WORKING PAPER
JUNE 20 17
The Geopolitics of
Renewable Energy
Meghan O’Sullivan
Indra Overland
David Sandalow
This paper is the result of work initiated by the International Renewable Energy Agency (IRENA)
and the Norwegian Ministry of Foreign Afairs. On March 22-23, 2017, the German Federal Foreign
Oice, IRENA, and the Norwegian Ministry of Foreign Afairs convened a workshop on the
geopolitics of renewable energy in Berlin, Germany.
A prior version of this document served as the discussion paper for that workshop. This working
paper relects discussions at the Berlin workshop and the contributions of those present. The
authors are grateful for the insights of all participants and for the support of IRENA, the German
Federal Foreign Oice, and the Norweigan Ministry of Foreign Afairs for their assistance with the
conference.
The work by Columbia University and NUPI on this working paper was funded by the Norwegian
Ministry of Foreign Afairs. The work by the Harvard Kennedy School received support from the
Middle East Initiative Kuwait Program. The authors are very grateful for this support.
This is a group product. Authors endorse the overall direction and content of this working paper,
though not necessarily every statement.
Design & Layout by Andrew Facini, Belfer Center, Harvard Kennedy School
This working paper is published by:
Center on Global Energy Policy
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New York, NY 10025
energypolicy.columbia.edu
The Geopolitics of Energy Project
Belfer Center for Science and International Afairs
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79 JFK Street
Cambridge, MA 02138
belfercenter.org/geopolitics
Cover photo: Solar panels at sunrise. (Karsten Würth)
Printed in the United States of America
WORKING PAPER
JUNE 20 17
The Geopolitics of
Renewable Energy
LEAD AUTHORS:
Meghan O’Sullivan
Indra Overland
Harvard Kennedy School of Government
Norwegian Institute of International Afairs—NUPI
David Sandalow
Columbia Center on Global Energy Policy
CONTRIBUTING AUTHORS:
Harry Begg
Harvard
Arno Behrens
Neil Bhatiya
Alex Clark
CEPS
Columbia
Harvard
Tobias Cremer
Harvard
Jonathan Elkind
Micah Fessler
Columbia
Harvard
Nathan Lemphers
Melanie Nakagawa
Magdalena Seol
Can Soylu
NUPI
Columbia
Harvard
Harvard
Roman Vakulchuk
NUPI
Executive Summary
For a century, the geopolitics of energy has been synonymous with the
geopolitics of oil and gas. However, geopolitics and the global energy economy are both changing. he international order predominant since the
end of World War II faces mounting challenges. At the same time, renewable energy is growing rapidly. Nevertheless, the geopolitics of renewable
energy has received relatively little attention, especially when considering
the far-reaching consequences of a global shit to renewable energy.
he paper starts with a discussion of seven renewable energy scenarios
for the coming decades: the IEA’s World Energy Outlook 2016, the EIA’s
International Energy Outlook 2016, IRENA’s REmap 2016, Bloomberg’s
New Energy Outlook 2016, BP’s Energy Outlook 2016, Exxon-Mobil’s Outlook for Energy 2016 and the joint IEA and IRENA G20 de-carbonization
scenario.
Some of these are forecasting while others are backcasting scenarios. While
all the forecasting scenarios envisage growth in renewable energy, none
anticipate a revolution in which renewable energy use surpasses consumption of any of the fossil fuels in the next several decades. In contrast, the
backcasting scenarios posit a future in which the world employs a radically
diferent energy mix where consumption of renewables eventually surpasses that of fossil fuels. In all three backasting scenarios covered here,
the share of renewables of total primary energy reaches 30-45% in 2035 or
2040 and 50-70% in 2050.
he paper then discusses seven mechanisms through which renewables
could shape geopolitics.
iv
Executive Summary
Critical materials supply chains. As the transition to renewable energy
accelerates, cartels could develop around materials critical to renewable
energy technologies. Even if these cartels are unable to achieve the kind
of impact that OPEC did in the 1970s oil market, they might be able to
exert inluence over consumers of these materials. Rare earth elements
are widely used in clean energy technologies, including solar panels and
wind turbines. Although rare earths elements are found in many countries
around the world, they are usually found in dilute concentrations and are
oten diicult to extract. Today almost all mining, production and processing of rare earth elements takes place in China. Lithium, cobalt and indium
are also widely used in clean energy technologies and might in some circumstances present opportunities for cartelization.
Technology and inance. In a world in which renewables are the dominant
source of energy, capital for investment and technology may increasingly
become sources of international cooperation or rivalry. First, increased
tensions between developing and developed countries could develop over
the transfer of technology. Second, conlict over renewable energy infrastructure could develop, especially if new asymmetric dependencies arise
between major producers and consumers of renewable energy. Finally, it is
not clear whether the expansion of renewable energy will involve a shit to
more decentralized and distributed energy generation (similar to farming)
or to larger companies with the inancial and scientiic clout to keep pace
in an intense global race to continuously improve technology and cost-cutting (similar to mobile telephone manufacturing).
New resource curse. he prevalence of the resource curse could be afected
by a rise of renewable energy in at least three ways. First, as oil and gas
lose their dominance in the energy mix, petro-states will lose access to the
high rents associated with the resource curse. Second, there is the question
The Geopolitics of Renewable Energy
v
of whether countries that produce large amounts of renewable energy are
likely to become subject to the resource curse, just as major oil and gas
producers have been. However, it is also possible that countries producing
renewable energy for export may actually end up with more diversiied
economies than they would otherwise, as the requirements for developing
renewable energy resources are quite diferent from the petroleum sector.
hird, there is potential for a new resource curse in countries rich in rare
earth elements.
Electric grids. Renewable energy technologies may lead to greater electric
interconnections between nations, more widespread distributed energy
generation or both. he potential geopolitical implications are complex.
On the one hand, greater cross-border trade in electricity could create
geopolitical vulnerabilities for electricity importers. On the other hand,
greater electric interconnection could increase interdependence among
nations, reducing risks of conlict. Renewable energy technologies will
afect the vulnerability of electric grids to cyber attacks, potentially creating
new vulnerabilities while at the same enhancing resilience with more widespread microgrids and distributed energy technologies.
Reduced oil and gas demand. To the extent that renewable energy reduces
demand for oil and gas, there could be signiicant geopolitical consequences. For oil and gas producers, the decline in revenue generated from
fossil fuel energy exports can provide an impetus for political reform and
economic diversiication. However, a decline in petroleum revenue could
also lead to political instability, especially in the short to medium term.
