-more-beneficiaries-announces-finance-minister-nirmala-sitharaman-101612162680636.html
https://www.hindustantimes.com/budget/union-budget-2021-ujjwala-scheme-to-be-extended-to-1-crore-more-beneficiaries-announces-finance-minister-nirmala-sitharaman-101612162680636.html
https://www.hindustantimes.com/budget/union-budget-2021-ujjwala-scheme-to-be-extended-to-1-crore-more-beneficiaries-announces-finance-minister-nirmala-sitharaman-101612162680636.html
https://www.hindustantimes.com/budget/union-budget-2021-ujjwala-scheme-to-be-extended-to-1-crore-more-beneficiaries-announces-finance-minister-nirmala-sitharaman-101612162680636.html
ENDNOTES · DISTRIBUTED RENEWABLES FOR ENERGY ACCESS 04
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S263 PIB Delhi, “Cabinet approves extension of time limit for availing
the benefits of ‘Pradhan Mantri Garib Kalyan Yojana’ for Ujjwala
beneficiaries w.e.f. 01.07.20”, press release (Delhi: 8 July 2020),
https://pib.gov.in/PressReleasePage.aspx?PRID=1637214.
264 CCA, op. cit. note 175.
265 Ibid.
350
https://pib.gov.in/PressReleasePage.aspx?PRID=1637214
ENDNOTES · INVESTMENT FLOWS 05
IN
VE
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M
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FL
OW
SINVESTMENT FLOWS
1 BloombergNEF, Energy Transition Investment Trends. Tracking
Global Investment in the Low-carbon Energy Transition (London:
2021), p. 1, https://assets.bbhub.io/professional/sites/24/Energy-
Transition-Investment-Trends_Free-Summary_Jan2021 .
2 Ibid., p. 1.
3 International Energy Agency (IEA), World Energy Investment 2020
(Paris: 2020), https://www.iea.org/reports/world-energy-
investment-2020/power-sector#overview-of-power-investment.
4 Ibid.
5 EnergyPolicyTracker.org, “Search policies”, https://www.
energypolicytracker.org/search-results, viewed 18 April 2021.
6 Figure 46 based on BloombergNEF, op. cit. note 1, and on A.
McCrone, London, personal communication with Renewable
Energy Policy Network for the 21st Century (REN21), 18 March 2021.
7 BloombergNEF, op. cit. note 1; McCrone, op. cit. note 6.
8 McCrone, op. cit. note 6.
9 Ibid.
10 BloombergNEF, op. cit. note 1; McCrone, op. cit. note 6.
Figure 47 based on idem.
11 Ibid., both references.
12 Ibid., both references.
13 Ibid., both references.
14 Ibid., both references.
15 Ibid., both references.
16 C. Nedopil Wang, China Belt and Road Initiative (BRI) Investment
Report 2020 (Green BRI Center and International Institute of
Green Finance: Beijing, 2020), https://green-bri.org/wp-content/
uploads/2021/01/China-BRI-Investment-Report-2020 .
17 Ibid.
18 Ibid.
19 Ibid.
20 Global Development Policy Center, Boston University, “China’s
Global Power Database”, http://www.bu.edu/cgp, viewed 6 May
2021; C. Springer, “Greening China’s overseas energy projects”,
China Dialogue, 18 November 2020, https://chinadialogue.net/en/
energy/greening-chinas-overseas-energy-projects.
21 Ibid., both references.
22 BloombergNEF, op. cit. note 1; McCrone, op. cit. note 6.
23 Ibid., both references.
24 Ibid., both references.
25 BloombergNEF, op. cit. note 1, p. 6.
26 Ibid., p. 6.
27 Ibid., pp. 6-7.
28 Ibid., p. 7.
29 Ibid.; McCrone, op. cit. note 6. Figure 48 based on idem.
30 United Nations Industrial Development Organization (UNIDO),
World Small Hydropower Development Report 2019 – Case
Studies (Vienna: 2019), https://www.unido.org/sites/default/
files/files/2020-02/WSHPDR%202019%20Case%20Studies ;
N. Chhabra Roy et al., “Risk management in small hydropower
(SHP) projects of Uttarakhand: An innovative approach”,
IIMB Management Review, September 2020, https://www.
sciencedirect.com/science/article/pii/S0970389617303889.
31 World Bank, “Geothermal energy is on a hot path”, 3 May 2018,
https://www.worldbank.org/en/news/feature/2018/05/03/
geothermal-energy-development-investment.
32 International Renewable Energy Agency (IRENA), Advanced Biofuels:
What Holds Them Back? (Abu Dhabi: 2019), https://irena.org/
publications/2019/Nov/Advanced-biofuels-What-holds-them-back.
33 Ibid.
34 Ibid.; A. Salgado and F. Boshell, “Biofuels: slump
in investment and innovations must be reversed”,
Energy Post, 3 December 2019, https://energypost.eu/
biofuels-slump-in-investment-and-innovations-must-be-reversed.
35 BloombergNEF, op. cit. note 1; McCrone, op. cit. note 6;
Frankfurt School – United Nations Environment Programme
Collaborating Centre for Climate & Sustainable Energy Finance
(FS-UNEP), Global Trends in Renewable Energy Investment 2020
(Frankfurt: 2020), https://www.fs-unep-centre.org/wp-content/
uploads/2020/06/GTR_2020 .
36 BloombergNEF, op. cit. note 1, p. 5.
37 Ibid., p. 4.
38 Ibid., p. 11.
39 Y. Dagnet and J. Jaeger, “Not enough climate action in
stimulus plans”, World Resources Institute (WRI), 15
September 2020, https://www.wri.org/blog/2020/09/
coronavirus-green-economic-recovery.
40 Ibid.
41 IEA, Evaluation of Possible Recovery Measures (Paris: 2020),
https://www.iea.org/reports/sustainable-recovery/evaluation-
of-possible-recovery-measures#abstract.
42 Ibid.
43 EnergyPolicyTracker.org, op. cit. note 5. The 31 governments
are: Argentina, Australia, Bangladesh, Brazil, Canada, China,
Colombia, European Institutions, Finland, France, Germany, India,
Indonesia, Italy, Japan, Mexico, New Zealand, Norway, Poland, the
Republic of Korea, the Russian Federation, Saudi Arabia, South
Africa, Spain, Sweden, the Netherlands, Turkey, Ukraine, the
United Kingdom, the United States and Vietnam.
44 EnergyPolicyTracker.org, op. cit. note 5. Figure 49 based on idem,
viewed 19 April 2021.
45 Ibid.; EnergyPolicyTracker.org, “Methodology”, https://www.
energypolicytracker.org/methodology, viewed 18 April 2021.
46 EnergyPolicyTracker.org, op. cit. note 5.
47 Ibid.
48 Ibid.
49 European Council, “Special European Council, 17-21 July 2020”,
https://www.consilium.europa.eu/en/meetings/european-
council/2020/07/17-21; World Future Council, Renewables in the
Post-COVID-19 Recovery Package of the EU (Hamburg: 2021),
https://www.renewablescongress.org/wp-content/uploads/
GRC_REcovery_EU_FINAL ; European Commission, “EU’s
Next Long-term Budget & NextGenerationEU: Key Facts and
Figures (Brussels: 11 November 2020), https://ec.europa.eu/info/
sites/info/files/about_the_european_commission/eu_budget/
mff_factsheet_agreement_en_web_20.11 .
50 European Council, op. cit. note 49; World Future Council, op. cit.
note 49.
51 World Future Council, op. cit. note 49.
52 Dagnet and Jaeger, op. cit. note 39; EnergyPolicyTracker.org,
op. cit. note 5.
53 EnergyPolicyTracker.org, op. cit. note 5.
54 “Trailblazing PV-storage contract shows growing dispatch skills”,
Reuters, 12 February 2020, https://www.reutersevents.com/
renewables/pv-insider/trailblazing-pv-storage-contract-shows-
growing-dispatch-skills.
55 EnergyPolicyTracker.org, op. cit. note 5.
56 Ibid.
57 Dagnet and Jaeger, op. cit. note 39
58 Ibid.; WRI, “Nigeria moves toward a sustainable COVID-19
recovery”, 14 January 2021, https://www.wri.org/blog/2021/01/
nigeria-moves-toward-sustainable-covid-19-recovery.
59 Government of Colombia, “Con el nuevo ‘Compromiso por el
Futuro de Colombia’, el país está haciendo las grandes apuestas”,
20 August 2020, https://idm.presidencia.gov.co/prensa/Paginas/
Con-el-nuevo-Compromiso-por-el-Futuro-de-Colombia-el-pais-
esta-haciendo-las-grandes-apuestas-Duque-200820.aspx.
60 IRENA, “The COVID-19 recovery offers opportunities to address
climate crisis”, 12 December 2020, https://irena.org/newsroom/
expertinsights/2020/Dec/The-COVID-19-Recovery-Offers-
Opportunities-to-Address-Climate-Crisis; BloombergNEF,
op. cit. note 1, p. 16.
61 BloombergNEF, op. cit. note 1, p. 16.
62 Ibid., p. 16; WilderHill New Energy Global Innovation Index,
https://nexindex.com, viewed 22 March 2021; S&P Global, ”S&P
Global Clean Energy Index”, https://www.spglobal.com/spdji/en/
indices/esg/sp-global-clean-energy-index/#overview, viewed
22 March 2021.
351
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ENDNOTES · INVESTMENT FLOWS 05
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S63 BloombergNEF, op. cit. note 1, p. 16; WilderHill New Energy Global
Innovation Index, op. cit. note 62.
64 BloombergNEF, op. cit. note 1, p. 16.
65 T. Team, “Why has SunPower’s stock already tripled this year?” Forbes,
30 September 2019, https://www.forbes.com/sites/greatspeculations/
2019/09/30/why-has-sunpowers-stock-already-tripled-this-year.
66 S&P Global Clean Energy Index, “Overview”, https://www.
spglobal.com/spdji/en/indices/esg/sp-global-clean-energy-
index/#overview, viewed 22 March 2021.
67 McCrone, op. cit. note 6.
68 R. Macquerie et al., Updated View on the Global Landscape of
Climate Finance 2019 (London: Climate Policy Initiative, 2020),
https://www.climatepolicyinitiative.org/wp-content/uploads/
2020/12/Updated-View-on-the-2019-Global-Landscape-of-
Climate-Finance-1 .
69 Ibid.
70 The target was initially set in Cancun, through decision 1/CP.16,
and was reaffirmed in Paris through decision 1/CP.21, paragraph
53. United Nations Framework Convention on Climate Change
(UNFCCC), “Background note on the USD 100 billion goal in the
context of UNFCCC process, in relation to advancing on SDG
indicator 13.a.1”, https://unstats.un.org/sdgs/tierIII-indicators/
files/13.a.1_Background , viewed April 2021; UNFCCC, “Report
of the Conference of the Parties on its twenty-first session, held
in Paris from 30 November to 13 December 2015” (Bonn: 2015),
https://unfccc.int/resource/docs/2015/cop21/eng/10a01 .
71 Organisation for Economic Co-operation and Development
(OECD), Climate Finance Provided and Mobilised by Developed
Countries in 2013-18 (Paris: November 2020), https://www.oecd-
ilibrary.org/docserver/f0773d55-en .
72 Ibid.
73 Ibid., p. 21.
74 Ibid., p. 21.
75 Macquerie et al., op. cit. note 68; OECD, op. cit. note 71.
76 OECD, op. cit. note 71.
77 Ibid.
78 Climate Funds Update, “Data dashboard”, https://
climatefundsupdate.org/data-dashboard, viewed March 2021.
79 Independent Expert Group on Climate Finance, Delivering on
the $100 Billion Climate Finance Commitment and Transforming
Climate Finance (December 2020), https://www.un.org/sites/un2.
un.org/files/100_billion_climate_finance_report .
80 Ibid.
81 Green Climate Fund (GCF), Status of Pledges and Contributions
(Initial Resource Mobilization), Status Date: 31 December 2020
(Incheon, Republic of Korea: 2020), https://www.greenclimate.
fund/sites/default/files/document/status-pledges-irm-gcf1_3 .
82 Ibid.
83 GCF, “Status of the GCF Portfolio: Approved Projects and
Fulfilment of Conditions, GCF/B.27/Inf.03” (Incheon, Republic of
Korea: 23 October 2020), https://www.greenclimate.fund/sites/
default/files/document/gcf-b27-inf03 .
84 Ibid.
85 Global Environment Facility, “Renewable energy and energy
access”, https://www.thegef.org/topics/renewable-energy-and-
energy-access, viewed March 2021.
86 Climate Investment Funds (CIF), “Clean technologies”, https://
www.climateinvestmentfunds.org/topics/clean-technologies,
viewed March 2021.
87 CIF, CTF Results Report (Washington, DC: 19 November 2020), https://
www.climateinvestmentfunds.org/sites/cif_enc/files/meeting-
documents/ctf_tfc.25_3.1_results_report . Note that 2020 is
the most recent reporting year and refers either to 1 July 2019 to
30 June 2020, or to 1 January 2019 to 31 December 2019 depending
on the reporting cycle of the multilateral development bank.
88 Climate Funds Update, “Clean Technology Fund”, https://
climatefundsupdate.org/the-funds/clean-technology-fund,
viewed March 2021.
89 CIF, op. cit. note 87, p. 20.
90 African Development Bank (AfDB) et al., Joint Report on
Multilateral Development Banks' Climate Finance 2019 (London:
European Bank for Reconstruction and Development, 2020),
https://www.eib.org/attachments/press/1257-joint-report-on-
mdbs-climate-finance-2019 .
91 Ibid., p. 23.
92 Ibid., p. 23.
93 Ibid., p. 40.
94 Multilateral development banks include the AfDB, the Asian
Development Bank, the Asian Infrastructure Investment Bank,
the EBRD, the European Investment Bank, the Inter-American
Development Bank, the Islamic Development Bank and the World
Bank. AfDB et al., Joint Report on Multilateral Development Banks'
Climate Finance (London: European Bank for Reconstruction and
Development (EBRD), various editions, 2015-2019), as follows:
https://publications.iadb.org/en/2015-joint-report-multilateral-
development-banks-climate-finance, https://publications.iadb.
org/en/2016-joint-report-multilateral-development-banks-
climate-finance, https://publications.iadb.org/en/2017-joint-
report-multilateral-development-banks-climate-finance, https://
publications.iadb.org/en/2018-joint-report-multilateral-development-
banks-climate-finance, https://publications.iadb.org/en/2019-joint-
report-on-multilateral-development-banks-climate-finance.
95 Ibid.
96 Ibid. Figure 50 from idem.
97 OECD, op. cit. note 71.
98 Ibid.
99 Ibid.
100 Ibid.
101 Climate Bonds Initiative (CBI), “Explaining green bonds”, https://
www.climatebonds.net/market/explaining-green-bonds, viewed
March 2021.
102 CBI, “Record $269.5bn green issuance for 2020: Late surge sees
pandemic year pip 2019 total by $3bn”, 24 January 2021, https://
www.climatebonds.net/2021/01/record-2695bn-green-issuance-
2020-late-surge-sees-pandemic-year-pip-2019-total-3bn.
103 BloombergNEF, “Record month shoots green bonds past
trillion-dollar mark”, 10 May 2020, https://about.bnef.com/blog/
record-month-shoots-green-bonds-past-trillion-dollar-mark.
104 CBI, op. cit. note 102; CBI, personal communication with REN21,
March 2021.
105 CBI, op. cit. note 102; CBI, personal communication, op. cit. note 104.
106 CBI, personal communication, op. cit. note 104; CBI, “Data”,
https://www.climatebonds.net/market/data, viewed 24 March 2021.
107 CBI, personal communication, op. cit. note 104.
108 GCF, Tipping or Turning Point: Scaling Up Climate Finance in the
Era of COVID-19 (Incheon, Republic of Korea: October 2020),
pp. 23-24, https://www.greenclimate.fund/sites/default/files/
document/gcf-working-paper-tipping-or-turning-point-scaling-
climate-finance-era-covid-19 .
109 Ibid., pp. 23-24.
110 Ibid., pp. 23-24.
111 Ibid., pp. 23-24.
112 Ibid., pp. 23-24.
113 Independent Expert Group on Climate Finance, op. cit. note 79.
114 Gofossilfree.org, “Who has committed to divestment?” https://
gofossilfree.org/divestment/commitments, viewed April 2021.
115 Ibid.
116 Ibid.
117 350.org, “Breaking: Biggest-ever joint faith divestment from fossil
fuels”, 18 May 2020, https://350.org/breaking-biggest-ever-joint-
divestment-from-fossil-fuels; S&P Global Market Intelligence,
“Vatican's call for fossil fuel divestment could have long-term impacts”,
30 June 2020,https://www.spglobal.com/marketintelligence/en/
news-insights/latest-news-headlines/vatican-s-call-for-fossil-fuel-
divestment-could-have-long-term-impacts-59221023.
118 Gofossilfree.org, op. cit. note 114.
119 Ibid.
120 Institute for Energy Economics and Financial Analysis (IIEFA),
“Over 100 and counting”, https://ieefa.org/finance-exiting-coal,
viewed March 2021.
121 IIEFA, “Asset managers are leaving coal”, https://ieefa.org/asset-
managers-leaving-coal, viewed March 2021.
352
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ENDNOTES · INVESTMENT FLOWS 05
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S122 Climate Action 100+, 2020 Progress Report (2020), p. 44, https://
www.climateaction100.org/wp-content/uploads/2020/12/CA100-
Progress-Report .
123 Climate Chance and Finance for Tomorrow, Global Synthesis
Report on Climate Finance. Global Observatory on Non-State
Climate Action (2020), https://www.climate-chance.org/
wp-content/uploads/2020/10/global-synthesis-report-on-
climate-finance-2020-complete-climate-chance .
124 Task Force on Climate-related Financial Disclosures,
Recommendations of the Task Force on Climate-related Financial
Disclosures (Basel: 2017), https://assets.bbhub.io/company/
sites/60/2020/10/FINAL-2017-TCFD-Report-11052018 .
125 IIEFA, “Finance is leaving oil and gas”, https://ieefa.org/finance-
exiting-oil-and-gas, viewed March 2021.
126 Octopus, “Institutional investors set to double allocations to
renewables in next five years”, 23 November 2020, https://
octopusgroup.com/newsroom/latest-news/institutional-
investors-set-to-double-allocations-to-renewables-in-next-
five-years; Octopus, “Institutional investors set to nearly triple
divestment from fossil fuels in the next decade according to
survey”, 14 October 2019, https://octopusgroup.com/newsroom/
latest-news/institutional-investors-to-nearly-triple-divestment-
from-fossil-fuels-in-the-next-decade-according-to-survey.
127 “Investors ‘raising’ renewables share of investments”,
reNEWS, 23 January 2020, https://renews.biz/64598/
investors-raising-renewables-share-of-investments.
128 BankTrack, Banking on Climate Change. Fossil Fuel Finance Report
2020 (Nijmegen, Netherlands: 2020), https://www.banktrack.org/
download/banking_on_climate_change_fossil_fuel_finance_
report_2020/banking_on_climate_change__2020_vf_2 .
129 Energy Monitor, “Still banking on fossil fuels”, 25 September
2020, https://energymonitor.ai/finance/sustainable-finance/
still-banking-on-fossil-fuels.
130 The study concludes that, while divestment campaigns generate
positive change, efforts directly allocated to phasing out fossil
fuel consumption and carbon dioxide emissions would better
serve the cause. R. Pollin and T. Hansen, Economics and Climate
Justice Activism: Assessing the Fossil Fuel Divestment Movement
(Amherst, MA: Political Economy Research Institute, University of
Massachusetts at Amherst, 24 April 2018), https://www.peri.umass.
edu/economists/robert-pollin/item/1076-economics-and-climate-
justice-activism-assessing-the-fossil-fuel-divestment-movement.
131 Ibid.
132 Ibid.
133 T. F. Cojoianu et al., “Does the fossil fuel divestment movement
impact new oil and gas fundraising?” Journal of Economic
Geography, vol. 21, no. 1 (January 2021), pp. 141-64, https://
academic.oup.com/joeg/article/21/1/141/6042790.
134 Energy Monitor, op. cit. note 129.
135 Ibid.
136 Ibid.; M. Burton and F. Nangoy, “Asia’s coal developers feeling left out
by cold shoulder from banks”, Reuters, 25 June 2019, https://www.
reuters.com/article/us-asia-coal-finance/asias-coal-developers-
feeling-left-out-by-cold-shoulder-from-banks-idUSKCN1TQ15B.
137 Energy Monitor, op. cit. note 129.
138 End Coal, “Global Coal Public Finance Tracker”, https://endcoal.
org/finance-tracker, viewed 24 March 2021.
139 Global Policy, “Are fossil fuel divestment campaigns working? A
conversation with economist Robert Pollin”, 29 May 2018, https://
www.globalpolicyjournal.com/blog/29/05/2018/are-fossil-fuel-
divestment-campaigns-working-conversation-economist-robert-
pollin; F. Mormann, “Why the divestment movement is missing
the mark”, Nature Climate Change, December 2020, https://www.
nature.com/articles/s41558-020-00950-2.epdf.
140 IEA, “Global investment in the power sector by technology, 2017-
2020”, 26 May 2020, https://www.iea.org/data-and-statistics/charts/
global-investment-in-the-power-sector-by-technology-2017-2020.
141 Figure 51 based on Ibid.
142 Octopus, “Institutional investors set to double allocations to
renewables in next five years”, op. cit. note 126.
143 M. Hutchins, “The weekend read: Behind the curve”, pv magazine,
14 November 2020, https://www.pv-magazine.com/2020/11/14/
the-weekend-read-behind-the-curve.
144 Ibid.
145 Ibid.
146 C40 Cities, “Mayors of 12 major cities commit to divest from fossil
fuel companies, invest in green and just recovery from COVID-19
crisis”, press release (New York: 22 September 2020), https://
www.c40.org/press_releases/cities-commit-divest-invest.