Consumer countries would improve their trade balances and their room
to maneuver in the international system. he development of renewable
energy is already a game changer for Chile, Jordan, Morocco, and several
island states in terms of energy security.
vi
Executive Summary
Avoided climate change. Reduced greenhouse gas emissions as a result
of expanded use of renewable energy should logically reduce the risk of
conlict and instability that climate change would otherwise generate. One
region where large-scale deployment of renewable energy may have signiicant geopolitical consequences is Africa.
Sustainable energy access. Access to modern forms of energy is one of
the preconditions for achieving sustainable development. he geopolitical
impacts of access to energy are important, as such access can contribute
to lasting solutions to instability and conlict. It is possible that renewables
not only have an impact on geopolitics but that geopolitics, particularly in
risky and institutionally unstable environments, can also inluence investments in renewable energy by increasing the cost of capital.
hese categories do not ofer a comprehensive assessment of the ways in
which renewables afect geopolitics. he purpose of this paper is to provide
food for thought for a broader discussion on the ways in which greater
renewable energy and geopolitics intersect. Accordingly, the inal section
(Section III) suggests areas and directions for future research.
The Geopolitics of Renewable Energy
vii
Table of Contents
Executive Summary ........................................................................................... iv
Introduction ......................................................................................................... 1
I. Renewable Energy Deployment Scenarios ..................................................3
A) Forecasting Scenarios ................................................................................ 4
B) Backcasting Scenarios ............................................................................... 7
1)
IEA 450 Scenario (from World Energy Outlook 2016) .............................................................. 7
2)
IRENA REmap Doubling Options (IRENA REmap 2016 edition) .............................................. 8
3)
IRENA and IEA’s “Perspectives for the Energy Transition” (March 2017) .............................. 9
II. Mechanisms ..................................................................................................11
A) Critical Materials Supply Chains .............................................................. 11
B) Technology and Finance ...........................................................................14
C) New “Resource Curse” .............................................................................. 17
D) Electric Grids .............................................................................................19
1)
Supergrids ..................................................................................................................................19
2)
Micro-Grids and Of-Grid Solutions ..........................................................................................21
3)
Cyber Risks ................................................................................................................................ 23
E) Reduced Oil and Gas Demand ................................................................ 25
1)
Impacts on Producers ............................................................................................................... 25
2)
Impacts on Consumers ............................................................................................................. 27
F) Avoided Climate Change .......................................................................... 28
G) Access to Sustainable Energy ..................................................................31
III. Uncertainties ................................................................................................33
IV. Options for Further Analysis .......................................................................34
Scenario building ........................................................................................... 34
Modeling ......................................................................................................... 34
Index of geopolitical vulnerability ................................................................. 35
Geographically based review ........................................................................ 35
Analytical distinctions ................................................................................... 36
V. Conclusion .................................................................................................... 37
Annex I: Literature review .................................................................................38
Overview ......................................................................................................... 39
Geopolitical beneits ......................................................................................40
Geopolitical downsides ...................................................................................41
Vulnerable states ........................................................................................... 42
Uncertainty ..................................................................................................... 45
Changes in the international system ............................................................ 46
Scenarios and typologies .............................................................................. 47
Metals and industrial minerals scarcity ....................................................... 47
Other aspects ................................................................................................. 48
Methodological note ...................................................................................... 49
References (literature review).......................................................................................................... 49
Annex II: Workshop Program ............................................................................52
Annex III: Workshop Participants .....................................................................55
Solar panels are seen near transmission
lines in northwestern China’s Ningxia
Hui autonomous region, Oct. 9, 2015.
(AP Photo/Ng Han Guan)
Introduction
For decades, the geopolitics of energy has been largely synonymous
with the geopolitics of oil and gas. he focus on how oil and gas
shapes the way states develop, interact with one another, form
alliances and wage war has made a certain amount of sense. Oil and
gas account for more than half of global energy consumption and
captured close to 70 percent of total investment in energy supply
from 2000-2015.1 he world’s transportation systems—and therefore
national economies—depend almost completely on supplies of oil.
Yet geopolitics and the global energy economy are both changing.
he traditional deinition of geopolitics is the inluence of geography
upon the foreign relations of states. However in recent years the role of
non-state actors in international relations has both grown and become
increasingly well recognized. Leaders and policymakers are more and
more consumed by transnational threats, which pose challenges to
multiple countries and cross borders; cyber and terrorism are two of
the most prominent examples, alongside climate change. At the same
time, many of the concerns of earlier decades have resurfaced in recent
years, as challenges have mounted to the international order that has
been predominant since the end of World War II. Great power conlict—while unimaginable only a few years ago—is now again in the
realm of the possible.
Meanwhile the costs of solar and wind power have dropped dramatically, helping renewable energy make signiicant inroads into the
global energy mix. Sales of alternative fuel vehicles, while still small as
a percentage of total vehicle sales, have climbed sharply, especially in
China. Cross-border renewable energy trade has caused international
tensions, including solar trade disputes between the European Union
and China and between the United States and India. Investment in
renewable energy is crossing international borders and in some cases
is overtaking fossil energy investments. Non-energy companies are
1
US EIA, International Energy Outlook 2016 -- http://www.eia.gov/outlooks/ieo/exec_summ.
cfm - at Figure ES-2 (with respect to energy consumption); IEA World Energy Outlook 2016,
Executive Summary, pg 2, https://www.iea.org/publications/freepublications/publication/
WorldEnergyOutlook2016ExecutiveSummaryEnglish.pdf (with respect to investment).
The Geopolitics of Renewable Energy
1
investing in major renewable energy projects across the globe, such as
Google’s investment in the Lake Turkana Wind Power Project in Kenya
(Africa’s biggest wind farm and the largest single private investment in
Kenya’s history when completed).2 Distributed renewable energy is helping
address energy poverty. In India, more than a million households are beneiting from solar energy, with over 10,000 remote villages securing basic
electricity through distributed renewable power alone.
Nonetheless, the geopolitics of renewable energy has received relatively
little study.3 he literature review carried out for this report inds that the
geopolitical consequences of a transition to renewable energy has received
far less attention than the geopolitical consequences of, for instance, fracking. Most research on the geopolitics of renewable energy to date has been
conducted by Dutch and German research institutions and largely consisted of gray literature (working papers, online reports, dissertations etc.).
(See the annex for further detail).
One reason for the dearth of research on this topic may be that the geopolitics of renewable energy difers considerably from that of oil and gas,
making it diicult to apply familiar frameworks and concepts. Another
may be that renewable energy’s role in the global economy has not until
recently been large enough to lead all but a few observers to consider its
geopolitical impacts. Most of the academic and policy work on renewable
energy to date has focused on how to achieve the transition to a low carbon
future, not on the impacts of a successful transition on global politics or
the power of states.
Policy makers, corporate leaders, and academics alike could beneit from a
better understanding of how a rapid expansion of renewable energy could
afect the geopolitical status quo. his paper suggests an analytic framework for exploring this topic.
2
2
The Guardian (09.10.2015) “Africa’s largest windfarm set to connect remote Kenya to the grid”,
https://www.theguardian.com/environment/2015/oct/09/africas-largest-windfarm-set-to-connect-remote-kenya-to-the-grid (last accessed 02.02.2017)
3
Overland, I. (2015) “Future Petroleum Geopolitics: Consequences of Climate Policy and Unconventional Oil and Gas,” Handbook of Clean Energy Systems, Chichester: Wiley, pp. 3517–3544, https://
www.academia.edu/15717140/Future_Petroleum_Geopolitics_Consequences_of_Climate_Policy_and_Unconventional_Oil_and_Gas
Introduction
he paper is focused on the geopolitics of renewable energy. It does not
address the geopolitics of a low carbon future more broadly. Other strategies for decarbonization—including a shit from coal to natural gas and
growth of nuclear power—may have important geopolitical consequences
that merit study as well. his study, however, focuses solely on the geopolitical implications of a large-scale shit to renewable energy.
I.
Renewable Energy
Deployment Scenarios
here are dozens of long-term projections ofering diferent views on the
global energy mix and how it will afect speciic regions or countries. In
this paper, we consider the projections of six major agencies and companies: the IEA World Energy Outlook (WEO) 2016, the EIA International
Energy Outlook (IEO) 2016, the IRENA REmap 2016, Bloomberg New
Energy Outlook 2016, the BP Energy Outlook 2016, Exxon-Mobil Outlook
for Energy 2016 and the IEA’s and IRENA’s G20 de-carbonization scenario
(2017). Each of these is based on diferent assumptions and methods, leading to diferent scenarios for the decades ahead.
In examining these scenarios, we distinguish between forecasting scenarios
and backcasting scenarios. Forecasting scenarios start with assumptions
about technology, policy and other topics such as global growth and population. hey then describe one or more futures based on these parameters
projected forward. Oten, in “best-guess” or reference case scenarios, these
scenarios tell us where the company or agency thinks the world is likely
to end up assuming some version of current trends continue. Backcasting
scenarios, in contrast, begin by staking out a particular future (usually a
desirable one) and working backwards to demonstrate the sort of policy
changes or technological advances required for that future to materialize.
he two types of scenarios serve diferent purposes. For reasons explained
below, we use backcasting scenarios from the IEA and IRENA as the principal analytical foundation for this study.
The Geopolitics of Renewable Energy
3
A) Forecasting Scenarios
he forecast scenarios surveyed in this paper contain diferent assumptions
about the penetration of renewables in the future energy mix, arising from
diferent sets of assumptions about policy, technological change, future
economic, population growth and other matters.4 One possible explanation
for diferent outcomes is timing, as some forecasts focus on 2035, while
others look to 2040. However, a mere ive-year gap cannot explain much
of the diference in outcomes. More signiicantly, the scenarios diverge in
relation to how they deine renewables or how they group together various
categories when reporting data. For instance, the IEA includes marketed
biomass (gathered wood) in its reporting on renewables, whereas some
company forecasts, such as the one from BP, do not. he EIA includes biofuels along with oil and other liquids.
In addition, each forecast is based on a diferent set of assumptions about
policy, technological change, and other matters. For example, scenarios
are oten built on diferent assumptions about how quickly China is able to
transition its economy away from an export focus to a more service-oriented basis for growth; such assumptions afect China’s overall coal use
(and the balance of other fuels). Scenarios also contain diferent assumptions about global economic growth and the rate of the expansion of the
world’s population; both can inluence the pace of energy demand growth.
Another diference is the extent to which renewables permeate sectors outside the power ones. Finally, scenarios can difer on the speed and scope
of the penetration of transportation by natural gas and/or electriication,
which afects demand for oil, natural gas, and possibly many forms of
renewables.
Despite these diferences, one similarity among these forecasts is notable
for purposes of this paper. While all the forecast scenarios see growth in
renewable energy, none anticipate a revolution in renewable energy use.
In their “best guess” or reference case scenarios, none see consumption of
4
4
For example, scenarios are often built on diferent assumptions about how quickly China is able to
transition its economy away from an export focus to a more service-oriented basis for growth; such
assumptions afect China’s overall coal use (and the balance of other fuels).
I. Renewable Energy Deployment Scenarios
renewable energy surpassing consumption of any of the fossil fuels (oil,
natural gas, or coal) in the next several decades.5
he reference case forecasting scenarios we reviewed project a 4-7 percentage point shit from fossil fuels to renewables in the next 15-25 years.
IEA’s main scenario, the New Policies Scenario, forecasts that the share of
renewables, including biomass, biofuels and hydroelectricity, in the energy
mix will grow from 14.2% in 2014 to 19.3% in 2040. In contrast, the EIA’s
reference case forecasts growth from 12.2% in 2015 to 16.1% in 2040.
While such scenarios are important to consider, they are of limited value
in assessing the geopolitical consequences of renewable energy. Indeed, by
projecting that the transition to renewable energy in the coming decades is
unlikely to be substantial, these scenarios raise questions about the need to
consider the geopolitical consequences of such a transition.
here are, however, important reasons to consider the geopolitical consequences of renewable energy. First, many of forecasting scenarios have
consistently underestimated the growth of renewable energy in the past.6
Wind and solar installed capacity had to be adjusted upwards in almost
every forecasting report over the last decade. It is therefore not unreasonable to surmise that the growth of renewables in the future may outpace
current projections. Second, even small changes in the global energy mix
could have signiicant geopolitical consequences. he global energy system
is so vast—with trillions of dollars of legacy infrastructure—that even
minor changes could have outsized impacts in some regions and sectors.
5
The EIA has its “Reference Case;” the IEA has its main scenario called “New Policies Scenario;” BP
has what it calls its “base case.”