147 Ibid.
148 Catholic Impact Investing Collaborative, “Catholic Impact Investing
Pledge”, http://www.catholicimpact.org/catholic-impact-investing-
pledge, viewed March 2021.
149 Rockefeller Brothers Fund, “Fossil Fuel Divestment”, https://www.
rbf.org/mission-aligned-investing/divestment, viewed March 2021.
150 Ibid.
151 Global Policy, op. cit. note 139.
152 Ibid.
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https://energymonitor.ai/finance/sustainable-finance/still-banking-on-fossil-fuels
https://energymonitor.ai/finance/sustainable-finance/still-banking-on-fossil-fuels
https://www.peri.umass.edu/economists/robert-pollin/item/1076-economics-and-climate-justice-activism-assessing-the-fossil-fuel-divestment-movement
https://www.peri.umass.edu/economists/robert-pollin/item/1076-economics-and-climate-justice-activism-assessing-the-fossil-fuel-divestment-movement
https://www.peri.umass.edu/economists/robert-pollin/item/1076-economics-and-climate-justice-activism-assessing-the-fossil-fuel-divestment-movement
https://academic.oup.com/joeg/article/21/1/141/6042790
https://academic.oup.com/joeg/article/21/1/141/6042790
https://www.reuters.com/article/us-asia-coal-finance/asias-coal-developers-feeling-left-out-by-cold-shoulder-from-banks-idUSKCN1TQ15B
https://www.reuters.com/article/us-asia-coal-finance/asias-coal-developers-feeling-left-out-by-cold-shoulder-from-banks-idUSKCN1TQ15B
https://www.reuters.com/article/us-asia-coal-finance/asias-coal-developers-feeling-left-out-by-cold-shoulder-from-banks-idUSKCN1TQ15B
https://endcoal.org/finance-tracker
https://endcoal.org/finance-tracker
https://www.globalpolicyjournal.com/blog/29/05/2018/are-fossil-fuel-divestment-campaigns-working-conversation-economist-robert-pollin
https://www.globalpolicyjournal.com/blog/29/05/2018/are-fossil-fuel-divestment-campaigns-working-conversation-economist-robert-pollin
https://www.globalpolicyjournal.com/blog/29/05/2018/are-fossil-fuel-divestment-campaigns-working-conversation-economist-robert-pollin
https://www.globalpolicyjournal.com/blog/29/05/2018/are-fossil-fuel-divestment-campaigns-working-conversation-economist-robert-pollin
https://www.nature.com/articles/s41558-020-00950-2.epdf
https://www.nature.com/articles/s41558-020-00950-2.epdf
https://www.iea.org/data-and-statistics/charts/global-investment-in-the-power-sector-by-technology-2017-2020
https://www.iea.org/data-and-statistics/charts/global-investment-in-the-power-sector-by-technology-2017-2020
https://www.pv-magazine.com/2020/11/14/the-weekend-read-behind-the-curve
https://www.pv-magazine.com/2020/11/14/the-weekend-read-behind-the-curve
https://www.c40.org/press_releases/cities-commit-divest-invest
https://www.c40.org/press_releases/cities-commit-divest-invest
http://www.catholicimpact.org/catholic-impact-investing-pledge
http://www.catholicimpact.org/catholic-impact-investing-pledge
https://www.rbf.org/mission-aligned-investing/divestment
https://www.rbf.org/mission-aligned-investing/divestment
ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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1 M. O’ Malley et al., Energy Systems Integration: Defining and
Describing the Value Proposition, International Institute for Energy
Systems Integration (Golden, CO: 2016), https://www.nrel.gov/
docs/fy16osti/66616 .
2 M. Roser, “Why did renewables become so cheap so fast? And
what can we do to use this global opportunity for green growth?”
Our World in Data, 1 December 2020, https://ourworldindata.org/
cheap-renewables-growth; International Renewable Energy
Agency (IRENA), “Renewables increasingly beat even the cheapest
coal competitors on cost”, press release (Abu Dhabi: 2 June 2020),
https://www.irena.org/newsroom/pressreleases/2020/Jun/
Renewables-Increasingly-Beat-Even-Cheapest-Coal-Competitors-
on-Cost; US Environmental Protection Agency (EPA), “Local
renewable energy benefits and resources”, https://www.epa.gov/
statelocalenergy/local-renewable-energy-benefits-and-resources,
updated 19 February 2021.
3 Organisation for Economic Co-operation and Development
(OECD), “Green growth and energy”, https://www.oecd.org/
greengrowth/greening-energy/greengrowthandenergy.htm,
viewed 14 March 2021; International Energy Agency (IEA),
“System integration of renewables: Decarbonising while
meeting growing demand”, https://www.iea.org/topics/system-
integration-of-renewables, viewed 14 March 2021.
4 Examples of both public and private efforts to integrate renewables
are provided throughout this chapter. For further examples and
background, see: IEA, Power Systems in Transition (Paris: 2020),
https://www.iea.org/reports/power-systems-in-transition; IRENA,
Solutions to Integrate High Shares of Variable Renewable Energy,
Report to the G20 Energy Transitions Working Group (Abu Dhabi:
2019), https://www.irena.org/-/media/Files/IRENA/Agency/
Publication/2019/Jun/IRENA_G20_grid_integration_2019 .
5 For examples, see the Global Overview and Market and Industry
chapters of this report.
6 IEA, “Renewable energy market update”, May 2020, https://www.
iea.org/reports/renewable-energy-market-update/covid-19-
impact-on-renewable-energy-growth; N. Mojarro, “COVID-19 is a
game-changer for renewable energy. Here’s why”, World Economic
Forum, 16 June 2020, https://www.weforum.org/agenda/2020/06/
covid-19-is-a-game-changer-for-renewable-energy.
7 IEA, op. cit. note 6; Mojarro, op. cit. note 6.
8 G. Parkinson, “Wind and solar hit record grid levels in Europe as
pandemic curbs energy demand”, RenewEconomy, 20 May 2020,
https://reneweconomy.com.au/wind-and-solar-hit-record-grid-
levels-in-europe-as-pandemic-curbs-energy-demand-83006; IEA,
op. cit. note 6; O. Zinaman, personal communication with Renewable
Energy Policy Network for the 21st Century (REN21), 12 January 2021.
9 G. Parkinson, “South Australia fast-tracks energy plan to dodge
blackouts and meet 100% renewables goal”, RenewEconomy,
19 June 2020, https://reneweconomy.com.au/south-australia-
fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-
renewables-goal-43196; J. Deign, “How South Australia is dealing
with rampant solar growth”, Greentech Media, 21 September
2020, https://www.greentechmedia.com/articles/read/
how-south-australia-is-dealing-with-rampant-solar-growth.
10 Mojarro, op. cit. note 6; J. Ambrose and N. Kommenda, “Britain
breaks record for coal-free power generation”, The Guardian (UK),
28 April 2020, https://www.theguardian.com/business/2020/
apr/28/britain-breaks-record-for-coal-free-power-generation.
11 Ember, Global Electricity Review 2021 (London: 2021), https://
ember-climate.org/project/global-electricity-review-2021.
12 B. Kroposki, Summarizing the Technical Challenges of High Levels
of Inverter based Resources in Power Grids (Golden, CO: National
Renewable Energy Laboratory (NREL), April 2019), https://www.
nrel.gov/docs/fy19osti/73869 .
13 Smart Energy International, “Why digitalization is
a key enabler of the energy transition”, 30 August
2019, https://www.smart-energy.com/news/
why-digitalisation-is-a-key-enabler-of-the-energy-transition.
14 C. Pordage, “Future-proofing the network with smart
substations”, Utility, 13 May 2020, https://utilitymagazine.
com.au/future-proofing-the-network-with-smart-substations;
M. Sease, “Grid modernization 2020: Pushing boundaries”,
Energy Central, 19 June 2020, https://energycentral.com/c/gr/
grid-modernization-2020-pushing-boundaries.
15 E. Danziger, “Next-generation load forecasting critical in
rapidly changing energy landscape”, PowerGrid International,
12 November 2020, https://www.power-grid.com/smart-grid/
next-generation-load-forecasting-critical-in-rapidly-changing-
energy-landscape; L. Munuera, IEA, personal communication
with REN21, 11 November 2020.
16 C. Smith, ESIG, personal communication with REN21,
9 November 2020.
17 Figure 52 from the following sources: Denmark share of net
generation based on net generation data of 16,353 GWh from
wind power, 1,181 GWh from solar PV, and total net production of
27,907 GWh, from Danish Energy Agency, “Månedlig elstatistik.
Oversigtstabeller”, in Electricity Supply, https://ens.dk/en/
our-services/statistics-data-key-figures-and-energy-maps/
annual-and-monthly-statistics, viewed 15 April 2021; Uruguay
share of wind generation of 5,437.7 GWh, solar generation 525.5
GWh and total 13,470.5 GWh, from Ministerio de Industria,
Energía y Minería, “Balance Preliminar 2020”, https://ben.miem.
gub.uy/preliminar.php; Ireland share of wind as percentage of
demand, based on provisional 2020 data from EIRGRID, “System
& renewable summary report”, https://www.eirgridgroup.
com/how-the-grid-works/renewables, accessed 16 April 2021;
Germany share of gross electricity production of wind onshore
103,66 TWh, wind offshore 27,303 TWh (total wind: 130,963
TWh), solar gross electricity production 50,6 TWh, and total
gross electricity production 558 TWh, from Federal Ministry
for Economic Affairs and Energy and AGEE Stat, “Time series
for the development of renewable energy sources in Germany”,
2021, https://www.erneuerbare-energien.de/EE/Navigation/
DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/
zeitreihen.html; Greece share of wind production of 9,323 GWh,
Solar PV production 3,898 GWh, solar rooftop PV 494 GWh, and
total 42,229.90 GWh, from Dapeep, “Μηνιαίο Δελτίο Ειδικού
Λογαριασμού ΑΠΕ & ΣΗΘΥΑ”, 2020, https://www.dapeep.gr/
wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_
ELAPE_v1.0_21.03.2021 , viewed April 2021, all in Greek and
provided by I. Tsipouridis, REDPro Consultants, Athens, personal
communication with REN21, 12 April 2021; Spain share of demand
coverage of wind 22.2%, and solar 6.1%, from Red Eléctrica
de España (REE), The Spanish Electricity System – Preliminary
Report 2020 (Madrid: February 2021), with estimated data as of
13 January 2021, p. 15, https://www.ree.es/sites/default/files/
publication/2021/03/downloadable/avance_ISE_2020_EN ;
United Kingdom share of electricity generation of wind onshore
34.95 TWh, wind offshore 40.66 TWh, solar PV 12.8 TWh, and
total electricity generation 312.76 TWh, from UK Department
for Business, Energy & Industrial Strategy (BEIS), “Fuel used
in electricity generation and electricity supplied”, March 2021,
https://assets.publishing.service.gov.uk/government/uploads/
system/uploads/attachment_data/file/972781/ET_5.1_MAR_21.
xls; Portugal share of 12,067 GWh of wind production and
1,269 GWh of solar PV, and total production of 49,342 GWh,
from REN, “Dados Tecnicos / Technical Data 20”, p. 9, https://
www.centrodeinformacao.ren.pt/PT/InformacaoTecnica/
DadosTecnicos/AFnet_RENPRO%20Brochura%20Dados%20
T%C3%A9cnicos%202020 ; Australia share of wind of
22,196 GWh and solar PV of 22,288 GWh, and total generation
of 221,957 GWh from OpenNEM, “Western Australia (SWIS)”,
https://opennem.org.au/energy/wem/?range=all&interval=1y,
viewed 23 April 2021; The Netherlands provisional data for
net production of wind onshore 9,785 TWh and offshore 5,484
TWh, solar 8,056 TWh and total net production of 118,920
TWh, from CBS StatLine, “Electricity balance sheet; supply
and consumption”, https://opendata.cbs.nl/statline/#/CBS/en/
dataset/84575ENG/table?ts=1619216097037, viewed 3 May 2021;
Honduras power generation data on the National Interconnected
Electrical System – Energía Eléctrica Generada en el Sistema
Inteconectado Nacional, based on net generation of wind of
707,202.8 MWh, solar of 1,044,775.9 MWh, and total 9,292,817.3
MWh, from Empresa Nacional de Energía Eléctrica (ENEE),
Boletines Estadísticos Año 2020 – Diciembre, http://www.enee.
hn/index.php/planificacionicono/182-boletines-estadisticos;
Sweden share of wind of 27,589 GWh, solar 805 GWh, and total
159,635 GWh, from Statistics Sweden, “Elproduktion i Sverige
efter produktionsslag. Månad 2017M01 – 2021M02”, https://www.
statistikdatabasen.scb.se/pxweb/sv/ssd/START__EN__EN0108/
Elprod; Belgium share of wind onshore generation of 4.1 TWh
and offshore 6.7 TWh, and solar generation of 4.3 TWh, from Elia
Group, “Belgium’s electricity mix in 2020: Renewable generation
up 31% in a year marked by the COVID-19 crisis”, 7 January 2021,
354
https://www.nrel.gov/docs/fy16osti/66616
https://www.nrel.gov/docs/fy16osti/66616
https://ourworldindata.org/cheap-renewables-growth
https://ourworldindata.org/cheap-renewables-growth
https://www.irena.org/newsroom/pressreleases/2020/Jun/Renewables-Increasingly-Beat-Even-Cheapest-Coal-Competitors-on-Cost
https://www.irena.org/newsroom/pressreleases/2020/Jun/Renewables-Increasingly-Beat-Even-Cheapest-Coal-Competitors-on-Cost
https://www.irena.org/newsroom/pressreleases/2020/Jun/Renewables-Increasingly-Beat-Even-Cheapest-Coal-Competitors-on-Cost
https://www.epa.gov/statelocalenergy/local-renewable-energy-benefits-and-resources
https://www.epa.gov/statelocalenergy/local-renewable-energy-benefits-and-resources
https://www.oecd.org/greengrowth/greening-energy/greengrowthandenergy.htm
https://www.oecd.org/greengrowth/greening-energy/greengrowthandenergy.htm
https://www.iea.org/topics/system-integration-of-renewables
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https://www.iea.org/reports/power-systems-in-transition
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Jun/IRENA_G20_grid_integration_2019
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Jun/IRENA_G20_grid_integration_2019
https://www.iea.org/reports/renewable-energy-market-update/covid-19-impact-on-renewable-energy-growth
https://www.iea.org/reports/renewable-energy-market-update/covid-19-impact-on-renewable-energy-growth
https://www.iea.org/reports/renewable-energy-market-update/covid-19-impact-on-renewable-energy-growth
https://www.weforum.org/agenda/2020/06/covid-19-is-a-game-changer-for-renewable-energy
https://www.weforum.org/agenda/2020/06/covid-19-is-a-game-changer-for-renewable-energy
https://reneweconomy.com.au/wind-and-solar-hit-record-grid-levels-in-europe-as-pandemic-curbs-energy-demand-83006
https://reneweconomy.com.au/wind-and-solar-hit-record-grid-levels-in-europe-as-pandemic-curbs-energy-demand-83006
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://reneweconomy.com.au/south-australia-fast-tracks-energy-plan-to-dodge-blackouts-and-meet-100-renewables-goal-43196
https://www.greentechmedia.com/articles/read/how-south-australia-is-dealing-with-rampant-solar-growth
https://www.greentechmedia.com/articles/read/how-south-australia-is-dealing-with-rampant-solar-growth
https://www.theguardian.com/business/2020/apr/28/britain-breaks-record-for-coal-free-power-generation
https://www.theguardian.com/business/2020/apr/28/britain-breaks-record-for-coal-free-power-generation
https://ember-climate.org/project/global-electricity-review-2021
https://ember-climate.org/project/global-electricity-review-2021
https://www.nrel.gov/docs/fy19osti/73869
https://www.nrel.gov/docs/fy19osti/73869
https://www.smart-energy.com/news/why-digitalisation-is-a-key-enabler-of-the-energy-transition
https://www.smart-energy.com/news/why-digitalisation-is-a-key-enabler-of-the-energy-transition
https://utilitymagazine.com.au/future-proofing-the-network-with-smart-substations
https://utilitymagazine.com.au/future-proofing-the-network-with-smart-substations
https://energycentral.com/c/gr/grid-modernization-2020-pushing-boundaries
https://energycentral.com/c/gr/grid-modernization-2020-pushing-boundaries
https://www.power-grid.com/smart-grid/next-generation-load-forecasting-critical-in-rapidly-changing-energy-landscape
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https://www.power-grid.com/smart-grid/next-generation-load-forecasting-critical-in-rapidly-changing-energy-landscape
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ens.dk/en/our-services/statistics-data-key-figures-and-energy-maps/annual-and-monthly-statistics
https://ben.miem.gub.uy/preliminar.php
https://ben.miem.gub.uy/preliminar.php
https://www.eirgridgroup.com/how-the-grid-works/renewables
https://www.eirgridgroup.com/how-the-grid-works/renewables
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.erneuerbare-energien.de/EE/Navigation/DE/Service/Erneuerbare_Energien_in_Zahlen/Zeitreihen/zeitreihen.html
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
https://www.dapeep.gr/wp-content/uploads/ELAPE/2020/08_DEC_2020_DELTIO_ELAPE_v1.0_21.03.2021
https://www.ree.es/sites/default/files/publication/2021/03/downloadable/avance_ISE_2020_EN
https://www.ree.es/sites/default/files/publication/2021/03/downloadable/avance_ISE_2020_EN
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972781/ET_5.1_MAR_21.xls
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972781/ET_5.1_MAR_21.xls
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/972781/ET_5.1_MAR_21.xls
https://www.centrodeinformacao.ren.pt/PT/InformacaoTecnica/DadosTecnicos/AFnet_RENPRO%20Brochura%20Dados%20T%C3%A9cnicos%202020
https://www.centrodeinformacao.ren.pt/PT/InformacaoTecnica/DadosTecnicos/AFnet_RENPRO%20Brochura%20Dados%20T%C3%A9cnicos%202020
https://www.centrodeinformacao.ren.pt/PT/InformacaoTecnica/DadosTecnicos/AFnet_RENPRO%20Brochura%20Dados%20T%C3%A9cnicos%202020
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https://opennem.org.au/energy/wem/?range=all&interval=1y
https://opendata.cbs.nl/statline/#/CBS/en/dataset/84575ENG/table?ts=1619216097037
https://opendata.cbs.nl/statline/#/CBS/en/dataset/84575ENG/table?ts=1619216097037
http://www.enee.hn/index.php/planificacionicono/182-boletines-estadisticos
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https://www.statistikdatabasen.scb.se/pxweb/sv/ssd/START__EN__EN0108/Elprod
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https://www.statistikdatabasen.scb.se/pxweb/sv/ssd/START__EN__EN0108/Elprod
ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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Shttps://www.elia.be/-/media/project/elia/shared/documents/
press-releases/2021/20210107-mix-electrique-2020_en ;
Chile wind generation of 5,537 GWh, and solar of 7,638 GWh,
from Generadoras de Chile, “Generación Eléctrica en Chile”,
http://generadoras.cl/generacion-electrica-en-chile; Nicaragua
share of wind net generation of 538,826 MWh and solar of 22,688
MWh, and total generation of 3,379,530 MWh, from Instituto
Nicaragüense de Energía, Ente Regulador, Generación Neta
Sistema Eléctrico Nacional Año 2020, https://www.ine.gob.ni/
DGE/estadisticas/2020/generacion_neta_dic20_actfeb21 ;
Italy share of wind generation of 18,547 GWh, solar generation
of 25,549 GWh, and total 273,108 GWh, from Terna, Rapporto
mensile sul Sistema Elettrico, https://download.terna.it/terna/
Rapporto_Mensile_Dicembre%202020_8d8b615dca4dafe .
18 V. Henze, “Scale-up of solar and wind puts existing coal, gas at
risk”, BloombergNEF, 28 April 2020, https://about.bnef.com/blog/
scale-up-of-solar-and-wind-puts-existing-coal-gas-at-risk.
19 Ibid.; P. Denholm et al., The Potential for Battery Energy Storage to
Provide Peaking Capacity in the United States (Golden, CO: NREL,
2019), https://www.nrel.gov/docs/fy19osti/74184 ; footnote
on the ‘Duck Curve’ effect based on Energy.gov, “Confronting the
duck curve: How to address over-generation of solar energy”, 12
October 2017, https://www.energy.gov/eere/articles/confronting-
duck-curve-how-address-over-generation-solar-energy, and on
P. N. Patel, “Developments in energy storage could spell the end
of the Duck Curve”, POWER, 1 June 2018, https://www.powermag.
com/developments-in-energy-storage-could-spell-the-end-of-
the-duck-curve.
20 reve, “Global demand for corporate renewable electricity sourcing
continues to grow despite COVID-19 pandemic”, 9 December
2020, https://www.evwind.es/2020/12/09/global-demand-for-
corporate-renewable-electricity-sourcing-continues-to-grow-
despite-covid-19-pandemic/78451.
21 IRENA, Innovation Landscape Brief: Innovative Ancillary Services
(Abu Dhabi: 2019), https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2019/Feb/IRENA_Innovative_ancillary_
services_2019 ; P. Denholm, Y. Sun and T. Mai, An Introduction
to Grid Services: Concepts, Technical Requirements, and Provision
from Wind (Golden, CO: NREL, 2019), https://www.nrel.gov/docs/
fy19osti/72578 .
22 D. Proctor, “FERC order backs grid market for DERs”,
POWER, 17 September 2020, https://www.powermag.com/
ferc-order-backs-grid-market-for-ders.