6
Aleklett, Kjell; Höök, Mikael; Jakobsson, Kristofer; Lardelli, Michael; Snowden, Simon; Söderbergh,
Bengt, The Peak of the Oil Age—Analyzing the world oil production Reference Scenario in World
Energy Outlook 2008, Energy Policy, 2010, Vol.38(3), pp.1398-1414; Rolf de Vos and David de Jager,
“World Energy Outlook hides the real potential of renewables” EnergyPost: http://energypost.eu/
world-energy-outlook-hides-real-potential-renewables/
The Geopolitics of Renewable Energy
5
Figure 1.
EIA IEO2016
Share
of Fossil
Fuels
Year
2014
Share of
Renewables
(deined as ‘’other’’
than liquids, gas,
coal and nuclear)
BPEO2016
IEA WEO2016
Share
of Fossil
Fuels
Share
of Fossil
Fuels
11.95%
2015
83.25%
12.19%
2016
82.62%
12.66%
2020
81.26%
2025
Share of
Renewables
9.22%
Share of
Renewables
81.01%
14.16%
85.43%
9.57%
13.83%
83.01%
11.41%
79.04%
15.50%
80.21%
14.66%
80.96%
13.28%
77.72%
16.50%
2030
79.33%
15.07%
79.10%
14.92%
76.34%
17.47%
2035
78.73%
15.61%
77.19%
16.65%
75.16%
18.41%
2040
78.24%
16.12%
74.04%
19.34%
-5.01%
3.93%
-6.97%
5.19%
% change
(from earliest
year to last
available year)
“Liquids’’ category does not
separate biofuels; biofuels
are thus included in the fossil
fuels category.
6
I. Renewable Energy Deployment Scenarios
-8.25%
7.09%
Biofuels and hydroelectricity
are calculated as part of
renewables here.
“Bioenergy includes the
traditional use of solid
biomass and modern use of
bioenergy.” Hydro is separate
from renewables, which
were reported as “other
renewables.”
B) Backcasting Scenarios
Backcasting scenarios take a diferent approach, deining a desired endpoint and working backwards to identify the steps required to arrive at
such an endpoint. hree backcasting scenarios may be helpful for this project: the IEA 450 scenario, the IRENA REmap Doubling Options scenario
and Perspectives for the Energy Transition, the full decarbonization scenario produced in cooperation with both organizations.
1)
IEA 450 Scenario
(from World Energy Outlook 2016)
he IEA’s 450 Scenario is a backcasting scenario from 2040 which starts
from the assumptions that the world must limit atmospheric carbon dioxide concentrations to 450 parts per million. (According to the IPCC, this
would result in a 50% chance of limiting the rise in global average temperatures to 2ºC above pre-industrial levels by 2100.) A major advantage of
this scenario is that it clearly states its assumptions and provides detailed
consideration of emerging technologies, including carbon capture and
storage (CCS), electric vehicles and biofuels. he 450 Scenario also ofers a
comprehensive overview of the global beneits of renewables based on an
extensive analysis of fossil-fuel markets, and examines changes to industrial, commercial and residential electricity prices. his allows the report to
spell out the consequences of such developments for the fossil fuel industry
and fossil fuel producing countries. Moreover, for the irst time, the 450
Scenario also looks at pathways towards limiting the increase to 1.5°C. he
scenario also has the advantage of having been recently updated to relect
the Paris agreement and 190 separate Nationally Determined Contributions (NDCs).
Despite these beneits, the 450 Scenario also has downsides for the purposes of this study. To make the backcasting exercise work, the report
adopts some bold assumptions, such as a carbon price of $140/ton by
2040 in power and industry in the United States, European Union, Brazil,
China, Russia, South Africa, New Zealand, Australia, Japan, Korea, and
The Geopolitics of Renewable Energy
7
Canada. he scenario also assumes extremely strong public institutions
capable of inancing eiciency measures and giving clear policy signals.
Another potential weakness is that the trade-ofs between the three factors
of environmental protection, economic growth and energy security could
be better developed. Moreover, there is little detail on adverse side efects of
technological advances, such as the negative impact of the growth of biofuels on food security or the temptation to increase fossil fuel consumption if
better CCS technology becomes available.
2)
IRENA REmap Doubling Options
(IRENA REmap 2016 edition)
IRENA’s Doubling Options scenario takes as its starting point a world in
2030 in which the total share of renewables in the primary energy mix
(including biomass) has doubled to 36%. he main conceptual strength
of the scenario is that it provides a detailed country-by-country roadmap
for its member states to reach the 36% goal. In so doing, it reveals the
extent to which the renewable energy opportunities vary among countries. Such discrepancies will be critical to the mapping of asymmetries
between countries and regions—and anticipating the geopolitical consequences such disparities as these may cause. he speciic focus on OECD
countries, BRICS, and GCC countries may further facilitate this exercise.
Another strength is the scenario’s in-depth examination of speciic sources
of renewable energy. It individually explores the trajectories of wind, solar,
and biofuels as well as the consequences of greater electriication. Similarly,
it provides a sectoral analysis of transport, buildings, and industry. A inal
advantage is that the report makes a clear and convincing economic argument for doubling the share of renewables in the global energy mix and the
falling price of renewables to their potential displacement of fossil fuels.
he large degree of geographical and sectoral diferentiation, however,
can also present a downside to the use of the IRENA Doubling Options
scenario for the purposes of this study. he strong segmentation makes it
more diicult to identify assumptions on a meta-level, or to ind a middle
ground between universal fulillment of all individual country options and
8
I. Renewable Energy Deployment Scenarios
going into the detail for every single country. Moreover, given this diiculty to dissect and quantify the assumptions it is sometimes hard to assess
their feasibility, especially since many assumptions appear dependent on
immediate policy action in speciic sectors. Perhaps the greatest weakness
of the scenario, however, is that outside the power sector, it provides no
detailed projection of how the doubling of renewables would impact other
sources of energy (for example, in the transportation sector), which is critical for assessing the geopolitics of renewable energy.
3)
IRENA and IEA’s “Perspectives for the
Energy Transition” (March 2017)
his joint venture of IRENA and the IEA was commissioned by Germany
in the year of its G20 presidency, and conceived as input into G20 work on
energy and climate. he efort produced two backcasting scenarios—one
by each institutions—both of which take as a starting point a world in 2050
which is consistent with limiting the rise in global temperatures to 2ºC by
2100 with a probability of 66%. Whereas each institution developed a different pathway for such a future, in both renewables make up a much more
signiicant proportion of the total primary energy supply in 2050. he
request from the German government was to illuminate the key elements
of a low-carbon transition with particular focus on the G20 energy sector,
including cost-efective investment in power generation, transport, buildings and industrial production with policy co-beneits.
he report considers, in detail, the implications of rising energy demand,
the need for changes in investment patterns, the efects of climate change
on food security and migration, air pollution in emerging economies,
energy eiciency and in particular, the role of renewables in the context of rapid technological change. he IEA scenario anticipates 40-45%
renewables in the primary energy supply by 2050, while IRENA envisions
65%. In either case, it is clear that meeting the Paris Agreement will have
enormous implications for the role of renewables, as well as for the fuels
renewable energy will displace.
The Geopolitics of Renewable Energy
9
he advantages of such a scenario for the purposes of this study are
manifold. First, the cooperation between IRENA and IEA combines the
above-described strengths in the approaches of both institutions. It draws
on the comprehensiveness of the IEA’s approach, in particular its detailed
assessment of how other sources of energy will fare, and clearly stated
assumptions about which overall technical advances will be necessary.
It incorporates IRENA’s strengths on detailed sectoral and geographical
analysis for renewable energy deployment and maintains a focus on the
economic consequences of such a radical energy transition in terms of
investment, stranded assets, growth, trade and employment.
Crucially, the data analysis was conducted separately by both institutions,
with very similar results, lending the indings additional credibility. he
support and consultation of academic institutions such as the Institute for
Sustainable Futures (Sydney), the Smith School of Enterprise and Environment (Oxford), and the IPCC endow the report with additional expertise
and inter-institutional perspectives. At the time of writing, the IEA-IRENA
scenario is the newest and most up-to-date scenario on ofer.
10
I. Renewable Energy Deployment Scenarios
II. Mechanisms
he backcasting scenarios summarized above portray a future in which
the world employs a radically diferent energy mix. All three describe a
future in which the share of renewables of total primary energy is between
30-45% in 2035/2040 and between 50-70% in 2050. In this section we consider the potential geopolitical consequences if renewables reach this level
of deployment. he section is organized around ive topics -- critical material supply chains, technology and inance, electric grids, reduced oil and
gas demand and avoided climate change. We examine whether high levels
of renewable energy deployment could have geopolitical consequences
related to each of these topics.
A) Critical Materials Supply Chains
As the transition to renewable energy accelerates, cartels could develop
around materials critical to renewable energy technologies. Even if these
cartels were unable to generate as much impact as OPEC did with oil in
years past, they might be able to exert inluence over consumers of these
materials. Some materials critical for renewable energy technologies are
also critical in other sectors, such as consumer products and weaponry,
raising the potential for competition between sectors as well.
Rare earth elements (including dysprosium, neodymium, terbium, europium and yttrium) are oten considered to be critical components of
renewable energy hardware.7 Ironically, rare earth elements are not rare.
hey are found in many countries, including China, Russia, Australia, the
United States, Brazil, India, Malaysia and hailand. However, two countries—China and Russia—together hold 57% of global reserves, while the
largest remaining country, Australia, holds a mere 2.4% of global reserves.8
Furthermore, rare earths are found in dilute concentrations and are oten
diicult to separate, making mining, production and processing diicult
7
Resnick Institute. 2011. Critical Materials For Sustainable Energy Applications. Resnick Institute
Report. http://resnick.caltech.edu/docs/R_Critical.pdf
8
U.S. Geological Survey. 2016. Rare Earths. U.S. Geological Survey: Mineral Commodity Summaries.
https://minerals.usgs.gov/minerals/pubs/commodity/rare_earths/mcs-2016-raree.pdf
The Geopolitics of Renewable Energy
11
and capital intensive. Today almost all mining, production and processing
of rare earths is in China. Rare earths mined elsewhere generally must be
exported to China for processing and then re-imported.9 As demand for
renewable energy technologies continues to increase, countries may be
inclined to hold rare earth elements in reserve for themselves and compete
over these resources.
Strategies for avoiding cartel development and geopolitical tensions with
respect to rare earths include (i) developing supplies in additional countries, (ii) reducing the need for rare earths in renewable energy and other
sectors through technological innovation, and (iii) improved re-use and
recycling.10 Absent such strategies, dependence on China as the overwhelmingly dominant supplier of rare earths for global commerce will
continue.
Lithium is also critical for renewable energy technologies. Lithium ion
batteries are used to help manage the intermittency of solar and wind
power and in electric vehicles. hey are also widely used in other industries, including personal electronics.11 he world’s largest lithium producers
are Australia, Chile China and Argentina (in that order). Bolivia has
signiicant lithium resources, but they remain largely untapped. Current
calculations about the global demand for lithium are based on assumptions
about the penetration rate of electric vehicles, which may change rapidly
if more EVs become commercially available and cost-competitive with
traditional automobiles.12 Even if global lithium resources are adequate to
meet global demand, short- and medium term mismatches between supply
and demand could give leverage to producer nations. As with rare earths,
strategies for reducing dependence include developing additional supplies,
12
9
Karen Smith Stegen. 2015. “Heavy rare earths, permanent magnets, and renewable energies: An
imminent crisis.” Energy Policy 79, 1-8.
10
See U.S. Department of Energy, Critical Materials Strategy (December 2011), 12
11
U.S. Geological Survey. 2015. Lithium. U.S. Geological Survey: Mineral Commodity Summaries.
https://minerals.usgs.gov/minerals/pubs/commodity/lithium/mcs-2015-lithi.pdf, accessed 19
February 2017.
12
Tam Hunt (2015). “Is There Enough Lithium to Maintain the Growth of the Lithium-Ion Battery
Market?” Greentech Media, https://www.greentechmedia.com/articles/read/Is-There-EnoughLithium-to-Maintain-the-Growth-of-the-Lithium-Ion-Battery-M, accessed 19 February 2017.
II. Mechanisms
developing synthetic substitutes, and recycling (though the latter is currently not economically viable).13
Indium and cobalt are also used in renewable energy technologies including solar panels and batteries. China provides roughly half the world’s
indium. DR Congo provides more than half the world’s cobalt.
Geological reserves are not absolutes, but a function of factors including:
demand; investment in geological exploration; technologies available for
geological exploration, extraction and processing, and their costs; introduction of robots and artiicial intelligence in mining operations; scale
economies at all levels; the accounting regulations and choice of inancial
model for calculation of reserves that are commercially viable to extract.
he size of global reserves and their distribution among countries are
therefore subject to signiicant changes over time.