23 J. St. John, “California’s interconnection rules open doors to
flexible solar-storage, vehicle-to-grid charging”, Greentech Media,
30 September 2020, https://www.greentechmedia.com/articles/
read/californias-interconnection-rules-open-doors-to-flexible-
solar-storage-vehicle-to-grid-charging.
24 Smart Energy, “New ancillary service market paves the way
to a renewables-led future”, 6 December 2020, https://www.
smart-energy.com/industry-sectors/energy-grid-management/
new-ancillary-service-market-paves-the-way-to-a-renewables-
led-future; J. Parnell, “Renewable generators are the UK’s latest
tool to smooth out renewable generation”, Greentech Media, 23
June 2020, https://www.greentechmedia.com/articles/read/
renewable-generators-are-uks-latest-tool-to-smooth-out-
renewable-generation.
25 IRENA, op. cit. note 4.
26 IEA, “Electricity security in tomorrow's power systems”,
23 October 2020, https://www.iea.org/articles/
electricity-security-in-tomorrow-s-power-systems.
27 IRENA, Innovation Landscape Brief: Flexibility in Conventional
Power Plants (Abu Dhabi: 2019), https://www.irena.org/-/media/
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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IE
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72 IEA, op. cit. note 69.
73 Ibid.
356
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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S74 J. Turner, “HySHIP: Inside Europe’s flagship hydrogen ship
demonstrator project”, Ship Technology, 22 December 2020,
https://www.ship-technology.com/features/hydrogen-vessel;
ShipInsight, “MOL joins Wind Hunter project for wind and
hydrogen ship as step to zero emission future”, 1 December 2020,
https://shipinsight.com/articles/mol-joins-wind-hunter-project-
for-wind-and-hydrogen-ship-as-step-to-zero-emission-future;
G. Rowles, “Yara takes delivery of autonomous boxship Yara
Birkeland”, Splash, 30 November 2020”, https://splash247.com/
yara-takes-delivery-of-autonomous-boxship-yara-birkeland.
75 Transport Scotland, Rail Services Decarbonisation Action Plan
(Edinburgh: 2020), https://www.transport.gov.scot/media/47906/
rail-services-decarbonisation-action-plan ; D. Nag, “Indian
Railways plans to use surplus railway land to generate 20 GW of
renewable energy; details”, Financial Express, 27 August 2020,
https://www.financialexpress.com/infrastructure/railways/indian-
railways-plans-to-use-surplus-railway-land-to-generate-20-gw-
of-renewable-energy-details/2066847.
76 A. Hirschlag, “Next stop, hydrogen-powered trains”, BBC, 27
February 2020, https://www.bbc.com/future/article/20200227-
how-hydrogen-powered-trains-can-tackle-climate-change.
77 E. Bellini, “Flexible heat pumps ideal for power grids congested
by solar and wind”, pv magazine, 29 January 2021, https://www.
pv-magazine.com/2021/01/29/flexible-heat-pumps-ideal-for-
power-grids-congested-by-solar-and-wind.
78 M. Lempriere, “ICE ban brought forward to ‘2030’ in landmark
moment as Johnson releases Ten Point Plan”, Current, 18
November 2020, https://www.current-news.co.uk/news/ice-
ban-brought-forward-to-2030-in-landmark-moment-as-johnson-
releases-ten-point-plan.
79 Figure 54 adapted from IRENA, IEA and REN21, Renewable
Energy Policies in a Time of Transition (Abu Dhabi and Paris: 2018),
https://www.ren21.net/wp-content/uploads/2019/06/17-8622_
Policy_FullReport_web_FINAL .
80 IEA, Heat Pumps (Paris: 2020), https://www.iea.org/reports/
heat-pumps.
81 IRENA, Heat Pumps Technology Brief (Abu Dhabi: 2013), https://
www.irena.org/-/media/Files/IRENA/Agency/Publication/2013/
IRENA-ETSAP-Tech-Brief-E12-Heat-Pumps .
82 Ibid.
83 IRENA, IEA and REN21, Renewable Energy Policies in a Time of
Transition: Heating and Cooling (Abu Dhabi and Paris: 2020),
p. 50, https://www.ren21.net/wp-content/uploads/2019/05/
IRENA_IEA_REN21-Policies_HC_2020_Full_Report .
84 IRENA, op. cit. note 81; IRENA, IEA and REN21, op. cit. note 83, p 50.
85 IRENA, IEA and REN21, op. cit. note 83, p. 50.
86 Ibid., p. 50.
87 IRENA, IEA and REN21, op. cit. note 83, p. 50.
88 Ibid., p. 50.
89 M. Dyson et al., “Building electrification: A key to a safe climate
future”, Rocky Mountain Institute, 20 October 2020, https://
rmi.org/building-electrification-a-key-to-a-safe-climate-
future; J. Gerdes, “Heat pumps unlock the path to building
decarbonisation”, Energy Monitor, 29 December 2020, https://
energymonitor.ai/technology/electrification/heat-pumps-
unlock-the-path-to-building-decarbonisation; R. Lowe and T.
Oreszczyn, Building Decarbonisation Transition Pathways: Initial
Reflections (Oxford, UK: CREDS, 2020), https://www.creds.ac.uk/
wp-content/uploads/CREDS-decarb-transitions-brief-2020 .
90 IEA Heat Pumping Technologies, Heat Pumps in
District Heating and Cooling Systems (Paris: 2020),
https://heatpumpingtechnologies.org/publications/
annex-47-heat-pumps-in-district-heating-and-cooling-systems.
91 IEA, op. cit. note 80.
92 Ibid.
93 BloombergNEF, Energy Transition Investment Trends (London:
2021), slide 10, https://assets.bbhub.io/professional/sites/24/
Energy-Transition-Investment-Trends_Free-Summary_Jan2021 .
94 C. Zhao, Chinese Heat Pump Association, personal
communication with REN21, March 2021.
95 Chinaiol, “Monthly China’s household AC production (ten
thousand units)”, http://data.chinaiol.com/ecdata/index,
viewed 15 March 2021; Chinaiol is a market intelligence firm
focusing on the HVAC industry, consumer electronics, intelligent
manufacturing areas and provides data, information, and
consulting services for global enterprises.
96 Japan Refrigeration and Air Conditioning Industry Association
(JRAIA), “Domestic shipment record of home air conditioners
(room air conditioners)”, https://www.jraia.or.jp/statistic/detail.
html?ca=0&ca2=0 (using Google Translate), viewed 20 March
2021; JRAIA, “Domestic shipment record of commercial air
conditioners (package air conditioners)”, https://www.jraia.
or.jp/statistic/detail.html?ca=1&ca2=3 (using Google Translate),
viewed 20 March 2021.
97 Ibid., both references.
98 JRAIA, “Household heat pump water heater (Eco Cute) Domestic
shipment record”, https://www.jraia.or.jp/statistic/detail.
html?ca=0&ca2=1 (using Google Translate), viewed 20 March
2021.
99 BloombergNEF, op. cit. note 93.
100 Air Conditioning, Heating & Refrigeration Institute (AHRI), “AHRI
releases December 2020 U.S. Heating and Cooling Equipment
Shipment Data”, 12 February 2021, https://www.ahrinet.org/
App_Content/ahri/files/Statistics/Monthly%20Shipments/2020/
December_2020 .
101 BloombergNEF, op. cit. note 93.
102 Heating, Refrigeration and Air Conditioning Institute of Canada
(HRAI), “Canadian HVACR Equipment Quarterly Statistics”,
https://www.hrai.ca/hvacr-statistics, viewed 25 March 2021.
103 European Heat Pump Association (EHPA), “Market Data”, https://
www.ehpa.org/market-data, viewed 30 March 2021; T. Nowak,
EHPA, personal communication with REN21, 25 March 2021.
104 EHPA, op. cit. note 103.
105 Ibid.
106 Bundesverband Energiespeicher Systeme (BVES) e.V., “BVES
Branchenanalyse 2021 – Entwicklung und Perspektiven der
Energiespeicherbranche in Deutschland”, 15 March 2021,
https://www.bves.de/wp-content/uploads/2021/03/2021_
BVES_Branchenanalyse ; S. Amelang, “Germany crosses
threshold of one million heat pumps”, Clean Energy Wire, 10
December 2020, https://www.cleanenergywire.org/news/
germany-crosses-threshold-one-million-heat-pumps.
107 S. Amelang, “Heat pump industry expects strong growth in Germany
after tepid increase in 2019”, Clean Energy Wire, 31 January 2020,
https://www.cleanenergywire.org/news/heat-pump-industry-
expects-strong-growth-germany-after-tepid-increase-2019.
108 Ministère de la transition écologique et solidaire, “Coup de pouce
‘Chauffage’ et "Isolation”, 14 April 2021, https://www.ecologie.gouv.
fr/coup-pouce-chauffage-et-isolation; Gestore Servizi Energetici,
“Conto Termico”, https://www.gse.it/servizi-per-te/efficienza-
energetica/conto-termico, viewed 20 March 2021; UK BEIS,
“Welcome to the Domestic Renewable Heat Incentive payment
calculator”, https://renewable-heat-calculator.service.gov.uk,
viewed 30 March 2021.
109 R. Lowes, J. Rosenow and P. Guertler, Getting on Track to Net
Zero: A Policy Package for a Heat Pump Mass Market in the
UK (Brussels: 2021), https://www.raponline.org/wp-content/
uploads/2021/03/RAP-Heat-Pump-Policy-0324212 .
110 EHPA, Large Scale Heat Pumps in Europe: Vol. 2 (Brussels: 2020),
https://www.ehpa.org/fileadmin/user_upload/Large_heat_
pumps_in_Europe_Vol_2_FINAL .
111 R. de Boer et al, Strengthening Industrial Heat Pump Innovation:
Decarbonizing Industrial Heat (The Hague: SINTEF et al., 2020),
https://www.sintef.no/globalassets/sintef-energi/industrial-heat-
pump-whitepaper/2020-07-10-whitepaper-ihp-a4 .
112 Ibid.
113 NIBE, Year-end Report 2020 (Stockholm: 2021), https://www.
nibe.com/download/18.a8733e21778fd3d0f07f9/1613500169613/
GB-Q4-2020-NIBE-EN .
114 B. Coyne, “Legal & General buys into heat pump firm Kensa”,
The Energyst, 17 April 2020, https://theenergyst.com/
legal-general-buys-into-heat-pump-firm-kensa.
115 European Commission (EC), “Case M.9858 – BOSCH GROUP/
ELCO GROUP/JV REGULATION (EC) No 139/2004 MERGER
PROCEDURE” (Brussels: 2020), https://ec.europa.eu/
competition/mergers/cases1/202035/m9858_166_3 .
116 K. Uhlenhuth, “Not just solar: Ikea breaking new ground in
geothermal, too”, Energy News Network, 13 June 2014,
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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117 US DOE, OEERE, Prefabricated Zero Energy Retrofit Technologies:
A Market Assessment (Washington, DC: 2020), https://rmi.org/
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118 LG, LG Smart Home Energy Package (Seoul: 2020), https://
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ENERGY%20PACKAGE ; R. Diermann, “LG Electronics
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119 Ibid., both references.
120 US DOE, OEERE, op. cit. note 117.
121 EHPA, “Virtual tour at Factory Zero – presentations and video now
available”, 7 October 2020, https://www.ehpa.org/about/news/
article/virtual-tour-at-factory-zero-presentations-and-video-now-
available; EHPA, “Press release: Heat pumps are now ready to surf
the renovation wave”, 20 November 2020, https://www.ehpa.org/
about/news/article/press-release-heat-pumps-are-now-ready-
to-surf-the-renovation-wave; EC, “Towards a smart, efficient and
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122 IEA, Energy Technology Perspectives 2020 (Paris: 2020), p. 164,
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123 EC, “EU legislation to control F-gases”, https://ec.europa.eu/
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124 Ibid., both references.
125 IEA Heat Pumping Technologies, “IEA HPT Annex 54: Heat
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126 J. Gerdes, “Massachusetts pilot project offers gas utilities a possible
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127 “Stonewater and Kensa pilot smart city scheme”, GeoDrilling
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128 NewClimate Institute, Renewable Heating Virtual Article 6 Pilot
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130 de Boer et al., op. cit. note 111.
131 Ibid.
132 Ibid.
133 L. Sugden, The 2020s Is the Decade to Decarbonise Heat (Edinburgh:
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134 C. Weiller and R. Sioshansi, “The role of plug-in electric vehicles
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136 J. Borrás, “Thailand gets fleet of electric ferries to help clean up
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137 IEA, Global EV Outlook 2021 (Paris: 2021), https://www.iea.org/
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138 A. Bertoli, “How many EV drivers have solar power In USA
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139 IEA, op. cit. note 137.
140 Ibid.
141 Ibid. Figure 55 based on idem.
142 M. Gorner and L. Paoli, “How global electric car sales defied Covid-19
in 2020”, IEA, 28 January 2021, https://www.iea.org/commentaries/
how-global-electric-car-sales-defied-covid-19-in-2020.
143 IEA, op. cit. note 137.
144 Ibid.
145 Gorner and Paoli, op. cit. note 142; IEA, op. cit. note 137.
146 IEA, op. cit. note 137.
147 Ibid.
148 Ibid.
149 H. Shukla, “Electric two-wheeler sales decline by 5.46% in
2020”, Mercom India, 7 January 2021, https://mercomindia.com/
electric-two-wheeler-sales-decline.
150 IEA, op. cit. note 137.
151 Ibid.
152 Ibid.; “Electric bus, main fleets and projects around the world”,
Sustainable Bus, 19 May 2020, https://www.sustainable-bus.com/
electric-bus/electric-bus-public-transport-main-fleets-projects-
around-world; BloombergNEF, op. cit. note 96, slide 9.
153 BloombergNEF, op. cit. note 93, slide 9.
154 Ibid., slide 9.
155 Ibid., slide 9.
156 “Electric bus, main fleets and projects around the world”, op. cit.
note 152.
157 IEA, op. cit. note 137; “Electric bus, main fleets and projects
around the world”, op. cit. note 155; “The pandemic doesn’t stop
the European e-bus market: +22% in 2020”, Sustainable Bus,
19 February 2021, https://www.sustainable-bus.com/news/
europe-electric-bus-market-2020-covid.
158 “Denmark, Luxembourg, & Netherlands lead on electric buses In
Europe”, CleanTechnica, 15 January 2021, https://cleantechnica.
com/2021/01/15/denmark-luxembourg-netherlands-lead-on-
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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S159 IEA, op. cit. note 137; Dialogo Chino, “La transición hacia buses
eléctricos en América Latina es irreversible”, 10 December 2020,
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hacia-buses-electricos-en-america-latina-es-irreversible.
160 J. Sensiba, “Bogota gets 470 new electric buses, Berlin gets
90”, CleanTechnica, 31 December 2020, https://cleantechnica.
com/2020/12/31/bogota-gets-470-new-electric-buses-berlin-
gets-90; Dialogo Chino, op. cit. note 159; “Bogotá, la ciudad con
mayor número de buses eléctricos en Latinoamérica”, Semana,
11 January 2021, https://www.semana.com/nacion/articulo/
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161 IEA, op. cit. note 137.
162 “California pushes for the transition to electric buses: Only
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163 IEA, op. cit. note 137.
164 BloombergNEF, op. cit. note 93, slide 9.
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166 S. Hanley, “China invests in EV charging infrastructure to offset
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167 IEA, op. cit. note 137.
168 Ibid.
169 Government of Canada, “Building back better: A plan to fight the
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170 IEA, Rail (Paris: 2020), https://www.iea.org/reports/rail.
171 A. Chaturvedi, “100% electrification in railways in next
3.5 years, says Piyush Goyal”, Hindustan Times, 16 July
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172 C. Ames, “38% of Britain’s rail network now electrified”, Transport
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173 Z. Shahan, “Global plugin vehicle sales up 43% in 2020, European
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174 M. Holland, “Tesla passes 1 million EV milestone & Model 3
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175 J. Attwood, “Renault Zoe eclipses Tesla Model 3 as Europe's
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176 E. Cheng, “Chinese electric car company Nio doubles deliveries in
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177 D. Broom, “2020 was a breakthrough year for electric
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179 J. Rosenholtz, “2022 GMC Hummer EV first look review:
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181 Ibid.
182 Shahan, op. cit. note 173.
183 Ibid.
184 J. Parnell, “Shell, Volvo and Daimler back hydrogen as Europe
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185 J. Crider, “Mercedes-Benz is done chasing the
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186 R. J. Kuhudzai, “1st Ethiopian-assembled all-electric Hyundai Ioniq
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engineering-plant.
187 CNBC, “LG and Magna announce billion dollar joint venture
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com/2020/12/23/lg-and-magna-announce-billion-dollar-
joint-venture-in-electric-car-gear.html; J. Parnell, “A battery
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188 Mitsui O. S. K. Lines, “‘e5 Consortium’ established to promote
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189 IEA, “A rapid rise in battery innovation is playing a key role in
clean energy transitions”, 22 September 2020, https://www.iea.
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role-in-clean-energy-transitions.
190 BloombergNEF, “Battery pack prices cited below $100/kWh
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pack-prices-cited-below-100-kwh-for-the-first-time-in-2020-
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191 BloombergNEF, op. cit. note 190.
192 H. Shukla, “Daily news wrap-up: Tesla to make cobalt free
batteries”, Mercom India, 24 September 2020, https://
mercomindia.com/daily-news-wrap-up-tesla-batteries.
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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S193 D. Robinson, “Six electric vehicle charging innovations that
could be crucial to green transport revolution”, NS Energy,
27 April 2020, https://www.nsenergybusiness.com/features/
electric-vehicle-charging-innovations; D. Robinson, “Electric
taxis can now be charged wirelessly in UK city in £3.4m trial”,
NS Energy, 17 January 2020, https://www.ns-businesshub.com/
transport/wireless-charging-electric-vehicles-nottingham;
Momentum Dynamics, “Link Transit, Wenatchee WA celebrates
50 mwh of energy delivered wirelessly to electric bus fleet”, 19
May 2020, https://momentumdynamics.com/2020/05/19/link-
transit-wenatchee-wa-celebrates-50-mwh-of-energy-delivered-
wirelessly-to-electric-bus-fleet; J. Bellington, “China announces
national standard for wireless electric vehicle charging”, Electric
& Hybrid Vehicle Technology News, 7 May 2020, https://www.
electrichybridvehicletechnology.com/news/charging-technology/
china-announces-national-standard-for-wireless-electric-vehicle-
charging.html.
194 Robinson, op. cit. note 193; InsideEVs, “These pop-up public
charging points by Urban Electric are pretty neat”, 16 May 2020,
https://insideevs.com/news/423649/urban-electric-discrete-
pop-up-public-charge-points; Urban Electric, “Convenient
on-street electric vehicle charging”, https://www.urbanelectric.
london, viewed 11 May 2021; J. S. Murray, “Seeing the light:
Siemens powers up UK's first ‘Electric Avenue’”, Business Green,
19 March 2020, https://www.businessgreen.com/news/4012735/
seeing-light-siemens-powers-uk-electric-avenue.
195 C. Hanvey, “EV managed charging: Lessons from
utility pilot programs”, Smart Electric Power Alliance,
25 July 2019, https://sepapower.org/knowledge/
ev-managed-charging-lessons-from-utility-pilot-programs.
196 R. Lee and S. Brown, “How superfast charging batteries can
help sell the transition to electric vehicles”, The Conversation,
26 January 2021, https://theconversation.com/how-superfast-
charging-batteries-can-help-sell-the-transition-to-electric-
vehicles-153872; SoreDot, “Technology”, https://www.store-dot.
com/technology, viewed 11 May 2021.
197 V2G Hub, “Insights”, https://www.v2g-hub.com/insights/
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198 Ibid.
199 T. Casey, “Scotland banks on hydrogen fuel cell trains for zero
emission railway by 2035”, CleanTechnica, 1 January 2021, https://
cleantechnica.com/2021/01/01/scotland-banks-on-hydrogen-
fuel-cell-trains-for-zero-emission-railway-by-2035; A. Davis,
“Transport for the North hails region as a pioneer of hydrogen
transport technologies”, Highways Today, 5 October 2020, https://
highways.today/2020/10/05/transport-north-hydrogen-transport.
200 Hirschlag, op. cit. note 76.
201 T. Casey, “Hard sails & green hydrogen for the cargo
ships of the future”, CleanTechnica, 3 December
2020, https://cleantechnica.com/2020/12/03/
hard-sails-green-hydrogen-for-the-cargo-ships-of-the-future.
202 T. Mullaney, “Rolls-Royce thinks it can make a plane Greta
Thunberg would fly in”, CNBC, 15 December 2019, https://www.
cnbc.com/2019/12/16/rolls-royce-thinks-it-can-make-a-plane-
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com, viewed 11 May 2021; Rolls-Royce, “ACCEL: Entering the
era of zero-emissions aviation”, https://www.rolls-royce.com/
innovation/accel.aspx, viewed 11 May 2021; Airbus, “Electric
flight”, https://www.airbus.com/innovation/zero-emission/
electric-flight.html, viewed 11 May 2021.
203 Wisk, “What’s happening at Wisk”, https://wisk.aero/news,
viewed 11 May 2021.
204 Environmental and Energy Study Institute, “Fact Sheet: Energy
Storage” (Washington, DC: 22 February 2019), https://www.
eesi.org/files/FactSheet_Energy_Storage_0219 ; M. Stanley
Whittingham, “History, evolution, and future status of energy
storage”, Proceedings of the IEEE, vol. 100 (13 May 2012), https://
ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6184265.
205 IRENA, “Energy storage”, https://www.irena.org/costs/Power-
Generation-Costs/Energy-Storage, viewed 11 May 2021; Energy
Storage (IEA), “Flexible sector coupling – annex 35”, https://iea-
eces.org/annex-35, viewed 11 May 2021.