Demand for minerals is a function of the prevalent technologies at any
moment. Advances in engineering oten make it possible to replace one
material with another within a technology. In addition, entire technologies
are sometimes replaced once scarcity develops or innovation creates viable
alternatives.
In many countries, lead times for the development of mines can be in the
range of 10 years. In addition some minerals critical to renewable energy
technologies are mined mainly as by-products of other minerals. As a
result of these and other factors, supply shortages may arise if demand
increases unexpectedly or too fast. However as supplies tighten, previously
uneconomic deposits may become viable, providing additional sources of
supply in the medium- to long-term.
13
Steve H. Mohr, Gavin M. Mudd, and Damien Giurco (2012). “Lithium Resources and Production:
Critical Assessment and Global Projections,” Minerals 2.3, 65-84.
The Geopolitics of Renewable Energy
13
B) Technology and Finance
Signiicant investment will be required to develop the renewable energy
technology and infrastructure contemplated in the backcasting scenarios.
As a result, intellectual property may be especially important in a world
dominated by renewable energy. Although intellectual property is highly
valuable in the fossil fuel sector as well, a country with substantial fossil
resources and limited technological competence can nevertheless receive
signiicant revenues. In the renewable energy sector, resources are much
more widely distributed and thus intellectual property rights may become
more important in relative terms. his may be an advantage for countries
with strong innovation cultures and research capacities.
his reality may create a shit in the source of power from securing access
to energy resources (as is the case with oil and gas) to strategic positioning
in infrastructure capacity and management system eiciency. As a result, in
a world in which renewables are a dominant source of energy, investment
and technology may increasingly become a source of cooperation or a
node of geopolitical rivalry. In this context, below are three possible macro
trends.
First, increased tensions between developing and developed countries
over the transfer of technology: As Criekemans indicates, “from an external-geopolitical perspective, those countries that today invest in renewable
energy sources and technology may become the dominant geopolitical players tomorrow.”14 Countries’ R&D expenditures may need to be
assessed from not only an economic or environmental perspective, but
also from a geopolitical one. However, while economics and the environment are frequently considered positive-sum games where absolute gains
matter, geopolitics is oten seen as a zero-sum game in which relative gains
are more important. As a result, trade of technology may become an area
of cooperation if countries consider technology and trade primarily in
economic or environmental terms, as it would then be in the interests of
developed countries to share technology even at low prices. his trend
is best exempliied by the emergence of “Mission Innovation” in 2015, a
global initiative of 22 countries and the European Union to dramatically
14
14
Criekemans (2011: 8)
II. Mechanisms
accelerate global clean energy innovation through governments making
commitments to double their investments in research and development
over ive years.
Related to this, it is also important to consider how collaborative private
sector platforms and multilateral institutions could inluence technology
transfer, whether in the form of the Breakthrough Energy Coalition, a partnership committed to broad investment in new energy technologies from
public and private sources, or the Green Climate Fund. However, if countries choose to view technologies as geopolitical rather than economic or
environmental assets, it should also be considered how companies—who
oten own the technology—might try to incentivize countries to cooperate
when these countries may have little interest in doing so.
In reality, the distinction between economic, environmental and geopolitical dimensions is of course much more blurred. Yet, it is important to
keep these countervailing interests in mind when trying to understand
why there is tension between developing and developed countries when
it comes to the sharing of renewable energy technology or why certain
countries have taken particular positions. For instance, the government
in Tehran is not considered to be internationalist, yet it is one of the most
vocal proponents of research cooperation. Another example of where
economic reasons coupled with geopolitical considerations have trumped
environmental objectives is the EU’s anti-dumping and anti-subsidy duties
on imports of solar cells and solar panels from China.15
A second related trend would be potential competition with respect to
renewable energy infrastructure. German energy companies are already
undergoing deep transformations as they attempt to adapt to the new
emerging energy landscape. he energy companies of many countries
could follow. In 2015, the biggest locations for renewable energy investment were China (far out in front at $83.3 billion) and the United States
($38.3 billion), with Japan taking third place ($35.7 billion). India was up
15
European Commission: “Commission imposes duties to prevent imports of dumped and subsidised
Chinese solar panel components via Taiwan and Malaysia”, http://trade.ec.europa.eu/doclib/press/
index.cfm?id=1461 (last accessed 02.02.2017)
The Geopolitics of Renewable Energy
15
14% at $7.4 billion.16 While Asia was expected to be the major consumer
region for the conventional energy, in the renewable energy dominant
world, the region will have a substantial renewable energy capacity. One
possibility of how China might parlay this into geopolitical leverage is if
it moves ahead with its proposed $50 trillion worldwide wind and solar
power grid, the “Global Energy Interconnection,” which China envisions
could be in operation by 2050.17 he project envisions both global power
connectivity and global power generation from the North Pole to the
farms in the equator. How would other countries respond? How would this
project and the technological transfers involved tether other countries to
China? (See the discussion below on “supergrids.”) What would happen if
a new technology emerged providing a cheaper and more eicient way of
transporting renewable energy, for example related to hydrogen?
Sovereign wealth funds and institutional investors could also come to play
important roles, both by choosing what new energy infrastructure or technology to invest in, and through the resulting control over these assets.
Finally, one could argue that the nature of renewable energy makes its
development better suited to smaller companies and privately funded
start-ups, rather than the large state-owned companies predominant in the
world of oil and gas. his is in part because renewable energy lends itself
to a more decentralized and distributed energy generation system than
fossil fuels. Cheap solar, innovative business models, and a new breed of
entrepreneurs are revolutionizing how energy access issues are addressed:
new players focused on “of-grid” or “mini-grid” solutions are challenging
the assumption that only an expanded hub-and-spoke power grid can meet
the needs of the world’s 1.2 billion with inadequate access to power. hese
startups are mostly privately-funded and between them had raised over
$450m cumulatively in case of year-2015.18 he rise in the number of these
successful start-ups that enable demand response is leading to increasingly
more distributed energy systems. In turn, these more distributed systems
16
16
Bloomberg New Energy Finance, “Global Trends in Renewable Energy Investment 2015,” Frankfurt
School-UNEP Centre/BNEF, 2015; Rebecca Harrington, “The US is actually leading the way on
clean energy” 6 May 2016. http://www.businessinsider.com/us-2015-renewable-energy-investments-2016-5
17
World Economic Forum, “China wants to build a $50tn global wind and solar power grid” (5 April
2016)
18
ClimateScope 2016, http://global-climatescope.org/en/blog/2016/12/15/Climatescope2016-launch/.
II. Mechanisms
may require a broadening of the decision-making power away from a concentrated set of a few countries and large players to one that empowers
more individuals and smaller players.
However, the opposite may be more nearly true: companies with substantial balance sheets may be best positioned to succeed in the renewable
energy sector as it grows. In recent years large oil and gas companies have
started to move into the renewable energy market in a signiicant way.19
For example, Total’s expansion into renewables has included the acquisitions of SunPower, a U.S. solar panel manufacturer for $1.4 billion and
Sat a leading battery designer for $1 billion. Related, Statoil is committed
to building a renewable energy business and will see in 2017 its second
conventional ofshore North Sea wind farm coming online, the 402 MW
Dudgeon, and the 30MW Buchan Deep project, the world’s irst loating
array.20 he impact these seemingly deeper capital pools for investment in
renewables will have in deployment and market adoption has not yet been
fully analyzed but could also afect country positions toward cooperation
or competition.
C) New “Resource Curse”
he high rents associated with the production and sale of fossil fuels have
sometimes been associated with a variety of developmental ills, collectively referred to as the resource curse.21 Particularly when oil and gas
are produced in countries with weak institutions, the rents extracted may
lead to any or all of the following: an overvalued exchange rate, a decline
in non-tradeable sectors of the economy, increased corruption, authoritarian institutions, and domestic and international violent conlict.22 he
19
Macalister, Terry. “Green really is the new black as Big Oil gets a taste for renewables,” The Guardian, 21 May 2016.
20
Snieckus, Darius. “Ones to Watch 2017: The world’s oil giants are all too aware that the tide is
turning so expect more activity in wind and solar this year, writes Darius Snieckus”, Recharge News,
updated 30 January 2017.
21
Frankel, J.A. (2010) The Natural Resource Curse: A Survey. NBER Working Paper. www.nber.org/
papers/w15836
22
Humphreys, M., Sachs, J. and Stiglitz, J. (2007) Escaping the Resource Curse; Overland, I. (2012)
“Slippery slopes: pitfalls for the rulers of resource-rich states,” in Andreas Heinrich and Heiko
Pleines (eds), Challenges of the Caspian Resource Boom: Domestic Elites and Policy-Making,
Houndmills: Palgrave Macmillan, pp. 35-45.
The Geopolitics of Renewable Energy
17
prevalence of the resource curse could be afected by the dominance of
renewable energy in at least three ways.
First, as oil and gas lose their dominance in the energy mix, the rents
associated with their production will diminish. As a result, oil and gas-producing countries will lose access to the high rents associated with the
resource curse. Alternatively, without rents, which helped provide a critical
supplemental income stream to certain countries, those countries may be
more vulnerable to domestic unrest or conlict. his issue area is dealt with
in more detail in the section below on reduced demand for oil and gas.
Secondly, there is the question of whether countries producing large
amounts of renewable energy are likely to be subject to the resource curse,
just as large oil and gas producers have been. A renewable energy resource
curse seems unlikely to materialize for a number of reasons. Renewable
energy resources are not point-source and mainly require surface area,
which—in spite of possible conlicts over land ownership23—is less scarce
and concentrated than oil or gas. Some areas have much higher renewable
energy potential than others—e.g. Chile’s Atacama Desert—yet potential
developers may nevertheless choose to build renewable capacity domestically when faced with the national security premium of being in thrall to
another state for electricity supply, or if the cost of transmission is too high.
he fact that successfully deploying renewable energy requires a country to
have a high governance capacity and the involvement of multiple sectors,
including rare earths and metals, technology, skilled labor, manufacturing and construction, reduces the chances of “Dutch disease” (the idea
that disproportionate income from one sector causes the appreciation of a
country’s currency, leading to the weakening of other sectors and increased
long-term vulnerability). Instead, countries “specializing” in renewable
energy may actually end up with more diversiied and progressive economies than they would otherwise.
Finally, there is potential for a new resource curse, which would be less
associated with a country’s potential for renewables themselves than with
its position within the energy value chain and its possession of rare earths
23
18
In contrast to point source resources, the construction of large solar and wind farms (with
transmission lines) could require support from a wider range of stakeholders, depending on the
country’s land ownership patterns. There is certainly potential for valuable areas to be permitted
and exploited illegally or in contravention of international transparency norms (cf. EITI standards).
II. Mechanisms
and metals. As noted above, the rise in renewable energy will increase
dependence on advanced raw materials to build the machines to produce
solar PV panels, wind turbines, etc.—many of which require highly specialized manufacturing processes and rare earth elements concentrated
in particular countries. he production and sale of these elements, in a
renewable-energy intensive world, could carry signiicant rents, which may
in turn shape the development of domestic institutions in some places as
oil and gas did in the past.
D) Electric Grids
1)
Supergrids
“Supergrids” are multinational electricity grids. Supergrids were originally designed with one principal purpose: to enhance the reliability of
participating countries’ electric systems. In recent years several supergrids
have been proposed, with broader purposes. he Desertec project24, the
North Sea Ofshore Grid25 and the Asia Super Grid26 are all designed for
1) resource-sharing and 2) economies of scale.27 In these multinational
supergrids, countries lacking renewable natural resources import energy,
and resource-rich countries export energy to countries with high electricity prices. For instance, IRENA has found that Ukraine has a renewable
energy potential of 60 TWh/yr for wind power, and 38.2 TWh/yr for solar
power.28 In January 2017, Ukraine exported electricity worth USD 21.6
million to Hungary, Poland and Moldova, while importing electricity
worth USD 267,000 from Russia, USD 7,000 from Moldova and USD 4,000
24
DESERTEC. 2017. The Desertec Concept. http://www.desertec.org/the-concept
25
ENTSOE. 2017. The North Seas Countries’ Ofshore Grid Initiative (NSCOGI). https://www.entsoe.
eu/about-entso-e/system-development/the-north-seas-countries-ofshore-grid-initiative-nscogi/
Pages/default.aspx
26
Nobuo Tanaka: “Asia’s Tangled Power Lines: Ensure Energy Security by Building a Smarter Grid”,
Foreign Afairs, August 1 2012.