206 See Energy Systems Integration and Enabling Technologies
chapters in REN21, Renewables 2019 Global Status Report (Paris:
2019), https://www.ren21.net/gsr-2019 and REN21, Renewables 2018
Global Status Report (Paris: 2018), https://www.ren21.net/gsr-2018.
207 A. Colthorpe, “Energy storage markets ‘resilient to the pandemic’,
says Wärtsilä CEO”, Energy Storage News, 28 January 2021,
https://www.energy-storage.news/news/energy-storage-
markets-resilient-to-the-pandemic-says-waertsilae-ceo; European
Association for Storage of Energy (EASE), “Energy storage and
the COVID-19 recovery: Time for policymakers to step up their
commitments”, 7 July 2020, https://ease-storage.eu/news/energy-
storage-and-the-covid-19-recovery-time-for-policymakers-to-step-
up-their-commitments; IEA, “Energy integration”, in The Covid-19
Crisis and Clean Energy Progress (Paris: 2020, https://www.iea.
org/reports/the-covid-19-crisis-and-clean-energy-progress/
energy-integration#energy-storage.
208 China Energy Storage Alliance (CNESA), “The White Paper on
Energy Storage Industry Research 2021 was released, and the
new scale of electrochemical energy storage in China broke
through the GW mark”, 24 April 2021, http://www.cnesa.org/
index/inform_detail?cid=6083e524b1fd37c5358b456e (using
Google Translate); Sacred Sun, “CNESA officially released "Energy
Storage Industry White Paper 2021”, 26 April 2021, https://www.
sacredsun.com/News/Industry/2021/0426/Energy-Storage-
Industry-White-Paper-2021.html; IEA, “Energy storage”, in Tracking
Energy Integration 2020 (Paris: 2020), https://www.iea.org/reports/
tracking-energy-integration-2020; IEA, op. cit. note 207.
209 See Investment chapter in this report. F. Mayr, “Energy storage
in a post-pandemic world: Taking stock and preparing for future
success – part two”, Energy Storage News, 13 July 2020, https://
www.energy-storage.news/blogs/energy-storage-in-a-post-
pandemic-world-taking-stock-and-preparing-for; Colthorpe, op.
cit. note 207; S. Yubo, “2020 energy storage industry summary:
A new stage in large-scale development”, CNESA, 1 March 2021,
http://en.cnesa.org/latest-news/2021/2/28/2020-energy-storage-
industry-summary-a-new-stage-in-large-scale-development.
210 CNESA, op. cit. note 208. Figure 56 from idem and from CNESA,
Energy Storage Industry White Paper 2020 (Beijing: 2020),
http://en.cnesa.org/white-paper-access-multyear.
211 Yubo, op. cit. note 209.
212 Wood Mackenzie, “U.S. Energy Storage Monitor”, https://www.
woodmac.com/research/products/power-and-renewables/
us-energy-storage-monitor, viewed 4 March 2020; Wood
Mackenzie, “US energy storage market shatters quarterly
deployment record”, 3 March 2021, https://www.woodmac.com/
press-releases/us-energy-storage-market-shatters-quarterly-
deployment-record; Center for Sustainable Systems, University of
Michigan, “U.S. Energy Storage Factsheet” (Ann Arbor, MI: 2020),
http://css.umich.edu/factsheets/us-grid-energy-storage-factsheet.
213 EASE, “EMMES 5.0 – March 2021”, https://ease-storage.eu/
publication/emmes-5-0-march-2021.
214 N. El Chami, “Europe’s energy storage transformation”, Energy
Storage News, 9 November 2020, https://www.energy-storage.
news/blogs/europes-energy-storage-transformation.
215 CNESA, op. cit. note 208.
216 Ibid.
217 Ibid.
218 CNESA, “Global energy storage market analysis – 2020.Q3 (summary),
November 2020”, 17 November 2020, http://en.cnesa.org/latest-
news/2020/11/17/cnesa-global-energy-storage-market-analysis
2020q3-summary.
219 CNESA, op. cit. note 208; Yubo, op. cit. note 209; BloombergNEF,
op. cit. note 93.
220 Wood Mackenzie, “An attempted shortlist of the major
breakthroughs in the energy storage industry’s biggest year
ever”, Greentech Media, 28 December 2019, https://www.
greentechmedia.com/articles/read/the-top-10-energy-storage-
stories-of-2020; American Clean Power, “American Clean Power
Market Report Q4 2020”, slide 25/26, 2020, https://cleanpower.
org/resources/american-clean-power-market-report-q4-2020.
221 Ibid., both references; BloombergNEF, op. cit. note 93, slide 9.
Other projects from the following: C. Katz, “In boost for renewables,
grid-scale battery storage is on the rise”, Yale e360, 15 December
2020, https://e360.yale.edu/features/in-boost-for-renewables-
grid-scale-battery-storage-is-on-the-rise; K. Pickerel, “World’s
largest lithium-based energy storage system storing 1,200 MWh
of power now online in California”, Solar Power World, 6 January
2021 https://www.solarpowerworldonline.com/2021/01/worlds-
largest-lithium-based-energy-storage-system-storing-1200-
mwh-of-power-now-online-in-california; “In a first, TVA to install
360
https://www.nsenergybusiness.com/features/electric-vehicle-charging-innovations
https://www.nsenergybusiness.com/features/electric-vehicle-charging-innovations
https://www.ns-businesshub.com/transport/wireless-charging-electric-vehicles-nottingham
https://www.ns-businesshub.com/transport/wireless-charging-electric-vehicles-nottingham
https://momentumdynamics.com/2020/05/19/link-transit-wenatchee-wa-celebrates-50-mwh-of-energy-delivered-wirelessly-to-electric-bus-fleet
https://momentumdynamics.com/2020/05/19/link-transit-wenatchee-wa-celebrates-50-mwh-of-energy-delivered-wirelessly-to-electric-bus-fleet
https://momentumdynamics.com/2020/05/19/link-transit-wenatchee-wa-celebrates-50-mwh-of-energy-delivered-wirelessly-to-electric-bus-fleet
https://www.electrichybridvehicletechnology.com/news/charging-technology/china-announces-national-standard-for-wireless-electric-vehicle-charging.html
https://www.electrichybridvehicletechnology.com/news/charging-technology/china-announces-national-standard-for-wireless-electric-vehicle-charging.html
https://www.electrichybridvehicletechnology.com/news/charging-technology/china-announces-national-standard-for-wireless-electric-vehicle-charging.html
https://www.electrichybridvehicletechnology.com/news/charging-technology/china-announces-national-standard-for-wireless-electric-vehicle-charging.html
https://insideevs.com/news/423649/urban-electric-discrete-pop-up-public-charge-points
https://insideevs.com/news/423649/urban-electric-discrete-pop-up-public-charge-points
https://www.urbanelectric.london
https://www.urbanelectric.london
https://www.businessgreen.com/news/4012735/seeing-light-siemens-powers-uk-electric-avenue
https://www.businessgreen.com/news/4012735/seeing-light-siemens-powers-uk-electric-avenue
https://sepapower.org/knowledge/ev-managed-charging-lessons-from-utility-pilot-programs
https://sepapower.org/knowledge/ev-managed-charging-lessons-from-utility-pilot-programs
https://theconversation.com/how-superfast-charging-batteries-can-help-sell-the-transition-to-electric-vehicles-153872
https://theconversation.com/how-superfast-charging-batteries-can-help-sell-the-transition-to-electric-vehicles-153872
https://theconversation.com/how-superfast-charging-batteries-can-help-sell-the-transition-to-electric-vehicles-153872
https://www.store-dot.com/technology
https://www.store-dot.com/technology
https://www.v2g-hub.com/insights/status#graphs
https://www.v2g-hub.com/insights/status#graphs
https://cleantechnica.com/2021/01/01/scotland-banks-on-hydrogen-fuel-cell-trains-for-zero-emission-railway-by-2035
https://cleantechnica.com/2021/01/01/scotland-banks-on-hydrogen-fuel-cell-trains-for-zero-emission-railway-by-2035
https://cleantechnica.com/2021/01/01/scotland-banks-on-hydrogen-fuel-cell-trains-for-zero-emission-railway-by-2035
https://highways.today/2020/10/05/transport-north-hydrogen-transport
https://highways.today/2020/10/05/transport-north-hydrogen-transport
https://cleantechnica.com/2020/12/03/hard-sails-green-hydrogen-for-the-cargo-ships-of-the-future
https://cleantechnica.com/2020/12/03/hard-sails-green-hydrogen-for-the-cargo-ships-of-the-future
https://www.cnbc.com/2019/12/16/rolls-royce-thinks-it-can-make-a-plane-greta-thunberg-would-fly-in.html
https://www.cnbc.com/2019/12/16/rolls-royce-thinks-it-can-make-a-plane-greta-thunberg-would-fly-in.html
https://www.cnbc.com/2019/12/16/rolls-royce-thinks-it-can-make-a-plane-greta-thunberg-would-fly-in.html
https://airracee.com
https://airracee.com
https://www.rolls-royce.com/innovation/accel.aspx
https://www.rolls-royce.com/innovation/accel.aspx
https://www.airbus.com/innovation/zero-emission/electric-flight.html
https://www.airbus.com/innovation/zero-emission/electric-flight.html
https://wisk.aero/news
https://www.eesi.org/files/FactSheet_Energy_Storage_0219
https://www.eesi.org/files/FactSheet_Energy_Storage_0219
https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6184265
https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=6184265
https://www.irena.org/costs/Power-Generation-Costs/Energy-Storage
https://www.irena.org/costs/Power-Generation-Costs/Energy-Storage
https://iea-eces.org/annex-35
https://iea-eces.org/annex-35
https://www.ren21.net/gsr-2019
https://www.ren21.net/gsr-2018
https://www.energy-storage.news/news/energy-storage-markets-resilient-to-the-pandemic-says-waertsilae-ceo
https://www.energy-storage.news/news/energy-storage-markets-resilient-to-the-pandemic-says-waertsilae-ceo
https://ease-storage.eu/news/energy-storage-and-the-covid-19-recovery-time-for-policymakers-to-step-up-their-commitments
https://ease-storage.eu/news/energy-storage-and-the-covid-19-recovery-time-for-policymakers-to-step-up-their-commitments
https://ease-storage.eu/news/energy-storage-and-the-covid-19-recovery-time-for-policymakers-to-step-up-their-commitments
https://www.iea.org/reports/the-covid-19-crisis-and-clean-energy-progress/energy-integration#energy-storage
https://www.iea.org/reports/the-covid-19-crisis-and-clean-energy-progress/energy-integration#energy-storage
https://www.iea.org/reports/the-covid-19-crisis-and-clean-energy-progress/energy-integration#energy-storage
http://www.cnesa.org/index/inform_detail?cid=6083e524b1fd37c5358b456e
http://www.cnesa.org/index/inform_detail?cid=6083e524b1fd37c5358b456e
https://www.sacredsun.com/News/Industry/2021/0426/Energy-Storage-Industry-White-Paper-2021.html
https://www.sacredsun.com/News/Industry/2021/0426/Energy-Storage-Industry-White-Paper-2021.html
https://www.sacredsun.com/News/Industry/2021/0426/Energy-Storage-Industry-White-Paper-2021.html
https://www.iea.org/reports/tracking-energy-integration-2020
https://www.iea.org/reports/tracking-energy-integration-2020
https://www.energy-storage.news/blogs/energy-storage-in-a-post-pandemic-world-taking-stock-and-preparing-for
https://www.energy-storage.news/blogs/energy-storage-in-a-post-pandemic-world-taking-stock-and-preparing-for
https://www.energy-storage.news/blogs/energy-storage-in-a-post-pandemic-world-taking-stock-and-preparing-for
http://en.cnesa.org/latest-news/2021/2/28/2020-energy-storage-industry-summary-a-new-stage-in-large-scale-development
http://en.cnesa.org/latest-news/2021/2/28/2020-energy-storage-industry-summary-a-new-stage-in-large-scale-development
http://en.cnesa.org/white-paper-access-multyear
https://www.woodmac.com/research/products/power-and-renewables/us-energy-storage-monitor
https://www.woodmac.com/research/products/power-and-renewables/us-energy-storage-monitor
https://www.woodmac.com/research/products/power-and-renewables/us-energy-storage-monitor
https://www.woodmac.com/press-releases/us-energy-storage-market-shatters-quarterly-deployment-record
https://www.woodmac.com/press-releases/us-energy-storage-market-shatters-quarterly-deployment-record
https://www.woodmac.com/press-releases/us-energy-storage-market-shatters-quarterly-deployment-record
http://css.umich.edu/factsheets/us-grid-energy-storage-factsheet
https://ease-storage.eu/publication/emmes-5-0-march-2021
https://ease-storage.eu/publication/emmes-5-0-march-2021
https://www.energy-storage.news/blogs/europes-energy-storage-transformation
https://www.energy-storage.news/blogs/europes-energy-storage-transformation
http://en.cnesa.org/latest-news/2020/11/17/cnesa-global-energy-storage-market-analysis2020q3-summary
http://en.cnesa.org/latest-news/2020/11/17/cnesa-global-energy-storage-market-analysis2020q3-summary
http://en.cnesa.org/latest-news/2020/11/17/cnesa-global-energy-storage-market-analysis2020q3-summary
https://www.greentechmedia.com/articles/read/the-top-10-energy-storage-stories-of-2020
https://www.greentechmedia.com/articles/read/the-top-10-energy-storage-stories-of-2020
https://www.greentechmedia.com/articles/read/the-top-10-energy-storage-stories-of-2020
https://cleanpower.org/resources/american-clean-power-market-report-q4-2020
https://cleanpower.org/resources/american-clean-power-market-report-q4-2020
https://e360.yale.edu/features/in-boost-for-renewables-grid-scale-battery-storage-is-on-the-rise
https://e360.yale.edu/features/in-boost-for-renewables-grid-scale-battery-storage-is-on-the-rise
https://www.solarpowerworldonline.com/2021/01/worlds-largest-lithium-based-energy-storage-system-storing-1200-mwh-of-power-now-online-in-california
https://www.solarpowerworldonline.com/2021/01/worlds-largest-lithium-based-energy-storage-system-storing-1200-mwh-of-power-now-online-in-california
https://www.solarpowerworldonline.com/2021/01/worlds-largest-lithium-based-energy-storage-system-storing-1200-mwh-of-power-now-online-in-california
ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
EN
ER
GY
S
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TE
M
S
IN
TE
GR
AT
IO
N
AN
D
EN
AB
LI
NG
T
EC
HN
OL
OG
IE
Sits own 40-MWh battery storage system”, Renewable Energy
World, 23 September 2020, https://www.renewableenergyworld.
com/2020/09/23/in-a-first-tva-to-install-its-own-40-mwh-battery-
storage-system; C. Galford, “Southern California Edison contracts
four projects to add 590 MW of battery energy storage”, Daily
Energy Insider, 9 December 2020, https://dailyenergyinsider.com/
news/28269-southern-california-edison-contracts-four-projects-
to-add-590-mw-of-battery-energy-storage; J. St. John, “California
shifts $100M in behind-the-meter battery incentives to low-income
communities”, Greentech Media, 23 October 2020, https://www.
greentechmedia.com/amp/article/california-shifts-backup-battery-
incentives-to-help-low-income-communities.
222 American Clean Power, op. cit. note 220, slide 26; J. Spector, “LS
Power energizes world’s biggest battery, just in time for California’s
heat wave”, Greentech Media, 19 August 2020, https://www.
greentechmedia.com/articles/read/ls-power-energizes-worlds-
biggest-battery-near-san-diego-just-in-time-for-heatwave; P.
Ciampoli, “Texas utility plans first utility-scale storage projects”,
American Public Power Association, 3 January 2020, https://
www.publicpower.org/periodical/article/texas-utility-plans-
first-utility-scale-storage-projects; A. Bertola, “World’s largest
energy storage system proposed in Morro Bay”, KSBY News,
18 February 2021, https://www.ksby.com/news/local-news/
worlds-largest-energy-storage-system-proposed-in-morro-bay.
223 Wood Mackenzie, “US energy storage market
shatters quarterly deployment record”, 3 March 2021,
https://www.woodmac.com/press-releases/us-energy-
storage-market-shatters-quarterly-deployment-record.
224 BVES, op. cit. note 106, slide 6.
225 BSW Solar, “Solar battery boom”, 18 February 2021, https://www.
solarwirtschaft.de/en/2021/02/18/solar-battery-boom.
226 Clean Energy Regulator, “State data for battery installations with
small-scale systems”, http://www.cleanenergyregulator.gov.au/
DocumentAssets/Pages/State-data-for-battery-installations-
with-small-scale-systems.aspx, viewed 10 May 2021.
227 Electricity Markets & Policy, “Hybrid power plants are growing
rapidly: Are they a good idea?” 13 March 2020, https://emp.
lbl.gov/news/hybrid-power-plants-are-growing-rapidly-are;
BloombergNEF, How PV-Plus Storage Will Compete With Gas
Generation in the U.S. (London: 2020), https://assets.bbhub.io/
professional/sites/24/BloombergNEF-How-PV-Plus-Storage-
Will-Compete-With-Gas-Generation-in-the-U.S.-Nov-2020 .
228 A. Colthorpe, “Large-scale renewables-plus-storage projects in
US more than doubled from 2016 to 2019”, Energy Storage, 26
May 2020, https://www.energy-storage.news/news/large-scale-
renewables-plus-storage-projects-in-us-more-than-doubled-
from-2; BloombergNEF, op. cit. note 227. Example of projects
from the following: “Trailblazing PV-storage contract shows
growing dispatch skills”, Reuters, 12 February 2020, https://www.
reutersevents.com/renewables/pv-insider/trailblazing-pv-storage-
contract-shows-growing-dispatch-skills; List Solar, “New Mexico
energy plans nearly 1GW of solar-plus-storage to change coal
plant”, 13 October 2020, https://list.solar/news/new-mexico-
energy; S. Hanley, “Solar, storage, and wind — success stories
In Australia, US, and Vietnam”, CleanTechnica, 18 October 2020,
https://cleantechnica.com/2020/10/18/solar-storage-and-wind-
success-stories-in-australia-us-and-vietnam/amp; J. St. John,
“Southern California Edison contracts huge storage portfolio to
replace gas plants”, Greentech Media, 1 May 2020, https://www.
greentechmedia.com/articles/read/southern-california-edison-
picks-770mw-of-energy-storage-projects-to-be-built-by-next-year.
229 Energy Iceberg, “Renewable hybrid ‘great leap forward’”,
25 November 2020, https://energyiceberg.com/
china-renewable-hybrid-hype.
230 Saur Energy International, “Sungrow supplies 21 MWh solar-plus-
storage plant in Japan”, 8 February 2021, https://www.saurenergy.
com/solar-energy-news/sungrow-supplies-21-mwh-solar-plus-
storage-plant-in-japan; E. Bellini, “Solar-plus-storage as an
antidote to grid congestion in Japan’s northern island of Hokkaido”,
pv magazine, 8 February 2021, https://www.pv-magazine.
com/2021/02/08/solar-plus-storage-as-an-antidote-to-grid-
congestion-in-japans-northern-island-of-hokkaido.
231 CNESA, op. cit. note 208.
232 IRENA, Innovation Outlook: Thermal Energy Storage (Abu
Dhabi: 2020), https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2020/Nov/IRENA_Innovation_Outlook_
TES_2020 ; M. Farmer, “Thermal energy storage set to
triple – lessons from IRENA”, Power Technology, 6 January
2021, https://www.power-technology.com/features/
thermal-energy-storage-set-to-triple-lessons-from-irena.
233 See CSP section in Market and Industry chapter of this report.
IRENA, op. cit. note 232.
234 IRENA, op. cit. note 232.
235 Ibid., p. 46. See Solar Heating and Cooling section in Market
and Industry chapter of this report.
236 Ibid.; IEA Energy Conservation Through Energy Storage (IEA-
ECES), Applications of Thermal Energy Storage in the Energy
Transition – Benchmarks and Developments (Paris: 2018), https://
www.eces-a30.org/wp-content/uploads/Applications-of-
Thermal-Energy-Storage-in-the-Energy-Trenasition-Annex-30_
Public-Report .
237 State of Green, “Large-scale thermal storage pit”, https://
stateofgreen.com/en/partners/ramboll/solutions/large-scale-
thermal-pit-storage, viewed 10 May 2021.
238 IEA-ECES, op. cit. note 236; IRENA, op. cit. note 232.
239 Asian Development Bank, Solar District Heating in the People’s
Republic of China (Manila: 2019), https://www.adb.org/sites/
default/files/publication/514916/solar-district-heating-peoples-
republic-china .
240 IRENA, Green Hydrogen: A Guide to Policy Making (Abu Dhabi: 2020),
https://www.irena.org/publications/2020/Nov/Green-hydrogen.
241 Ibid.; D. Leitch, “Hydrogen: The great energy hope, or a whole lot
of hype?” RenewEconomy, 15 July 2020, https://reneweconomy.
com.au/hydrogen-the-great-energy-hope-or-a-whole-lot-of-
hype-16691; J. Parnell, “Europe’s green hydrogen revolution
is turning blue”, Greentech Media, 1 July 2020, https://www.
greentechmedia.com/articles/read/europes-green-hydrogen-
revolution-is-turning-blue; CarbonBrief, “In-depth Q&A: Does
the world need hydrogen to solve climate change?” 30 November
2020, https://www.carbonbrief.org/in-depth-qa-does-the-world-
need-hydrogen-to-solve-climate-change.
242 IRENA, op. cit. note 240; Energy Transitions Commission, Making
the Hydrogen Economy Possible: Accelerating Clean Hydrogen in
an Electrified Economy, April 2021, https://energy-transitions.org/
wp-content/uploads/2021/04/ETC-Global-Hydrogen-Report .
243 IRENA, op. cit. note 240; Wood Mackenzie, 2050: The Hydrogen
Possibility (2020), https://www.woodmac.com/our-expertise/
focus/transition/2050---the-hydrogen-possibility; CarbonBrief,
op. cit. note 241; IHS Markit, Top 10 Cleantech Trends in 2021
(London: 2021), p. 9, https://cdn.ihsmarkit.com/www/prot/
pdf/0221/IHS-MarkitTopCleanTechTrends2021-Whitepaper .
244 Australia, Chile, the EU, France, Germany, the Netherlands, Norway,
Portugal and Spain have hydrogen strategies with provisions to
support renewable hydrogen. Canada, Japan and the Republic of
Korea have hydrogen strategies that do not specifically support
renewable hydrogen. Italy, Finland, New Zealand, the Russian
Federation and others have published either an unofficial roadmap
or vision document for renewable hydrogen development. IRENA,
op. cit. note 241; Government of Canada, Hydrogen Strategy for
Canada (Ottawa: 2020), https://www.nrcan.gc.ca/sites/www.
nrcan.gc.ca/files/environment/hydrogen/NRCan_Hydrogen-
Strategy-Canada-na-en-v3 ; Ministerio para la Transición
Ecológica y el Reto Demográfico, “Una apuesta por el hidrógeno
renovable”, https://www.miteco.gob.es/es/ministerio/hoja-de-
ruta-del-hidrogeno-renovable.aspx, viewed 10 May 2021.
245 M. Burgess, “Portugal eyes a hydrogen-fuelled future”, Hydrogen
View, 8 April 2021, https://www.h2-view.com/story/portugal-
eyes-a-hydrogen-fuelled-future; Energy Iceberg, “China’s green
hydrogen effort in 2020: Gearing up for commercialization”,
7 October 2020, https://energyiceberg.com/china-renewable-
green-hydrogen; ETEnergyWorld, “National Hydrogen Mission:
Leapfrogging towards India’s cleaner future”, 16 February 2021,
https://energy.economictimes.indiatimes.com/news/renewable/
national-hydrogen-mission-leapfrogging-towards-indias-cleaner-
future/80991679.
246 IHS Markit, “Investment in green hydrogen production set
to exceed $1billion USD by 2023, according to IHS Markit”,
3 December 2020, https://news.ihsmarkit.com/prviewer/
release_only/slug/2020-12-03-investment-in-green-hydrogen-
production-set-to-exceed-1-billion-usd-by-2023.
247 G. Hering, “Air Liquide completes world’s largest green
hydrogen machine in Canada”, S&P Global, 26 January 2021,
361
https://www.renewableenergyworld.com/2020/09/23/in-a-first-tva-to-install-its-own-40-mwh-battery-storage-system
https://www.renewableenergyworld.com/2020/09/23/in-a-first-tva-to-install-its-own-40-mwh-battery-storage-system
https://www.renewableenergyworld.com/2020/09/23/in-a-first-tva-to-install-its-own-40-mwh-battery-storage-system
https://dailyenergyinsider.com/news/28269-southern-california-edison-contracts-four-projects-to-add-590-mw-of-battery-energy-storage
https://dailyenergyinsider.com/news/28269-southern-california-edison-contracts-four-projects-to-add-590-mw-of-battery-energy-storage
https://dailyenergyinsider.com/news/28269-southern-california-edison-contracts-four-projects-to-add-590-mw-of-battery-energy-storage
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ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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Shttps://www.spglobal.com/marketintelligence/en/news-insights/
latest-news-headlines/air-liquide-completes-world-s-largest-
green-hydrogen-machine-in-canada-62297835; L. Collins,
“World’s largest green-hydrogen plant inaugurated in Canada
by Air Liquide”, Recharge, 27 January 2021, https://www.
rechargenews.com/transition/worlds-largest-green-hydrogen-
plant-inaugurated-in-canada-by-air-liquide/2-1-952085; A.
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rechargenews.com/transition/japan-opens-worlds-largest-
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J. S. Hill, “Japan begins solar powered hydrogen production
at Fukushima plant”, RenewEconomy, 11 March 2020, https://
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production-at-fukushima-plant-89645.
248 L. Collins, “Growing ambition: The world’s 20 largest green-
hydrogen projects”, Recharge, 21 December 2020, https://www.
rechargenews.com/energy-transition/growing-ambition-the-
worlds-20-largest-green-hydrogen-projects/2-1-933755.
249 R. Nair, “Over 60 GW of green hydrogen projects in the pipeline
globally, says report”, Mercom India, 20 October 2020, https://
mercomindia.com/over-60-gw-green-hydrogen-projects.
250 J. S. Hill, “European consortium to deliver 95GW of solar and
67GW of hydrogen by 2030”, RenewEconomy, 16 February 2021,
https://reneweconomy.com.au/30-european-companies-form-
hydeal-ambition-project-to-deliver-95gw-of-solar-67gw-of-
hydrogen.
251 Asian Renewable Hub, https://asianrehub.com, viewed 10 May 2020.
252 Collins, op. cit. note 248; Asian Renewable Hub, op. cit. note 251.
253 A. Frangoul, “Green hydrogen project combining tidal power and
battery tech aims for continuous production”, CNBC, 10 November
2020, https://www.cnbc.com/2020/11/10/project-combining-
batteries-tidal-power-aims-for-hydrogen-production.html.
254 J. Spector, “So, what exactly is long-duration energy storage?”
Greentech Media, 26 October 2020, https://www.greentechmedia.com/
articles/read/so-what-exactly-is-long-duration-storage-explained.
255 Ibid.
256 IEA, op. cit. note 189.
257 Ibid.
258 BloombergNEF, op. cit. note 190.
259 S. Vorrath, “Solar flow battery breakthrough combines PV
generation and storage in one device”, RenewEconomy, 14
July 2020, https://reneweconomy.com.au/solar-flow-battery-
breakthrough-combines-pv-generation-and-storage-in-one-
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electronic-design-solidstate-batteries-advancing-toward-promise-
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260 J. Spector, “Long duration breakthrough? Form Energy’s first
project tries pushing storage to 150 hours”, Greentech Media,
7 May 2020, https://www.greentechmedia.com/articles/read/
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261 J. McMahon, “California sees zinc as likely successor to
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https://www.forbes.com/sites/jeffmcmahon/2020/10/06/
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form-energy-raises-another-70m-for-long-duration-storage.
262 Eos, “Eos raises millions from listing on Nasdaq, in rare battery
startup move to public markets”, https://eosenergystorage.com/
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263 O. Balch, “The curse of ‘white oil’: Electric vehicles’ dirty secret,
The Guardian (UK), 8 December 2020, https://www.theguardian.
com/news/2020/dec/08/the-curse-of-white-oil-electric-
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clean-electric-vehicles; C. Early, “The new ‘gold rush’ for green
lithium”, BBC, 24 November, https://www.bbc.com/future/
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extraction project to start in Germany”, 23 July 2020, https://
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lithium-extraction-project-to-start-in-germany.
264 World Bank, “New international partnership established to
increase the use of energy storage in developing countries”,
press release (Washington, DC: 28 May 2019), https://www.
worldbank.org/en/news/press-release/2019/05/28/new-
international-partnership-established-to-increase-the-use-of-
energy-storage-in-developing-countries; World Bank, “Batteries
can help renewables reach full potential in Africa”, 28 February
2019, https://www.worldbank.org/en/news/feature/2019/02/28/
batteries-can-help-renewables-reach-full-potential-in-africa.
265 Ibid., both references.
266 World Bank, “New international partnership”, op. cit. note 264;
World Bank, Warranties for Battery Energy Storage Systems in
Developing Countries (Washington, DC: 2020), http://documents1.
worldbank.org/curated/en/339531600374280939/pdf/Warranties-
for-Battery-Energy-Storage-Systems-in-Developing-Countries .
267 “UK solar developers deploy storage to capture
peak returns”, Reuters, 2 September 2020, https://
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uk-solar-developers-deploy-storage-capture-peak-returns.
268 Ibid.
269 IRENA, op. cit. note 232.
270 J. Spector, “The 5 most promising long-duration storage
technologies left standing”, Greentech Media, 31 March 2020,
https://www.greentechmedia.com/articles/read/most-promising-
long-duration-storage-technologies-left-standing.
271 IRENA, op. cit. note 232, p. 74; National Energy Technology
Laboratory, “NETL explores concrete solutions to store thermal
energy”, https://www.netl.doe.gov/node/9624, viewed 20 March
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concrete thermal storage plant”, Reuters, 3 July 2019, https://www.
reutersevents.com/renewables/csp-today/china-buys-49-acwa-
power-renewables-us-build-concrete-thermal-storage-plant.
272 Malta Inc., “Malta raises $50M to commercialize its long duration
energy storage system”, 24 February 2021, https://www.maltainc.
com/malta-raises-50-million.
273 Wood Mackenzie, op. cit. note 243; H. Shukla, “Daily news
wrap-up: Siemens and WUN H2 to build a CO2 free hydrogen
production facility”, Mercom India, 30 September 2020, https://
mercomindia.com/daily-news-wrap-up-siemens-wun-h2.
274 J. Deign, “Coalition aims for 25GW of green hydrogen
by 2026”, Greentech Media, 8 December 2020,
https://www.greentechmedia.com/articles/read/
coalition-aims-for-25-gw-of-green-hydrogen-by-2026.
275 US DOE, OEERE, “Collaboration between the United States
and the Netherlands focuses on hydrogen technology”,
6 October 2020, https://www.energy.gov/eere/articles/
collaboration-between-united-states-and-netherlands-
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and Portugal strengthen their ties for green hydrogen
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Africa gains momentum”, ESI Africa, 9 September 2020, https://
www.esi-africa.com/industry-sectors/renewable-energy/
exploring-hydrogen-resources-in-africa-gains-momentum.
276 IEA, Clean Energy Ministerial Hydrogen Initiative, https://
www.iea.org/programmes/cem-hydrogen-initiative. Current 21
participating countries: Australia, Austria, Brazil, Canada, Chile,
China, Costa Rica, the EU, Finland, Germany, India, Italy, Japan,
the Netherlands, New Zealand, Norway, Saudi Arabia, South
Africa, the Republic of Korea, the United Kingdom and the United
States.
362
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https://eosenergystorage.com/eos-raises-millions-from-listing-on-nasdaq-in-rare-battery-startup-move-to-public-markets
https://eosenergystorage.com/eos-raises-millions-from-listing-on-nasdaq-in-rare-battery-startup-move-to-public-markets
https://eosenergystorage.com/eos-raises-millions-from-listing-on-nasdaq-in-rare-battery-startup-move-to-public-markets
https://www.theguardian.com/news/2020/dec/08/the-curse-of-white-oil-electric-vehicles-dirty-secret-lithium
https://www.theguardian.com/news/2020/dec/08/the-curse-of-white-oil-electric-vehicles-dirty-secret-lithium
https://www.theguardian.com/news/2020/dec/08/the-curse-of-white-oil-electric-vehicles-dirty-secret-lithium
https://www.forbes.com/sites/tilakdoshi/2020/08/02/the-dirty-secrets-of-clean-electric-vehicles
https://www.forbes.com/sites/tilakdoshi/2020/08/02/the-dirty-secrets-of-clean-electric-vehicles
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https://www.bbc.com/future/article/20201124-how-geothermal-lithium-could-revolutionise-green-energy
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https://www.sonnenseite.com/en/science/worldas-first-zero-carbon-lithium-extraction-project-to-start-in-germany
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https://www.worldbank.org/en/news/press-release/2019/05/28/new-international-partnership-established-to-increase-the-use-of-energy-storage-in-developing-countries
https://www.worldbank.org/en/news/press-release/2019/05/28/new-international-partnership-established-to-increase-the-use-of-energy-storage-in-developing-countries
https://www.worldbank.org/en/news/feature/2019/02/28/batteries-can-help-renewables-reach-full-potential-in-africa
https://www.worldbank.org/en/news/feature/2019/02/28/batteries-can-help-renewables-reach-full-potential-in-africa
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http://documents1.worldbank.org/curated/en/339531600374280939/pdf/Warranties-for-Battery-Energy-Storage-Systems-in-Developing-Countries
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https://www.reutersevents.com/renewables/solar/uk-solar-developers-deploy-storage-capture-peak-returns
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https://www.greentechmedia.com/articles/read/most-promising-long-duration-storage-technologies-left-standing
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https://www.netl.doe.gov/node/9624
https://www.reutersevents.com/renewables/csp-today/china-buys-49-acwa-power-renewables-us-build-concrete-thermal-storage-plant
https://www.reutersevents.com/renewables/csp-today/china-buys-49-acwa-power-renewables-us-build-concrete-thermal-storage-plant
https://www.reutersevents.com/renewables/csp-today/china-buys-49-acwa-power-renewables-us-build-concrete-thermal-storage-plant
https://www.maltainc.com/malta-raises-50-million
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https://mercomindia.com/daily-news-wrap-up-siemens-wun-h2
https://mercomindia.com/daily-news-wrap-up-siemens-wun-h2
https://www.greentechmedia.com/articles/read/coalition-aims-for-25-gw-of-green-hydrogen-by-2026
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https://www.energy.gov/eere/articles/collaboration-between-united-states-and-netherlands-focuses-hydrogen-technology
https://www.energy.gov/eere/articles/collaboration-between-united-states-and-netherlands-focuses-hydrogen-technology
https://www.energy.gov/eere/articles/collaboration-between-united-states-and-netherlands-focuses-hydrogen-technology
https://www.energylivenews.com/2020/09/24/netherlands-and-portugal-strengthen-their-ties-for-green-hydrogen-transportation
https://www.energylivenews.com/2020/09/24/netherlands-and-portugal-strengthen-their-ties-for-green-hydrogen-transportation
https://www.energylivenews.com/2020/09/24/netherlands-and-portugal-strengthen-their-ties-for-green-hydrogen-transportation
https://www.esi-africa.com/industry-sectors/renewable-energy/exploring-hydrogen-resources-in-africa-gains-momentum
https://www.esi-africa.com/industry-sectors/renewable-energy/exploring-hydrogen-resources-in-africa-gains-momentum
https://www.esi-africa.com/industry-sectors/renewable-energy/exploring-hydrogen-resources-in-africa-gains-momentum
https://www.iea.org/programmes/cem-hydrogen-initiative
https://www.iea.org/programmes/cem-hydrogen-initiative
ENDNOTES · ENERGY SYSTEMS INTEGRATION AND ENABLING TECHNOLOGIES 06
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S277 IHS Markit, op. cit. note 243.
278 Energy Transitions Commission, op. cit. note 242, p. 27.
279 F. Schulz, “Germany plans to promote ‘green’ hydrogen with
€7 billion”, EURACTIV, 11 June 2020, https://www.euractiv.
com/section/energy/news/germany-plans-to-promote-
green-hydrogen-with-e7-billion; S. Goncalves, “Portugal
selects multi-billion post-coronavirus hydrogen projects”,
Reuters, 28 July 2020, https://www.reuters.com/article/
us-portugal-energy-hydrogen/portugal-selects-multi-billion-
post-coronavirus-hydrogen-projects-idUSKCN24T1S5;
J. Stones, “French government announces support for
hydrogen projects”, ICIS, 23 October 2020, https://www.
icis.com/explore/resources/news/2020/10/23/10566918/
french-government-announces-support-for-hydrogen-projects.
280 “European energy giants partner on Portugal green hydrogen
project”, Power Engineering International, 10 August 2020, https://
www.powerengineeringint.com/renewables/european-energy-
giants-partner-on-h2sines-green-hydrogen-production-project;
S. Djunisic, “Portugal-led partnership to assess viability of 1-GW
green hydrogen cluster”, Renewables Now, 30 July 2020, https://
www.renewablesnow.com/news/portugal-led-partnership-to-
assess-viability-of-1-gw-green-hydrogen-cluster-708266.
281 J. Parnell, “2020: The year of green hydrogen in
10 stories”, Greentech Media, 29 December 2020,
https://www.greentechmedia.com/articles/
read/2020-the-year-of-green-hydrogen-in-10-stories.
282 Schulz, op. cit. note 279; SolarPower Europe, newsletter, 5 June
2020, https://www.solarpowereurope.org/solarpower-europe-
newsletter-4.
283 X. Yihe, “Sinopec to shift gears from grey to green hydrogen”,
Upstream Online, 12 March 2021, https://www.upstreamonline.
com/energy-transition/sinopec-to-shift-gears-from-grey-to-
green-hydrogen/2-1-975983; Argus Media, “China’s Sinopec
outlines hydrogen aspirations”, 24 February 2021, https://www.
argusmedia.com/en/news/2189848-chinas-sinopec-outlines-
hydrogen-aspirations; L. Moffitt, “China’s Sinopec, Longi team
up for green hydrogen”, Argus Media, 16 April 2021, https://www.
argusmedia.com/en/news/2205975-chinas-sinopec-longi-team-
up-for-green-hydrogen; D. Murtaugh, “World’s biggest solar
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world-s-biggest-solar-company-joins-the-hydrogen-game.
284 J. St. John, “Plug Power raises $1B for US green hydrogen
infrastructure build-out”, Greentech Media, 24 November 2020,
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raises-1b-for-u.s-green-hydrogen-infrastructure-buildout.
285 J. St. John, “Xcel targets $1.4B in wind and solar investments,
outlines broader carbon-reduction goals”, Greentech Media, 30
October 2020, https://www.greentechmedia.com/articles/read/
xcel-targets-1.4b-in-wind-solar-investments-outlines-broader-
carbon-reduction-goals.
363
https://www.euractiv.com/section/energy/news/germany-plans-to-promote-green-hydrogen-with-e7-billion
https://www.euractiv.com/section/energy/news/germany-plans-to-promote-green-hydrogen-with-e7-billion
https://www.euractiv.com/section/energy/news/germany-plans-to-promote-green-hydrogen-with-e7-billion
https://www.reuters.com/article/us-portugal-energy-hydrogen/portugal-selects-multi-billion-post-coronavirus-hydrogen-projects-idUSKCN24T1S5
https://www.reuters.com/article/us-portugal-energy-hydrogen/portugal-selects-multi-billion-post-coronavirus-hydrogen-projects-idUSKCN24T1S5
https://www.reuters.com/article/us-portugal-energy-hydrogen/portugal-selects-multi-billion-post-coronavirus-hydrogen-projects-idUSKCN24T1S5
https://www.icis.com/explore/resources/news/2020/10/23/10566918/french-government-announces-support-for-hydrogen-projects
https://www.icis.com/explore/resources/news/2020/10/23/10566918/french-government-announces-support-for-hydrogen-projects
https://www.icis.com/explore/resources/news/2020/10/23/10566918/french-government-announces-support-for-hydrogen-projects
https://www.powerengineeringint.com/renewables/european-energy-giants-partner-on-h2sines-green-hydrogen-production-project
https://www.powerengineeringint.com/renewables/european-energy-giants-partner-on-h2sines-green-hydrogen-production-project
https://www.powerengineeringint.com/renewables/european-energy-giants-partner-on-h2sines-green-hydrogen-production-project
https://www.renewablesnow.com/news/portugal-led-partnership-to-assess-viability-of-1-gw-green-hydrogen-cluster-708266
https://www.renewablesnow.com/news/portugal-led-partnership-to-assess-viability-of-1-gw-green-hydrogen-cluster-708266
https://www.renewablesnow.com/news/portugal-led-partnership-to-assess-viability-of-1-gw-green-hydrogen-cluster-708266
https://www.greentechmedia.com/articles/read/2020-the-year-of-green-hydrogen-in-10-stories
https://www.greentechmedia.com/articles/read/2020-the-year-of-green-hydrogen-in-10-stories
https://www.solarpowereurope.org/solarpower-europe-newsletter-4
https://www.solarpowereurope.org/solarpower-europe-newsletter-4
https://www.upstreamonline.com/energy-transition/sinopec-to-shift-gears-from-grey-to-green-hydrogen/2-1-975983
https://www.upstreamonline.com/energy-transition/sinopec-to-shift-gears-from-grey-to-green-hydrogen/2-1-975983
https://www.upstreamonline.com/energy-transition/sinopec-to-shift-gears-from-grey-to-green-hydrogen/2-1-975983
https://www.argusmedia.com/en/news/2189848-chinas-sinopec-outlines-hydrogen-aspirations
https://www.argusmedia.com/en/news/2189848-chinas-sinopec-outlines-hydrogen-aspirations
https://www.argusmedia.com/en/news/2189848-chinas-sinopec-outlines-hydrogen-aspirations
https://www.argusmedia.com/en/news/2205975-chinas-sinopec-longi-team-up-for-green-hydrogen
https://www.argusmedia.com/en/news/2205975-chinas-sinopec-longi-team-up-for-green-hydrogen
https://www.argusmedia.com/en/news/2205975-chinas-sinopec-longi-team-up-for-green-hydrogen
https://www.bloomberg.com/news/articles/2021-04-05/world-s-biggest-solar-company-joins-the-hydrogen-game
https://www.bloomberg.com/news/articles/2021-04-05/world-s-biggest-solar-company-joins-the-hydrogen-game
https://www.greentechmedia.com/articles/read/plug-power-raises-1b-for-u.s-green-hydrogen-infrastructure-buildout
https://www.greentechmedia.com/articles/read/plug-power-raises-1b-for-u.s-green-hydrogen-infrastructure-buildout
https://www.greentechmedia.com/articles/read/xcel-targets-1.4b-in-wind-solar-investments-outlines-broader-carbon-reduction-goals
https://www.greentechmedia.com/articles/read/xcel-targets-1.4b-in-wind-solar-investments-outlines-broader-carbon-reduction-goals
https://www.greentechmedia.com/articles/read/xcel-targets-1.4b-in-wind-solar-investments-outlines-broader-carbon-reduction-goals
ENDNOTES · ENERGY EFFICIENCY, RENEWABLES AND DECARBONISATION 07
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NENERGY EFFICIENCY, RENEWABLES AND DECARBONISATION
1 United Nations Environment Programme (UNEP), “Why does
energy matter?” https://www.unenvironment.org/explore-
topics/energy/why-does-energy-matter, viewed 30 January
2021; International Energy Agency (IEA), Global Energy & CO2
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global-energy-co2-status-report-2019/emissions#abstract.
2 Of the NDC data analysed, 105 of the commitments were
accessed from United Nations Framework Convention on
Climate Change, “NDC Registry”, https://www4.unfccc.int/sites/
NDCStaging/Pages/Search.aspx, viewed February 2020. The
remaining data were retrieved from International Renewable
Energy Agency (IRENA), “Renewable energy in the NDCs”,
https://www.irena.org/Statistics/View-Data-by-Topic/Climate-
Change/Renewable-Energy-in-the-NDCs, viewed February 2020.
3 See Box 2 in Energy Efficiency chapter in Renewable Energy
Network for the 21st Century (REN21), Renewables 2020 Global
Status Report (Paris: 2020), https://www.ren21.net/gsr-2020.
4 IEA, Energy Efficiency 2020 (Paris: 2020), https://www.iea.org/
reports/energy-efficiency-2020.
5 IEA, “Decoupling of global emissions and economic growth
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growth-confirmed.
6 Based on IEA, World Energy Statistics database, 2020, www.iea.
org/statistics (all rights reserved; as modified by REN21), and on
M. Fischedick et al., “Industry”, in O. Edenhofer et al., eds., Climate
Change 2014: Mitigation of Climate Change. Contribution of Working
Group III to the Fifth Assessment Report of the Intergovernmental
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7 G. P. Peters et al., “Key indicators to track current progress and
future ambition of the Paris Agreement”, Nature Climate Change,
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8 For more on the combined impact of energy efficiency and
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9 Sidebar 7 from the following sources: IEA, op. cit. note 4; IEA,
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www.iea.org/reports/global-energy-review-2020/electricity;
IEA, Energy Efficiency 2020 (Paris: 2020), https://www.iea.org/
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S. Watson, “Moving forward with sustainable mobility in the post-
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10 Institut du Développement et des Relations Internationales
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decarbonisation in the EU: Which indicators, why and what
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11 Based on IEA, op. cit. note 6; European Commission Joint
Research Centre (EU JRC), EDGAR v5.0 Global Greenhouse Gas
Emissions, https://data.jrc.ec.europa.eu/collection/edgar, viewed
December 2020; M. Crippa et al., Fossil CO2 and GHG Emissions
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12 IEA, op. cit. note 6; EU JRC, op. cit. note 11; World Bank, “GDP,
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13 EU JRC, op. cit. note 11; World Bank, op. cit. note 12.
14 IEA, op. cit. note 4. Figure 57 from the following sources: IEA,
op. cit. note 6; EU JRC, op. cit. note 11; World Bank, op. cit. note 12.
15 IEA op. cit. note 4.
16 Based on IEA, op. cit. note 6.
17 Ibid.
18 EU JRC, op. cit. note 11.
19 Ibid.
20 Based on IEA, op. cit. note 6.
21 Figure 58 based on IEA, op. cit. note 6; IEA, Energy Transitions
Indicators (Paris: December 2019), https://www.iea.org/reports/
energy-transitions-indicators.
22 Ibid., both references.
23 Ibid.
24 Ibid.
25 IDDRI, op. cit. note 10; IEA, World Energy Statistics and
Balances, 2020 edition (Paris: 2020); EU JRC, op. cit. note 11.
Sidebar 8 based on the following sources: World Bank Group,
Regulatory Indicators for Sustainable Energy: Sustaining the
Momentum (Washington, DC: 2020), https://rise.esmap.org/
data/files/reports/2020-full-report/RiseReport-010421 ;
African Development Bank and World Bank, “Benchmarking
the quality of electricity regulation”, 2020, https://africa-
energy-portal.org/reports/electricity-regulatory-index-2020;
V. Foster and A. Rana, Rethinking Power Sector Reform in
the Developing World (World Bank: Washington, DC: 2020);
International Carbon Action Partnership, “China National
ETS”, https://icapcarbonaction.com/en/?option=com_
etsmap&task=export&format=pdf&layout=list&systems%
5B%5D=55, updated 12 April 2021. Figure 59 from World Bank
Group, op. cit. this note.
26 Based on IEA, op. cit. note 6.
27 Ibid.
28 IEA, Tracking Buildings 2020 (Paris: 2020), https://www.iea.org/
reports/tracking-buildings-2020.
29 Ibid.
30 Ibid.
31 IRENA, IEA and REN21, Renewable Energy Policies in a Time of
Transition: Heating and Cooling (Abu Dhabi and Paris: 2020),
https://www.ren21.net/wp-content/uploads/2019/05/IRENA_
IEA_REN21-Policies_HC_2020_Full_Report ; J. Gerdes,
“So, what exactly is building electrification?” Greentech Media,
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32 Ibid.
33 Energy Saver, “Heat pump systems”, https://www.energy.gov/energy
saver/heat-and-cool/heat-pump-systems, viewed December 2020.
34 IEA, op. cit. note 28; IEA, The Critical Role of Buildings (Paris: 2019),
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35 IEA, “Buildings”, https://www.iea.org/topics/buildings, viewed
December 2020; REN21, Renewables Global Status Report
2019 (Paris: 2019), https://www.ren21.net/gsr-2019; IEA, op. cit.
note 28; IEA, The Critical Role of Buildings, op. cit. note 34; IEA,
op. cit. note 6; Global Alliance for Buildings and Construction
(GlobalABC), 2020 Global Status Report for Buildings and
Construction: Towards a Zero-emissions, Efficient and Resilient
Buildings and Construction Sector (Nairobi: UNEP, 2020),
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Buildings%20GSR_FULL%20REPORT .
36 IEA, World Energy Outlook 2019 (Paris: 2019), https://www.iea.
org/reports/world-energy-outlook-2019/electricity.
37 Based on IEA, Energy Efficiency Indicators database (2020
edition), extended version (Paris: 2020), https://www.iea.org/
reports/energy-efficiency-indicators.
38 Programme for Energy Efficiency in Buildings, Smart and Efficient:
Digital Solutions to Save Energy in Buildings (Paris: 2019), https://
www.peeb.build//imglib/downloads/PEEB_DigitalSolutions_web .
364
https://www.unenvironment.org/explore-topics/energy/why-does-energy-matter
https://www.unenvironment.org/explore-topics/energy/why-does-energy-matter
https://www.iea.org/reports/global-energy-co2-status-report-2019/emissions#abstract
https://www.iea.org/reports/global-energy-co2-status-report-2019/emissions#abstract
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https://www.irena.org/Statistics/View-Data-by-Topic/Climate-Change/Renewable-Energy-in-the-NDCs
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https://www.ren21.net/gsr-2020
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ENDNOTES · ENERGY EFFICIENCY, RENEWABLES AND DECARBONISATION 07
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N39 GlobalABC, op. cit. note 35; Deepki, “Real estate”, https://www.
deepki.com/en/secteurs/real-estate, viewed November 2020;
Energisme, https://energisme.com/en, viewed November 2020.
40 GlobalABC, op. cit. note 35.
41 Considering several commercial building types, including offices,
retail, hotels and hospitals, the American Council for an Energy-
Efficient Economy concluded that smart technologies can reduce
a building’s energy use nearly 20%, from Ingram Micro Inc.,
“IOT Power Innovations for Smart Buildings” (Irvine, CA: 2019),
https://img.en25.com/Web/PentoniNET/%7Bc90d9525-354b-
4906-ba74-1cdd293183c5%7D_A2020706-Ingram_Micro_IoT_
Primer_-_IoT_Powers_Innovations_for_Smart_Buildings .
42 CBRE, “Smart homes”, https://www.cbre.co.jp/es-es/united%20
kingdom/research-and-reports/our-cities/smart-homes, viewed
January 2021.
43 Buildings Performance Institute Europe (BPIE), A Guidebook to
European Building Policy: Key Legislation and Initiatives (Brussels:
2020), https://www.bpie.eu/publication/a-guidebook-to-
european-building-policy-key-legislation-and-initiatives.
44 EU Building Stock Observatory, “Fact sheet: Nearly zero-energy
buildings”, https://ec.europa.eu/energy/eu-buildings-factsheets_
en, viewed 9 December 2020.
45 Ibid.
46 Team Zero, Zero Energy Residential Buildings Study (2020), https:
//drive.google.com/file/d/1TC2NAUr1slFkVi_PZF6QKOw2KKN
plTAD/view.
47 Energy Efficiency chapter in REN21, op. cit. note 3.
48 B. Lebot, Senior Policy Advisor, Ministère de la Transition
Ecologique et Solidaire, Paris, personal communication with
REN21, 16 November 2020.
49 BPIE, op. cit. note 43.
50 Based on IEA, op. cit. note 37.
51 Ibid.
52 BPIE, op. cit. note 43.
53 Energiesprong, “About”, https://energiesprong.org/about,
viewed 9 December 2020; “Efforts to make buildings
greener are not working”, The Economist, 3 January 2019,
https://amp.economist.com/international/2019/01/05/
efforts-to-make-buildings-greener-are-not-working.
54 Ibid., both references.
55 Based on IEA, op. cit. note 6; EU JRC, op. cit. note 11.
56 EU JRC, op. cit. note 11.
57 Figure 60 based on IEA, op. cit. note 6, and on Fischedick et al.,
op. cit. note 6.
58 O. Roelofsen et al., “Plugging in: What electrification can do
for industry”, McKinsey, 28 May 2020, https://www.mckinsey.
com/industries/electric-power-and-natural-gas/our-insights/
plugging-in-what-electrification-can-do-for-industry.
59 Ibid.
60 S. Porter et al., “Electrification in industrials: Transitioning
to a lower-carbon future through electrification of industrial
processes, spaces, and fleets”, Deloitte, 12 August 2020, https://
www2.deloitte.com/us/en/insights/industry/power-and-utilities/
electrification-in-industrials.html; Roelofsen et al., op. cit. note 58;
D. Schüwer and C. Schneider, “Electrification of industrial process
heat: Long-term applications, potentials and impacts”, ECEEE
Industrial Summer Study Proceedings, 2018, https://www.eceee.
org/library/conference_proceedings/eceee_Industrial_Summer_
Study/2018/4-technology-products-and-system-optimisation/
electrification-of-industrial-process-heat-long-term-applications-
potentials-and-impacts/2018/4-051-18_Schuewer .
61 US Department of Energy, Office of Energy Efficiency and
Renewable Energy, Industrial Heat Pumps for Steam and Fuel
Savings (Washington, DC: 2014), https://www.energy.gov/sites/
prod/files/2014/05/f15/heatpump .
62 Ibid.
63 J. Ling-Chin et al., “State-of-the-art technologies on low-
grade heat recovery and utilization in industry”, in Ibrahim H.
Al-Bahadly, ed., Energy Conversion: Current Technologies and
Future Trends (IntechOpen, 2019), https://www.intechopen.com/
books/energy-conversion-current-technologies-and-future-trends/
state-of-the-art-technologies-on-low-grade-heat-recovery-and-
utilization-in-industry.
64 European Heat Pump Association, “Large heat pump booklet: 4
new stories strengthen the argument that heat pumps are fit for
purpose for the industry”, 4 December 2019, https://www.ehpa.
org/about/news/article/large-heat-pump-booklet-4-new-stories-
strengthen-the-argument-that-heat-pumps-are-fit-for-purpose-f.
65 IEA Solar Heating and Cooling Programme (SHC), Solar
Heat Integrations in Industrial Processes, Technology Position
Paper (Paris: 2020), https://task49.iea-shc.org/Data/Sites/1/
publications/IEA-SHC-Technology-Position-Paper--Solar-
Heat-Integrations-Industrial-Processes--May2020 ; United
Nations Industrial Development Organization (UNIDO),
“Efficiency Solutions for Industrial Heat: Energy Efficiency
Solutions Series”, brochure (Geneva: 2020), https://www.
industrialenergyaccelerator.org/wp-content/uploads/Corrected-
SSO_brochure_3-DIC .
66 IEA SHC, Solar Heat Worldwide, Edition 2020 (Paris: 2020),
https://www.iea-shc.org/Data/Sites/1/publications/Solar-Heat-
Worldwide-2020 .
67 i-SCOOP, “Industry 4.0”, https://www.i-scoop.eu/industry-4-0/
energy-efficiency-industry-4-0, viewed December 2020.
68 UNIDO, “Energy Management System (EnMS): Energy
Efficiency Solutions Series”, brochure (Geneva: 2020), https://
www.industrialenergyaccelerator.org/wp-content/uploads/
EnMS_brochure-1 .
69 Ibid.; R. Ghoneim, “Opinion: Industrial energy efficiency is the
invisible climate solution”, Devex, 25 September 2019, https://
www.devex.com/news/opinion-industrial-energy-efficiency-is-
the-invisible-climate-solution-95681.
70 Based on IEA, op. cit. note 6.
71 Based on Ibid.
72 Based on Ibid.; EU JRC, op. cit. note 11.
73 EU JRC, op. cit. note 11.
74 IEA, Energy Efficiency 2018: Analysis and Outlook to 2040 (Paris:
2018), https://www.iea.org/efficiency2018.
75 L. Cozzi and A. Petropoulos, “Carbon emissions fell across all
sectors in 2020 except for one – SUVs”, IEA, 15 January 2021,
https://www.iea.org/commentaries/carbon-emissions-fell-
across-all-sectors-in-2020-except-for-one-suvs.
76 Ibid.
77 Figure 61 based on IEA, op. cit. note 37, for a selection of
countries. Calculation includes an extrapolation based on
historical compound annual average growth rates of carbon
intensity and/or kilometres travelled in 2018 for Austria, Belgium,
Canada, the Czech Republic, Denmark, Greece, the Netherlands,
the Slovak Republic and Spain.
78 International Council on Clean Transportation, 2017 Global
Update Light-Duty Vehicle Greenhouse Gas and Fuel Economy
Standards (Washington, DC: 2017), https://theicct.org/
publications/2017-global-update-LDV-GHG-FE-standards.
79 Ibid.
80 Ibid.
81 IEA, Fuel Consumption of Cars and Vans (Paris: 2020), https://
www.iea.org/reports/fuel-consumption-of-cars-and-vans.
82 UNEP, Used Vehicles and the Environment Global Overview of
Used Light Vehicles – Flow, Scale and Regulation (Nairobi: 2020),
https://wedocs.unep.org/bitstream/handle/20.500.11822/34298/
KFUVE .
83 Ibid. Note that while bans prevent polluting used vehicles from
circulating in importing countries, they can also reduce access to
affordable advanced vehicles, especially where new vehicles are
imported or produced under weak vehicle standards and policy
regulations. Many countries block the import of used vehicles not
(only) for environment and safety reasons, but also to protect their
own manufacturing industry.
84 Ibid.
85 Ibid.
86 US Department of Energy, “All-electric vehicles”, https://www.
fueleconomy.gov/feg/evtech.shtml, viewed February 2021.
87 European Commission, “Powering a climate-neutral economy:
An EU Strategy for Energy System Integration” (Brussels: 8 July
2020), p. 5, https://eur-lex.europa.eu/legal-content/EN/TXT/PDF.
88 European Environment Agency, “Range of life-cycle CO2 emissions
for different vehicle and fuel types”, 2017, https://www.eea.europa.
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ENDNOTES · ENERGY EFFICIENCY, RENEWABLES AND DECARBONISATION 07
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89 SLOCAT, “E-mobility trends and targets”, https://slocat.
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90 Based on IEA, op. cit. note 6.
91 Organisation for Economic Co-operation and Development
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93 IEA, Energy Efficiency 2020, Urban Transport (Paris: 2020),
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94 IEA, op. cit. note 9; D. Crow and A. Millot, “Working from home
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https://www.transportenvironment.org/sites/te/files/T%26E%E2%80%99s%20EV%20life%20cycle%20analysis%20LCA
https://www.transportenvironment.org/sites/te/files/T%26E%E2%80%99s%20EV%20life%20cycle%20analysis%20LCA
https://slocat.net/e-mobility
https://slocat.net/e-mobility
https://www.iea.org/reports/global-ev-outlook-2020
https://www.iea.org/reports/global-ev-outlook-2020
http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=ENV/EPOC/WPIEEP(2020)6/FINAL&docLanguage=En
http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=ENV/EPOC/WPIEEP(2020)6/FINAL&docLanguage=En
http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=ENV/EPOC/WPIEEP(2020)6/FINAL&docLanguage=En
https://www.greenbiz.com/article/are-shared-e-scooters-good-planet-only-if-they-replace-car-trips
https://www.greenbiz.com/article/are-shared-e-scooters-good-planet-only-if-they-replace-car-trips
https://www.greenbiz.com/article/are-shared-e-scooters-good-planet-only-if-they-replace-car-trips
https://www.fleeteurope.com/en/last-mile/europe/features/do-scooters-replace-cars
https://www.fleeteurope.com/en/last-mile/europe/features/do-scooters-replace-cars
https://www.iea.org/reports/energy-efficiency-2020/urban-transport#abstract
https://www.iea.org/reports/energy-efficiency-2020/urban-transport#abstract
https://www.iea.org/commentaries/working-from-home-can-save-energy-and-reduce-emissions-but-how-much
https://www.iea.org/commentaries/working-from-home-can-save-energy-and-reduce-emissions-but-how-much
ENDNOTES · FE ATURE: BUSINESS DEMAND FOR RENEWABLES 08
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1 BloombergNEF, “Corporate clean energy buying grew 18% in
2020, despite mountain of adversity”, 26 January 2021, https://
about.bnef.com/blog/corporate-clean-energy-buying-grew-18-
in-2020-despite-mountain-of-adversity.
2 Ibid.
3 See “Corporate sourcing of renewable energy” chapter in
Renewable Energy Network for the 21st Century (REN21),
Renewables 2018 Global Status Report (Paris: 2018),
https://www.ren21.net/gsr-2018.
4 H. Kopnina and J. Blewitt, Sustainable Business (London:
Routledge, 2018); P. McAteer, Sustainability Is the New Advantage:
Leadership, Change, and the Future of Business (London: Anthem
Press, 2019); S. Ponte, Business, Power and Sustainability in a
World of Global Value Chains (London: Zed Books, 2019).
5 M. Coppola et al., “Feeling the heat? Companies are under
pressure on climate change and need to do more”, Deloitte, 12
December 2019, https://www2.deloitte.com/us/en/insights/
topics/strategy/impact-and-opportunities-of-climate-change-on-
business.html.
6 Global Reporting Initiative, “GRI Standards”, https://www.
globalreporting.org/how-to-use-the-gri-standards/gri-
standards-english-language, viewed 15 May 2021; CDP, “How
100% renewable electricity is fast becoming the new normal”,
21 January 2018, https://www.cdp.net/en/articles/companies/
how-100-renewable-electricity-is-fast-becoming-the-new-normal.
7 BloombergNEF, op. cit. note 1; BloombergNEF, 2021 Energy
Transition Investment Trends (London: 2021), https://about.bnef.
com/energy-transition-investment, based on WilderHill New
Energy Global Innovation Index data for clean energy firms and
the NYSE Arca Oil Index for oil company data.
8 International Renewable Energy Agency (IRENA), Renewable
Energy Generation Costs in 2020 (Abu Dhabi: forthcoming 2021).
9 Solar Power Europe, “Global market outlook 2019-2023”, 10 May 2019,
https://www.solarpowereurope.org/global-market-outlook-2019-2023.
10 BloombergNEF, BNEF Executive Factbook 2020 (London: 22 April
2020), https://data.bloomberglp.com/promo/sites/12/678001-
BNEF_2020-04-22-ExecutiveFactbook .
11 RE-Source, “Risk mitigation for corporate renewable PPAs”,
March 2020, https://resource-platform.eu/wp-content/uploads/
files/statements/RE-Source%203 .
12 For example, company sustainability reporting frameworks such
as the Global Reporting Initiative and CDP are used for this and
other purposes. Deloitte, “Clarity in financial reporting”, February
2020, https://www2.deloitte.com/content/dam/Deloitte/au/
Documents/audit/deloitte-au-audit-clarity-disclosure-climate-
related-risks-070220 .
13 Current members from RE100, “RE100 members”, https://www.
there100.org/re100-members, viewed 6 May 2020; 2019 members
from RE100, idem, viewed 20 May 2019.
14 EV100, “EV100 members”, https://www.theclimategroup.org/
ev100-members, viewed 20 March 2021.
15 Many companies also have made commitments to support wider
international and global efforts on climate action, such as the Paris
Pledge (COP21 Paris Agreement), the United Nations (UN) Global
Compact and the UN Sustainable Development Goals (especially
SDG 7 on clean energy, SDG 12 on responsible consumption
and production, and SDG 13 on climate action)). Box 9 from
the following sources: Renewable Energy Buyers Alliance, “Our
vision”, https://rebuyers.org/about/vision, viewed 28 April 2021;
RE-Source, “About us”, https://resource-platform.eu/about-us,
viewed 28 April 2021; Renewable Thermal Collaborative, “About us”,
https://www.renewablethermal.org/about-us, viewed 28 April 2021;
Renewable Thermal Collaborative, “Our strategy”, https://www.
renewablethermal.org/our-strategy, viewed 6 May 2021; We Mean
Business, “What we do”, https://www.wemeanbusinesscoalition.
org/about, viewed 28 April 2021; Mission Possible Partnership,
“Action areas”, https://missionpossiblepartnership.org/action-
areas, viewed 6 May 2021; The Climate Group, “Energy”, https://
www.theclimategroup.org/energy, viewed 6 May 2021; The Climate
Group, “Transport”, https://www.theclimategroup.org/transport,
viewed 6 May 2021; The Climate Group, “Industry”, https://www.
theclimategroup.org/industry, viewed 6 May 2021; Renewable
Energy Institute, “Joint Initiatives”, https://www.renewable-ei.org/
en/joint_initiatives, viewed 6 May 2021.
16 See World Business Council for Sustainable Development
(WBCSD), “Guidelines for an integrated energy strategy:
Electricity”, https://wbcsdpublications.org/electricity, viewed 10
May 2021.
17 M. Bandyk, “Green tariffs drive big increases in corporate
renewable procurement”, Utility Dive, 13 March 2020, https://
www.utilitydive.com/news/green-tariffs-drive-big-increases-in-
corporate-renewable-procurement/574060; US Environmental
Protection Agency (EPA), “Utility green tariffs”, https://www.epa.
gov/greenpower/utility-green-tariffs, viewed 15 May 2021.
18 US EPA, “Unbundled Renewable Energy Certificates (RECs)”,
https://www.epa.gov/greenpower/unbundled-renewable-energy-
certificates-recs, viewed 15 May 2021.
19 Certificates are convenient to obtain, but there is a significant
degree of distance between the buyer and the renewable energy
provider. EACs are often an initial procurement choice for
companies, but firms can switch to more direct sourcing methods
as they become more accessible and attractive. Renewable
Energy Buyers Alliance, “Renewable energy procurement”,
https://rebuyers.org/programs/education-engagement/
renewable-energy-procurement, viewed 10 May 2021.
20 BloombergNEF, op. cit., note 1.
21 Ibid.
22 Ibid.
23 Ibid.
24 J. Bebon, “Corporate renewables purchases hit record 23.7 GW in
2020”, pv magazine, 27 January 2021, https://www.pv-magazine.com/
2021/01/27/corporate-renewables-purchases-hit-record-23-7-gw-
in-2020.
25 Figure 62 from BloombergNEF, op. cit. note 1; Bebon, op. cit. note 24.
26 DNV-GL, “2020’s hot topics in renewable energy procurement”,
www.dnvgl.com/article/2020-s-hot-topics-in-renewable-energy-
procurement-171046, viewed 10 May 2021.
27 Ibid.
28 M. Pariser, “The next step for corporate sustainability: 24/7/365
carbon-free energy matching”, Greentech Media, 3 September 2020,
https://www.greentechmedia.com/articles/read/transforming-
corporate-sustainability-with-24-7-365-carbon-free-energy-
matching; S. Lacey, “24/7 renewables: The emerging art of matching
renewables with demand”, Greentech Media, 5 February 2020,
https://www.greentechmedia.com/articles/read/24-7-renewables-
the-emerging-art-of-matching-renewables-with-demand.
29 LO3 Energy, “The quest for 24/7 renewable energy”, 27 March
2020, https://lo3energy.com/the-quest-for-24-7-renewable-energy.
30 Vattenfall, “Vattenfall to deliver renewable energy 24.7 to
Microsoft’s Swedish datacenters”, press release (Stockholm: 24
November 2020), https://group.vattenfall.com/press-and-media/
pressreleases/2020/vattenfall-to-deliver-renewable-energy-247-
to-microsofts-swedish-datacenters; Statkraft, “Statkraft receives
Daimler Supplier Award 2020 in the category Sustainability”, 12
February 2020,www.statkraft.com/newsroom/news-and-stories/
archive/2020/daimler-sustainability-award.
31 International Energy Agency (IEA), Tracking Report on Data Centres
and Data Transmission Networks (Paris: June 2020), https://www.
iea.org/reports/data-centres-and-data-transmission-networks.
32 A. Winston, G. Favaloro and T. Healy, “Energy strategy for the
C-Suite”, Harvard Business Review, January-February 2017,
https://hbr.org/2017/01/energy-strategy-for-the-c-suite.
33 A. Jasi, “Suppliers commit to achieving 100% renewable Apple
production”, The Chemical Engineer, 12 August 2020,
www.thechemicalengineer.com/news/suppliers-commit-to-
achieving-100-renewable-apple-production.
34 Walmart, “Walmart and Schneider Electric announce
groundbreaking collaboration to help suppliers access renewable
energy”, press release (Bentonville, AR: 10 September 2020),
https://corporate.walmart.com/newsroom/2020/09/10/walmart-
and-schneider-electric-announce-groundbreaking-collaboration-
to-help-suppliers-access-renewable-energy.
35 WBCSD, op. cit. note 16.
36 WBCSD, Cross-Border Renewable PPAs in Europe: An Overview
for Corporate Buyers (Geneva: December 2020), https://www.
wbcsd.org/contentwbc/download/10878/160801/1.
37 Ibid.
367
https://about.bnef.com/blog/corporate-clean-energy-buying-grew-18-in-2020-despite-mountain-of-adversity
https://about.bnef.com/blog/corporate-clean-energy-buying-grew-18-in-2020-despite-mountain-of-adversity
https://about.bnef.com/blog/corporate-clean-energy-buying-grew-18-in-2020-despite-mountain-of-adversity
https://www.ren21.net/gsr-2018
https://www2.deloitte.com/us/en/insights/topics/strategy/impact-and-opportunities-of-climate-change-on-business.html
https://www2.deloitte.com/us/en/insights/topics/strategy/impact-and-opportunities-of-climate-change-on-business.html
https://www2.deloitte.com/us/en/insights/topics/strategy/impact-and-opportunities-of-climate-change-on-business.html
https://www.globalreporting.org/how-to-use-the-gri-standards/gri-standards-english-language
https://www.globalreporting.org/how-to-use-the-gri-standards/gri-standards-english-language
https://www.globalreporting.org/how-to-use-the-gri-standards/gri-standards-english-language
https://www.cdp.net/en/articles/companies/how-100-renewable-electricity-is-fast-becoming-the-new-normal
https://www.cdp.net/en/articles/companies/how-100-renewable-electricity-is-fast-becoming-the-new-normal
https://about.bnef.com/energy-transition-investment
https://about.bnef.com/energy-transition-investment
https://www.solarpowereurope.org/global-market-outlook-2019-2023
https://data.bloomberglp.com/promo/sites/12/678001-BNEF_2020-04-22-ExecutiveFactbook
https://data.bloomberglp.com/promo/sites/12/678001-BNEF_2020-04-22-ExecutiveFactbook
https://resource-platform.eu/wp-content/uploads/files/statements/RE-Source%203
https://resource-platform.eu/wp-content/uploads/files/statements/RE-Source%203
https://www2.deloitte.com/content/dam/Deloitte/au/Documents/audit/deloitte-au-audit-clarity-disclosure-climate-related-risks-070220
https://www2.deloitte.com/content/dam/Deloitte/au/Documents/audit/deloitte-au-audit-clarity-disclosure-climate-related-risks-070220
https://www2.deloitte.com/content/dam/Deloitte/au/Documents/audit/deloitte-au-audit-clarity-disclosure-climate-related-risks-070220
https://www.there100.org/re100-members
https://www.there100.org/re100-members
https://www.theclimategroup.org/ev100-members
https://www.theclimategroup.org/ev100-members
https://rebuyers.org/about/vision
https://resource-platform.eu/about-us
https://www.renewablethermal.org/about-us
https://www.renewablethermal.org/our-strategy
https://www.renewablethermal.org/our-strategy
https://www.wemeanbusinesscoalition.org/about
https://www.wemeanbusinesscoalition.org/about
https://missionpossiblepartnership.org/action-areas
https://missionpossiblepartnership.org/action-areas
https://www.theclimategroup.org/energy
https://www.theclimategroup.org/energy
https://www.theclimategroup.org/transport
https://www.theclimategroup.org/industry
https://www.theclimategroup.org/industry
https://www.renewable-ei.org/en/joint_initiatives
https://www.renewable-ei.org/en/joint_initiatives
https://wbcsdpublications.org/electricity
https://www.utilitydive.com/news/green-tariffs-drive-big-increases-in-corporate-renewable-procurement/574060
https://www.utilitydive.com/news/green-tariffs-drive-big-increases-in-corporate-renewable-procurement/574060
https://www.utilitydive.com/news/green-tariffs-drive-big-increases-in-corporate-renewable-procurement/574060
https://www.epa.gov/greenpower/utility-green-tariffs
https://www.epa.gov/greenpower/utility-green-tariffs
https://www.epa.gov/greenpower/unbundled-renewable-energy-certificates-recs
https://www.epa.gov/greenpower/unbundled-renewable-energy-certificates-recs
https://rebuyers.org/programs/education-engagement/renewable-energy-procurement
https://rebuyers.org/programs/education-engagement/renewable-energy-procurement
https://www.pv-magazine.com/2021/01/27/corporate-renewables-purchases-hit-record-23-7-gw-in-2020
https://www.pv-magazine.com/2021/01/27/corporate-renewables-purchases-hit-record-23-7-gw-in-2020
https://www.pv-magazine.com/2021/01/27/corporate-renewables-purchases-hit-record-23-7-gw-in-2020
http://www.dnvgl.com/article/2020-s-hot-topics-in-renewable-energy-procurement-171046
http://www.dnvgl.com/article/2020-s-hot-topics-in-renewable-energy-procurement-171046
https://www.greentechmedia.com/articles/read/transforming-corporate-sustainability-with-24-7-365-carbon-free-energy-matching
https://www.greentechmedia.com/articles/read/transforming-corporate-sustainability-with-24-7-365-carbon-free-energy-matching
https://www.greentechmedia.com/articles/read/transforming-corporate-sustainability-with-24-7-365-carbon-free-energy-matching
https://www.greentechmedia.com/articles/read/24-7-renewables-the-emerging-art-of-matching-renewables-with-demand
https://www.greentechmedia.com/articles/read/24-7-renewables-the-emerging-art-of-matching-renewables-with-demand
https://lo3energy.com/the-quest-for-24-7-renewable-energy
https://group.vattenfall.com/press-and-media/pressreleases/2020/vattenfall-to-deliver-renewable-energy-247-to-microsofts-swedish-datacenters
https://group.vattenfall.com/press-and-media/pressreleases/2020/vattenfall-to-deliver-renewable-energy-247-to-microsofts-swedish-datacenters
https://group.vattenfall.com/press-and-media/pressreleases/2020/vattenfall-to-deliver-renewable-energy-247-to-microsofts-swedish-datacenters
http://www.statkraft.com/newsroom/news-and-stories/archive/2020/daimler-sustainability-award
http://www.statkraft.com/newsroom/news-and-stories/archive/2020/daimler-sustainability-award
https://www.iea.org/reports/data-centres-and-data-transmission-networks
https://www.iea.org/reports/data-centres-and-data-transmission-networks
https://hbr.org/2017/01/energy-strategy-for-the-c-suite
http://www.thechemicalengineer.com/news/suppliers-commit-to-achieving-100-renewable-apple-production
http://www.thechemicalengineer.com/news/suppliers-commit-to-achieving-100-renewable-apple-production
https://corporate.walmart.com/newsroom/2020/09/10/walmart-and-schneider-electric-announce-groundbreaking-collaboration-to-help-suppliers-access-renewable-energy
https://corporate.walmart.com/newsroom/2020/09/10/walmart-and-schneider-electric-announce-groundbreaking-collaboration-to-help-suppliers-access-renewable-energy
https://corporate.walmart.com/newsroom/2020/09/10/walmart-and-schneider-electric-announce-groundbreaking-collaboration-to-help-suppliers-access-renewable-energy
https://www.wbcsd.org/contentwbc/download/10878/160801/1
https://www.wbcsd.org/contentwbc/download/10878/160801/1
ENDNOTES · FE ATURE: BUSINESS DEMAND FOR RENEWABLES 08
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S38 S. Enkhardt, “Rollercoaster for the European PPA market in 2020”, pv
magazine, 21 January 2021, https://www.pv-magazine.com/2021/
01/21/rollercoaster-for-the-european-ppa-market-in-2020; Pexapark,
“2021 European PPA market outlook”, https://pexapark.com/blog/
european-ppa-market, viewed 10 May 2021.
39 RE100, “Growing renewable power: Companies seizing leadership
opportunities: RE100 progress and insights annual report 2020”,
December 2020, https://www.there100.org/growing-renewable-
power-companies-seizing-leadership-opportunities.
40 Ibid.
41 RE100 members include high-profile firms such as Apple, Bank of
America, BMW, eBay, GlaxoSmithKline, HP, Ikea, Kellogg, Lego,
Mars Group, Nike, Panasonic, Sony, Starbucks, Tata Motors, Tetra
Pak, Unilever, Walmart and Zurich Insurance. See RE100, op. cit.
note 13, viewed 10 May 2021.
42 Box 10 from the following sources: Amazon, “Amazon around
the globe”, https://sustainability.aboutamazon.com/about/
around-the-globe, viewed 10 May 2021; J. Parnell,”Amazon adds
3.4GW of renewables, overtakes Google as top corporate clean
power buyer”, Greentech Media, 10 December 2020, https://
www.greentechmedia.com/articles/read/amazon-adds-3.4-gw-
of-renewable-power-capacity-knocks-google-of-cppa-perch;
Day One Team, ”Amazon announces its largest single renewable
energy project yet”, Amazon, 8 February 2021, https://blog.
aboutamazon.eu/sustainability/amazon-announces-its-largest-
single-renewable-energy-project-yet; The Climate Pledge, www.
theclimatepledge.com, viewed 10 May 2021.
43 “Denmark's Orsted, Taiwan's TSMC sign world's largest renewable
corporate power deal”, Reuters, 8 July 2020, https://www.reuters.
com/article/us-renewables-offshore-orsted-tsmc-idUSKBN24910Q
44 BloombergNEF, op. cit. note 1.
45 S. Golden, “Q4 2020: Amazon, AT&T, McDonald’s and Starbucks
lead the way as clean energy procurement matures”, GreenBiz,
14 January 2021, https://www.greenbiz.com/article/q4-2020-
amazon-att-mcdonalds-and-starbucks-lead-way-clean-energy-
procurement-matures.
46 BloombergNEF, “Corporate PPA Deal Tracker”, March 2020,
www.bnef.com/core/insights/22615.
47 IEA, op. cit. note 31.
48 K-E. Stromsta, “Microsoft eyes new tool in decarbonization
quest: Green hydrogen”, Greentech Media, 27 July 2020, www.
greentechmedia.com/articles/read/microsoft-eyes-new-tool-in-
its-decarbonization-quest-green-hydrogen.
49 IEA, Tracking Report on Industry 2020 (Paris: June 2020),
www.iea.org/reports/tracking-industry-2020.
50 IEA, World Energy Balances 2020 (Paris: 2020), https://www.iea.
org/reports/world-energy-balances-overview; J. Friedmann, Z.
Fan and K. Tang, Low-carbon Heat Solutions for Heavy Industry:
Sources, Options, and Costs Today (New York: Columbia Center
on Global Energy Policy, October 2019), https://energypolicy.
columbia.edu/sites/default/files/file-uploads/LowCarbonHeat-
CGEP_Report_100219-2_0 .
51 IRENA, IEA and REN21, Renewable Energy Policies in a Time of
Transition: Heating and Cooling (Paris: 2020), https://www.ren21.
net/heating-and-cooling-2020.
52 Ibid.; IRENA, Reaching Zero with Renewables: Eliminating CO2
Emissions from Industry and Transport in Line with the 1.5°C Climate
Goal (Abu Dhabi: 2020), https://www.irena.org/-/media/Files/IRENA/
Agency/Publication/2020/Sep/IRENA_Reaching_zero_2020 .
53 IEA, op. cit. note 49.
54 Ibid.
55 Efficiency and use of carbon capture, utilisation and storage have
been cited as more immediately feasible strategies for at least
partial decarbonisation. However, full decarbonisation would be
out of reach if companies continue to rely on fossil fuels. Ibid.;
A. Hasangeigi et al., Electrifying US Industry: A Technology- and
Process-Based Approach to Decarbonization (Arlington: Renewable
Thermal Collaborative, January 2021), https://static1.squarespace.
com/static/5877e86f9de4bb8bce72105c/t/6018bf7254023d49
ce67648d/1612234656572/Electrifying+U.S.+Industry+2.1.21.
pdf; BloombergNEF, 2020 Executive Yearbook (London: April
2020), https://data.bloomberglp.com/promo/sites/12/678001-
BNEF_2020-04-22-ExecutiveFactbook .
56 A. Aston, “This carbon challenge is bigger than cars, aviation and
shipping combined”, GreenBiz, 13 August 2020, www.greenbiz.
com/article/carbon-challenge-bigger-cars-aviation-and-
shipping-combined; IEA, op. cit. note 49.
57 See Box 1 in “Global overview” chapter of REN21, Renewables
2019 Global Status Report (Paris: 2019), https://www.ren21.net/
wp-content/uploads/2019/05/gsr_2019_full_report_en .
58 IRENA, Companies in Transition Towards 100% Renewable
Energy: Focus on Heating and Cooling (Abu Dhabi: 2021), pp.
27-30, 34-36, https://coalition.irena.org/-/media/Files/IRENA/
Agency/Publication/2021/Feb/IRENA_Coalition_Companies_
in_Transition_towards_100_2021 . Box 11 from idem and from
Elpitiya, “Environment”, https://www.elpitiya.com/environment,
viewed 25 March 2021.
59 IRENA, op. cit. note 58, p. 15.
60 Ibid., pp. 24-26.
61 Ibid.
62 European Committee for Electrotechnical Standardization (CENELEC),
Standards in Support of the European Green Deal Commitments
(Brussels: 2020), p. 6, https://www.cencenelec.eu/news/policy_
opinions/PolicyOpinions/CEN-CENELEC%20Green%20Deal%20
Position%20Paper ; see also IRENA, op. cit. note 58.
63 Buyers included L’Oréal USA and the University of California
System working with the Renewable Thermal Collaborative (RTC)
and the Centre for Resource Solutions. Aston, op. cit. note 56.
64 Ibid.
65 N. Kareta, ed., “BMW Group sources aluminum produced using
solar energy”, Spotlight Metal, 2 February 2021, https://www.
spotlightmetal.com/bmw-group-sources-aluminum-produced-
using-solar-energy-a-996983; Hydro, “Hydro to explore hydrogen
opportunities”, 7 April 2021, https://www.globenewswire.com/en/
news-release/2021/04/07/2205516/0/en/Norsk-Hydro-Hydro-
to-explore-hydrogen-opportunities.html; Hydro, “Would you like
to shape the next phase of green industrial development?” http://
www.hydro.com/en-FR/careers/experienced-professionals/join-
our-new-green-growth-journey, viewed 14 May 2021.
66 A. Frangoul, “German steel powerhouse turns to ‘green’ hydrogen
produced using huge wind turbines”, CNBC, 12 March 2021,
https://www.cnbc.com/2021/03/12/german-steel-firm-uses-
green-hydrogen-produced-with-wind-turbines.html.
67 T. K. Blank, “A new Swedish iron processing project could disrupt
the global steel industry”, GreenBiz, 17 December 2020, https://
www.greenbiz.com/article/new-swedish-iron-processing-
project-could-disrupt-global-steel-industry; T. M. Blank, “Green
steel: A multi-billion dollar opportunity”, RMI, 29 September 2020,
https://rmi.org/green-steel-a-multi-billion-dollar-opportunity.
68 Ibid., both references.
69 L. Blain, “World's largest hydrogen ‘green steel’ plant to open
in Sweden by 2024”, New Atlas, 26 February 2021, https://
newatlas.com/energy/h2gs-green-hydrogen-steel; Greenfact,
“Gigascale green hydrogen plant planned for northern Sweden”,
24 February 2021, https://www.greenfact.com/News/1399/
Gigascale-green-hydrogen-plant-planned-for-northern-Sweden.
70 This was to be achieved over six priority areas of engagement:
1) accelerate cost-effective renewable thermal technologies; 2)
create market approaches and instruments; 3) increase market
transparency; 4) standardise renewable thermal energy products;
5) create innovative financing and project structures; 6) expand
collaboration among market stakeholders. Renewable Thermal
Collaborative, “Renewable Thermal Energy Buyers’ Statement”, www.
renewablethermal.org/buyers-statement, viewed 24 March 2021.
71 Ibid.
72 The Climate Group, “Building demand for net zero steel”, https://
www.theclimategroup.org/steelzero, viewed 15 May 2021.
73 Ibid.
74 Ibid.
75 The Climate Group, “New SteelZero initiative receives backing
from major businesses, ramping up demand for clean steelmaking”,
press release (London: 1 December 2020), https://www.
theclimategroup.org/our-work/press/new-steelzero-initiative-
receives-backing-major-businesses-ramping-demand-clean.
76 Eurelectric, “Accelerating fleet electrification”, February 2021,
https://evision.eurelectric.org.
77 See Transport section in Global Overview chapter. IEA, Tracking
Report on Electric Vehicles (Paris: August 2020), www.iea.org/
fuels-and-technologies/electric-vehicles.
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ENDNOTES · FE ATURE: BUSINESS DEMAND FOR RENEWABLES 08
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S78 Eurelectric, op. cit. note 76.
79 Ibid.
80 J. Lund, “2021 is the year for electric trucks”, GreenBiz, 19 January
2021, https://www.greenbiz.com/article/2021-year-electric-trucks.
81 See Road Transport section in this chapter for examples.
82 Eurelectric, op. cit. note 76.
83 For example, in the EU, by 2030, cars must reduce CO2 emissions
by 37.5% compared with 2021, and vans 31% less. For every gram
by which a vehicle exceeds the emissions limits, an EUR 95 fine
applies. In many countries, emission regulations generally are
becoming increasingly stringent. See REN21, Renewables in Cities
2021 Global Status Report (Paris: 2021), https://www.ren21.net/
wp-content/uploads/2019/05/REC_2021_full-report_en .
84 See Road Transport section in this chapter for examples.
85 Firms also tend to replace their vehicle fleets more often than
individual owners do, so business demand could play a key role
in EV market expansion. Regular company purchases of new
EVs could provide a steady supply of relatively new, affordable
EVs to the used vehicle market. S. Colle et al., “Accelerating fleet
electrification in Europe”, EY and Eurelectric, 2021, https://assets.
ey.com/content/dam/ey-sites/ey-com/en_gl/topics/energy/
ey-accelerating-fleet-electrification-in-europe-02022021-final .
86 BloombergNEF, op. cit. note 7.
87 Ibid. For comparison, investment in this road transport technology
was only 0.7% of that for EVs in 2020.
88 Neste, Annual Report 2020 (Espoo, Finland: 2021), https://
www.neste.com/sites/neste.com/files/release_attachments/
wkr0006 ; Biofuels International, “Neste drives forward with
renewable diesel expansion in Finland”, 19 May 2020, https://
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diesel-expansion-in-finland; Neste, “Neste MY Renewable Diesel
– high-performing low-carbon biofuel”, https://www.neste.com/
products/all-products/renewable-road-transport/neste-my-
renewable-diesel, viewed 7 May 2021.
89 Neste, “Neste and IKEA Finland to reduce the carbon footprint
of home deliveries ‒ IKEA is aiming towards emission-free
deliveries by 2025”, press release (Espoo, Finland: 21 February
2021), https://www.neste.com/releases-and-news/renewable-
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deliveries-ikea-aiming-towards-emission-free.
90 Neste, “Neste, McDonald’s Netherlands and HAVI enter into
circular economy collaboration in the Netherlands”, press release
(Espoo, Finland: 24 June 2020), https://www.neste.com/releases-
and-news/circular-economy/neste-mcdonalds-netherlands-and-
havi-enter-circular-economy-collaboration-netherlands.
91 Iveco, “Lidl, IVECO, LC3 and Edison introduce the first
biomethane-fuelled vehicles in the retailer’s Italian fleet”, press
release (Turin: 23 January 2020), https://www.iveco.com/en-us/
press-room/release/Pages/Lidl-IVECO-LC3-and-Edison-
introduce-the-first-biomethane-fuelled-vehicles-in-the-retailer-
Italian-fleet.aspx.
92 EV100, op. cit. note 14.
93 NextEra Energy, “First Student, First Transit and NextEra Energy
Resources agree to jointly pursue electrification of tens of
thousands of school and public transportation vehicles across
the U.S. and Canada”, press release (June Beach, FL: 26 January
2021), https://newsroom.nexteraenergy.com/2021-01-26-First-
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94 EV100, op. cit. note 14.
95 Transport Decarbonisation Alliance, “Getting zero emission vans
and trucks on the road!” http://tda-mobility.org/getting-zero-
emission-vans-and-trucks-on-the-road, viewed 10 May 2021.
96 Drive to Zero, https://globaldrivetozero.org, viewed 10 May 2021.
97 G. Revill, Railway (London: Reaktion Books, 2012).
98 IEA, The Future of Rail (Paris: 2019), https://www.iea.org/futureofrail.
99 Ibid.
100 IEA, Tracking Report on Rail (Paris: June 2020), https://www.iea.
org/reports/rail.
101 O. Cuenca, “Indian Railways targets net zero
emissions by 2030”, International Railway Journal, 16
July 2020, https://www.railjournal.com/technology/
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network-rail-becomes-the-first-railway-organisation-to-set-
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2021.
102 N. Hunt, “All aboard Europe's first biodiesel express”, Reuters, 7
June 2007,https://www.reuters.com/article/us-biofuels-branson-
idUSL0779077820070607; N. Dinesh Nayak, “Train running on
bio-diesel flagged off, The Hindu, 4 December 2015, https://
www.thehindu.com/news/national/karnataka/train-running-on-
biodiesel-flagged-off/article7947215.ece; “Western Railway runs
trains on biodiesel across Gujarat”, Times of India, 6 June 2019,
https://timesofindia.indiatimes.com/city/rajkot/wr-runs-trains-
on-biodiesel-across-state/articleshow/69668616.cms.
103 FPL, “Florida’s energy is on the move”, https://www.fpl.com/
landing/brightline.html, viewed 15 May 2021; J. Lane, “Florida’s
new high-speed intercity rail chooses biodiesel”, Biofuels Digest,
27 June 2017, https://www.biofuelsdigest.com/bdigest/2017/06/
27/floridas-new-high-speed-intercity-rail-chooses-biodiesel.
104 Biofuels International, “18 new biodiesel fuelled trains coming
to the Netherlands”, 13 July 2017, https://biofuels-news.
com/news/18-new-biodiesel-fuelled-trains-coming-to-the-
netherlands; Biofuels International, “Dutch are all aboard with
cleaner biodiesel trains”, 2 July 2020, https://biofuels-news.com/
news/dutch-are-all-aboard-with-cleaner-biodiesel-trains.
105 Energy News, “Amp Energy installs 7.8 MW solar plant for Hyderabad
Metro Rail”, 9 February 2020, Economic Times, https://energy.
economictimes.indiatimes.com/news/renewable/amp-energy-
installs-7-8-mw-solar-plant-for-hyderabad-metro-rail/80749956.
106 Japan for Sustainability, “Japanese Railway Company to
build a mega solar power plant in rail yard”, 23 March 2013,
https://www.japanfs.org/en/news/archives/news_id032818.
html; Nikkei Asia, “JR East to boost renewable energy
use in railway operations”, 5 March 2021, https://asia.
nikkei.com/Spotlight/Environment/Climate-Change/
JR-East-to-boost-renewable-energy-use-in-railway-operations.
107 P. Gordon, “ENGIE refuels the world’s first renewable hydrogen
passenger train”, Smart Energy International, 27 March 2020,
https://www.smart-energy.com/renewable-energy/engie-refuels-
the-worlds-first-renewable-hydrogen-passenger-train.
108 Ibid.
109 Ibid.
110 IEA, Tracking Report on International Shipping (Paris: June 2020),
www.iea.org/reports/international-shipping.
111 IEA, Energy Technology Perspectives 2020 (Paris: 2020), p. 118,
https://www.iea.org/reports/energy-technology-perspectives-2020.
112 J. Jordan, “Interview: The falling cost of biofuel – now a
‘commercially and technically viable’ alternative to fossil bunkers”,
Ship and Bunker News, 18 May 2020, https://shipandbunker.
com/news/world/939386-interview-the-falling-cost-of-biofuel-
now-a-commercially-and-technically-viable-alternative-to-fossil-
bunkers.
113 Advanced Biofuels USA, “Jan De Nul’s Dredger becomes the first
to sail 2,000 hours on 100% sustainable marine biofuel”, 19 June
2020, https://advancedbiofuelsusa.info/jan-de-nuls-dredger-
becomes-the-first-to-sail-2000-hours-on-100-sustainable-
marine-biofuel.
114 Biofuels International, “Höegh Autoliners completes its first carbon
neutral voyage”, 16 March 2021, https://biofuels-news.com/news/
hoegh-autoliners-completes-its-first-carbon-neutral-voyage.
115 GoodFuels, “Marine”, https://goodfuels.com/marine, viewed
10 May 2021; Biofuels International, “Tanker prepares to set sail
on 100% biofuel”, 31 March 2020, https://biofuels-news.com/
news/tanker-prepares-to-set-sail-on-100-biofuel.
116 Biofuels International, “EPS works with Goodfuels for marine biofuel
bunkering trial”, 16 October 2020, https://biofuels-news.com/news/
eps-works-with-goodfuels-for-marine-biofuel-bunkering-trial.
117 This formed part of BMW’s broader sustainability strategy
to reduce carbon emissions by scaling up demand across
the company’s supply chain relationships. GoodShipping,
https://goodshipping.com, viewed 10 May 2021; Biofuels
International, “BMW sets sail on new marine biofuels
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https://carbon.ci/case-studies/network-rail-becomes-the-first-railway-organisation-to-set-science-based-targets-aligned-to-1-5-degrees
https://www.reuters.com/article/us-biofuels-branson-idUSL0779077820070607
https://www.reuters.com/article/us-biofuels-branson-idUSL0779077820070607
https://www.thehindu.com/news/national/karnataka/train-running-on-biodiesel-flagged-off/article7947215.ece
https://www.thehindu.com/news/national/karnataka/train-running-on-biodiesel-flagged-off/article7947215.ece
https://www.thehindu.com/news/national/karnataka/train-running-on-biodiesel-flagged-off/article7947215.ece
https://timesofindia.indiatimes.com/city/rajkot/wr-runs-trains-on-biodiesel-across-state/articleshow/69668616.cms
https://timesofindia.indiatimes.com/city/rajkot/wr-runs-trains-on-biodiesel-across-state/articleshow/69668616.cms
https://www.fpl.com/landing/brightline.html
https://www.fpl.com/landing/brightline.html
https://www.biofuelsdigest.com/bdigest/2017/06/27/floridas-new-high-speed-intercity-rail-chooses-biodiesel
https://www.biofuelsdigest.com/bdigest/2017/06/27/floridas-new-high-speed-intercity-rail-chooses-biodiesel
https://biofuels-news.com/news/18-new-biodiesel-fuelled-trains-coming-to-the-netherlands
https://biofuels-news.com/news/18-new-biodiesel-fuelled-trains-coming-to-the-netherlands
https://biofuels-news.com/news/18-new-biodiesel-fuelled-trains-coming-to-the-netherlands
https://biofuels-news.com/news/dutch-are-all-aboard-with-cleaner-biodiesel-trains
https://biofuels-news.com/news/dutch-are-all-aboard-with-cleaner-biodiesel-trains
https://energy.economictimes.indiatimes.com/news/renewable/amp-energy-installs-7-8-mw-solar-plant-for-hyderabad-metro-rail/80749956
https://energy.economictimes.indiatimes.com/news/renewable/amp-energy-installs-7-8-mw-solar-plant-for-hyderabad-metro-rail/80749956
https://energy.economictimes.indiatimes.com/news/renewable/amp-energy-installs-7-8-mw-solar-plant-for-hyderabad-metro-rail/80749956
https://www.japanfs.org/en/news/archives/news_id032818.html
https://www.japanfs.org/en/news/archives/news_id032818.html
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/JR-East-to-boost-renewable-energy-use-in-railway-operations
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/JR-East-to-boost-renewable-energy-use-in-railway-operations
https://asia.nikkei.com/Spotlight/Environment/Climate-Change/JR-East-to-boost-renewable-energy-use-in-railway-operations
https://www.smart-energy.com/renewable-energy/engie-refuels-the-worlds-first-renewable-hydrogen-passenger-train
https://www.smart-energy.com/renewable-energy/engie-refuels-the-worlds-first-renewable-hydrogen-passenger-train
http://www.iea.org/reports/international-shipping
https://www.iea.org/reports/energy-technology-perspectives-2020
https://shipandbunker.com/news/world/939386-interview-the-falling-cost-of-biofuel-now-a-commercially-and-technically-viable-alternative-to-fossil-bunkers
https://shipandbunker.com/news/world/939386-interview-the-falling-cost-of-biofuel-now-a-commercially-and-technically-viable-alternative-to-fossil-bunkers
https://shipandbunker.com/news/world/939386-interview-the-falling-cost-of-biofuel-now-a-commercially-and-technically-viable-alternative-to-fossil-bunkers
https://shipandbunker.com/news/world/939386-interview-the-falling-cost-of-biofuel-now-a-commercially-and-technically-viable-alternative-to-fossil-bunkers
https://advancedbiofuelsusa.info/jan-de-nuls-dredger-becomes-the-first-to-sail-2000-hours-on-100-sustainable-marine-biofuel
https://advancedbiofuelsusa.info/jan-de-nuls-dredger-becomes-the-first-to-sail-2000-hours-on-100-sustainable-marine-biofuel
https://advancedbiofuelsusa.info/jan-de-nuls-dredger-becomes-the-first-to-sail-2000-hours-on-100-sustainable-marine-biofuel
https://biofuels-news.com/news/hoegh-autoliners-completes-its-first-carbon-neutral-voyage
https://biofuels-news.com/news/hoegh-autoliners-completes-its-first-carbon-neutral-voyage
https://goodfuels.com/marine
https://biofuels-news.com/news/tanker-prepares-to-set-sail-on-100-biofuel
https://biofuels-news.com/news/tanker-prepares-to-set-sail-on-100-biofuel
https://biofuels-news.com/news/eps-works-with-goodfuels-for-marine-biofuel-bunkering-trial
https://biofuels-news.com/news/eps-works-with-goodfuels-for-marine-biofuel-bunkering-trial
https://goodshipping.com
https://biofuels-news.com/news/bmw-sets-sail-on-new-marine-biofuels-programme
https://biofuels-news.com/news/bmw-sets-sail-on-new-marine-biofuels-programme
ENDNOTES · FE ATURE: BUSINESS DEMAND FOR RENEWABLES 08
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S118 “Preem signs agreement for renewable maritime fuel”,
Renewable Energy Magazine, 25 March 2020, https://www.
renewableenergymagazine.com/biogas/preem-signs-agreement-for-
renewable-maritime-fuel-20210325; “Hurtigruten buys fish-based fuel
for its future fleet”, The Maritime Executive, 24 May 2019, https://www.
maritime-executive.com/article/hurtigruten-buys-fish-based-fuel-for-
its-future-fleet; “Finnish firms testing liquefied biogas as shipping fuel”,
Bioenergy Insight, 12 June 2020, https://www.bioenergy-news.com/
news/finnish-firms-testing-liquefied-biogas-as-shipping-fuel.
119 J. Timperley,“The fuel that could transform shipping”, 29 November
2020, BBC Future Inc, www.bbc.com/future/article/20201127-
how-hydrogen-fuel-could-decarbonise-shipping; J. Saul and N.
Chestney, “First wave of ships explore green hydrogen as route
to net zero”, Reuters, 30 October 2020, www.reuters.com/article/
uk-shipping-energy-hydrogen-focus-idUKKBN27F19L.
120 S. Morgan, “Norway’s green hydrogen ship granted
€8m in EU funding”, EURACTIV, 27 October 2020,
https://www.euractiv.com/section/shipping/news/
norways-green-hydrogen-ship-granted-e8m-in-eu-funding.
121 “Offshore vessel to run on ammonia-powered fuel
cell”, The Maritime Executive, 25 January 2020,
https://www.maritime-executive.com/article/
offshore-vessel-to-run-on-ammonia-powered-fuel-cell.
122 World Ports Climate Action Program, https://
sustainableworldports.org/wpcap, viewed 10 May 2021.
123 The IMO’s stricter energy efficiency targets and new fuel and
emission standards adopted in 2019 were implemented starting in
2020. Working with the Global Industry Alliance, the organisation
set goals to reduce emissions in the ship-port interface. Also in
2020, the International Chamber of Shipping, the global shipping
trade association, announced plans to invest USD 5 billion to
fund research and development related to alternative fuels.
Poseidon Principles, https://www.poseidonprinciples.org, viewed
10 May 2021; International Maritime Organisation, “Reducing
greenhouse gas emissions from ships”, https://www.imo.org/
en/MediaCentre/HotTopics/Pages/Reducing-greenhouse-gas-
emissions-from-ships.aspx, viewed 23 April 2021.
124 GreenAir, “Biofuelled Virgin Boeing 747 takes to the skies
on pioneering first flight”, 24 February 2008, https://www.
greenaironline.com/news.php?viewStory=116; European
Parliament, Sustainable Aviation Fuels (Brussels: 2019),
p. 4, https://www.europarl.europa.eu/RegData/etudes/
BRIE/2020/659361/EPRS_BRI(2020)659361_EN .
125 IEA, Tracking Report on Aviation (Paris: June 2020), https://www.
iea.org/reports/aviation; International Civil Aviation Organization
(ICAO), “Environment”, https://www.icao.int/environmental-
protection/GFAAF/Pages/default.aspx, viewed 12 March 2021.
126 IEA, op. cit. note 125.
127 Blending typically must be carried out for larger aircraft. The first 100%
biofuel flight occurred in 2012. See “Flights that have been fuelled by
biofuels: Canada claims world’s first 100% biofuel-powered civil jet
flight”, Airportwatch, 12 October 2012, https://www.airportwatch.org.
uk/biofuels/flights-that-have-been-fuelled-by-biofuels.
128 IRENA, Biofuels for Aviation. Technology Brief (Abu Dhabi: 2017),
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/
2017/IRENA_Biofuels_for_Aviation_2017 .
129 J. Makower, “Can Shell help pilot a new era of sustainable
aviation?” GreenBiz, 14 December 2020, https://www.greenbiz.
com/article/can-shell-help-pilot-new-era-sustainable-aviation.
130 P. Le Feuvre, “Are aviation biofuels ready for take off?”
IEA, March 2019, https://www.iea.org/commentaries/
are-aviation-biofuels-ready-for-take-off.
131 See, for example: B. Cogley, “World’s first commercial electric
plane takes off near Vancouver”, Dezeen, 17 December 2019,
https://www.dezeen.com/2019/12/17/worlds-first-commercial-
electric-plane-canada-seaplane; Green Car Congress, “Wright
Electric begins motor development program for 186-seat electric
aircraft; 1.5MW motor, 3 kV inverter”, 31 January 2020, https://
www.greencarcongress.com/2020/01/20200131-wright.html.
132 See Aviation Transport section in this chapter.
133 IEA, op. cit. note 125.
134 IEA, op. cit. note 125; C. Cooper, “Sustainable aviation fuel: A
journey to greener skies”, 1 December 2020, https://www.greenbiz.
com/article/sustainable-aviation-fuel-journey-greener-skies;
Makower, op. cit. note 129.
135 Ibid., all references.
136 Green Car Congress, op. cit. note 131.
137 World Economic Forum, Clean Skies for Tomorrow Coalition,
www.weforum.org/projects/clean-skies-for-tomorrow-coalition,
viewed 10 May 2021.
138 Ibid.
370
https://www.renewableenergymagazine.com/biogas/preem-signs-agreement-for-renewable-maritime-fuel-20210325
https://www.renewableenergymagazine.com/biogas/preem-signs-agreement-for-renewable-maritime-fuel-20210325
https://www.renewableenergymagazine.com/biogas/preem-signs-agreement-for-renewable-maritime-fuel-20210325
https://www.maritime-executive.com/article/hurtigruten-buys-fish-based-fuel-for-its-future-fleet
https://www.maritime-executive.com/article/hurtigruten-buys-fish-based-fuel-for-its-future-fleet
https://www.maritime-executive.com/article/hurtigruten-buys-fish-based-fuel-for-its-future-fleet
https://www.bioenergy-news.com/news/finnish-firms-testing-liquefied-biogas-as-shipping-fuel
https://www.bioenergy-news.com/news/finnish-firms-testing-liquefied-biogas-as-shipping-fuel
http://www.bbc.com/future/article/20201127-how-hydrogen-fuel-could-decarbonise-shipping
http://www.bbc.com/future/article/20201127-how-hydrogen-fuel-could-decarbonise-shipping
http://www.reuters.com/article/uk-shipping-energy-hydrogen-focus-idUKKBN27F19L
http://www.reuters.com/article/uk-shipping-energy-hydrogen-focus-idUKKBN27F19L
https://www.euractiv.com/section/shipping/news/norways-green-hydrogen-ship-granted-e8m-in-eu-funding
https://www.euractiv.com/section/shipping/news/norways-green-hydrogen-ship-granted-e8m-in-eu-funding
https://www.maritime-executive.com/article/offshore-vessel-to-run-on-ammonia-powered-fuel-cell
https://www.maritime-executive.com/article/offshore-vessel-to-run-on-ammonia-powered-fuel-cell
https://sustainableworldports.org/wpcap
https://sustainableworldports.org/wpcap
https://www.poseidonprinciples.org
https://www.imo.org/en/MediaCentre/HotTopics/Pages/Reducing-greenhouse-gas-emissions-from-ships.aspx
https://www.imo.org/en/MediaCentre/HotTopics/Pages/Reducing-greenhouse-gas-emissions-from-ships.aspx
https://www.imo.org/en/MediaCentre/HotTopics/Pages/Reducing-greenhouse-gas-emissions-from-ships.aspx
https://www.greenaironline.com/news.php?viewStory=116
https://www.greenaironline.com/news.php?viewStory=116
https://www.europarl.europa.eu/RegData/etudes/BRIE/2020/659361/EPRS_BRI(2020)659361_EN
https://www.europarl.europa.eu/RegData/etudes/BRIE/2020/659361/EPRS_BRI(2020)659361_EN
https://www.iea.org/reports/aviation
https://www.iea.org/reports/aviation
https://www.icao.int/environmental-protection/GFAAF/Pages/default.aspx
https://www.icao.int/environmental-protection/GFAAF/Pages/default.aspx
https://www.airportwatch.org.uk/biofuels/flights-that-have-been-fuelled-by-biofuels
https://www.airportwatch.org.uk/biofuels/flights-that-have-been-fuelled-by-biofuels
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2017/IRENA_Biofuels_for_Aviation_2017
https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2017/IRENA_Biofuels_for_Aviation_2017
https://www.greenbiz.com/article/can-shell-help-pilot-new-era-sustainable-aviation
https://www.greenbiz.com/article/can-shell-help-pilot-new-era-sustainable-aviation
https://www.iea.org/commentaries/are-aviation-biofuels-ready-for-take-off
https://www.iea.org/commentaries/are-aviation-biofuels-ready-for-take-off
https://www.dezeen.com/2019/12/17/worlds-first-commercial-electric-plane-canada-seaplane
https://www.dezeen.com/2019/12/17/worlds-first-commercial-electric-plane-canada-seaplane
https://www.greencarcongress.com/2020/01/20200131-wright.html
https://www.greencarcongress.com/2020/01/20200131-wright.html
https://www.greenbiz.com/article/sustainable-aviation-fuel-journey-greener-skies
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http://www.weforum.org/projects/clean-skies-for-tomorrow-coalition
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