27
Ryan, Eamon. 2015. “The Power of a European Energy Union,” Project Syndicate, February 23.
https://www.project-syndicate.org/commentary/european-energy-union-by-eamon-ryan-2015-02;
28
IRENA, REMAP 2030: Renewable Energy Prospects for Ukraine (April 2015), https://www.irena.
org/remap/IRENA_REmap_Ukraine_paper_2015.pdf
The Geopolitics of Renewable Energy
19
from Belarus.29 Some proponents of supergrids argue that energy interdependency facilitated through supergrids can foster regional peace.30
However, there are many reasons why the rise of supergrids may have a
geopolitical Janus face. he central question is this: does the interdependence and cooperation necessary to build and facilitate a supergrid mean
actors become less likely to engage in various kinds of regional conlict? In
a supergrid region, a country may be able to use energy as a weapon, for
example by shutting of its supply to others. Before any project is inalized,
there are many geopolitical tensions that could arise. In the previous example with Ukraine and its neighboring nations, given geopolitical tensions in
the region the possibility of developing lexibility measures such as interconnectors to facilitate renewable energy development remains uncertain.
Another known tension that can arise is supergrid “shirking.” In order
to minimize the “energy weapon” threat, some actors will seek to reduce
reliance on the supergrid, for example through engaging in other bi- or
multi-lateral grid arrangements. Importer countries may also try to tie
the supergrid “free trade” agreement to other development issues, like
infrastructure inance, thereby increasing their individual (or bloc) inluence over exporter countries. Furthermore, if a supergrid is to be fueled
by renewables only, what happens to exporter countries’ non-renewable
resources in the ground and its “stranded assets?” Are they allowed to
continue using or exporting non-renewables to non-supergrid countries? Moreover, both importer and exporter countries will be interested
in bolstering security arrangements in the region. 31 Supergrids make all
participating countries equally vulnerable to security threats; a threat to
one country is a threat to all supergrid countries.32 Exporter countries
have their own various interests they will push for: who will pay for the
interconnectors? Who will maintain them? Will there be a local sourcing
20
29
Lilliestam, Johan, and Ellenbeck, Saskia. “Fostering Interdependence to Minimise Political Risks in
a European-North African Renewable Electricity Supergrid,” Green, Vol. 2 (2012), pp. 105-109; Yu,
Phelan. 2016.
30
“Tanaka Advocates Peacekeeping Through Energy in Asia,” Harvard Crimson, September 26. http://
www.thecrimson.com/article/2016/9/27/tanaka-advocates-energy-peacekeeping/
31
The Economist. 2017. “Electricity now lows across continents, courtesy of direct current,” January
14. http://www.economist.com/news/science-and-technology/21714325-transmitting-power-over-thousands-kilometres-requires-new-electricity.
32
Yu, Phelan. 2016. “Tanaka Advocates Peacekeeping Through Energy in Asia,” Harvard Crimson,
September 26. http://www.thecrimson.com/article/2016/9/27/tanaka-advocates-energy-peacekeeping/
II. Mechanisms
requirement? How will the supergrid contribute (e.g. through pooled
inancing) to expanding exporter countries’ own national grids? Such
potential areas of conlict raise questions of what institution regulates the
supergrid countries’ activities. How strong is that regulator, and who will
be the most powerful players in that institution?
An important part of the dynamic in such cases will be the asymmetry in
the interdependence of countries that are involved. In a way that is very
similar to pipeline politics, the inter-state politics of building, maintaining
and running a supergrid, how its exact locations are chosen and how the
questions listed above will be answered to a large extent will depend on the
geopolitical weight of the various participants.
hese factors will also play into the domestic politics of countries. National
politicians would need a “political sell” that explains why their country
cannot rely on domestic production of renewables, and why its own economy should be put in jeopardy owing to a luctuation or cutting of access
someplace else on the supergrid.33 here is also a clear appetite for “ofgrid,” local energy production: what becomes of this when a supergrid is
built?
2)
Micro-Grids and Of-Grid Solutions
While it is possible that a world reliant on renewable energy would be
based on supergrids, developments might also go in the opposite direction, towards micro-grids, of-grid solutions and greater decentralization.34
Such a development would involve reduced interdependency between
states. hus on the one hand, there should logically be reduced geopolitical
competition over fossil fuel resources. On the other hand, reduced interdependency might also mean reduced incentives to avoid conlict due to
dependency on fossil fuel resources. For example, in the current conlict
between the Russia and the West over Ukraine, the EU has ensured that
33
Oxford Analytica, 2011. “AFRICA: Solar power industry grows more competitive,” Oxford Analytica Daily Brief Service, September 12. http://search.proquest.com.ezp-prod1.hul.harvard.edu/
docview/888387001/.
34
Overland, I. (2016) “Energy: The Missing Link in Globalization,” Energy Research and Social Science,
14, pp. 122–130, http://www.sciencedirect.com/science/article/pii/S2214629616300093
The Geopolitics of Renewable Energy
21
natural gas is largely exempt from sanctions—in the process limiting the
impact of sanctions and the level of Russian-Western conlict.35 If the EU
were better supplied with solar and wind power and no longer so dependent on Russian gas it is less likely that it would have kept sanctions away
from natural gas.
It is also possible that the two opposing developments might take place at
the same time, with supergrids in some places and proliferation of locally
produced energy and micro-grids in other places. What geopolitical trend
would be likely to accompany such a scenario is a complex question.
Of- and micro-grid solutions that can function independently from larger
national or regional grids are becoming increasingly popular as a way to
provide broader energy access in poor and remote areas in developing
countries with underdeveloped national grids. If energy storage technology
improves, they could also become widespread in developed parts of the
world. Such of- and micro-grid solutions, however, also have signiicant
disruptive potential for geopolitics, by signiicantly weakening the control
of centralized government in several ways.
First, of-grid solutions are not only a way to signiicantly enlarge broader
energy access in poor areas, but also to create greater options for a decentralized access to education, health, and ultimately wealth. As a result,
these services, which are oten provided by centralized governments—
and oten used by them for political leverage—will become increasingly
regionalized and localized. his could challenge the social contract of
many societies. hus, citizens who provide for their own energy and have
increased access to education, health and wealth independently of government programs may feel emboldened to ask for more political participation
or in some extreme cases, even promote secessionist tendencies.
Second, micro- and of-grid solutions could challenge the revenue models
of many governments, particularly those reliant on royalties and other
centralized sources of income. he decentralization of renewables might
35
22
Fjaertoft, D. and I. Overland (2015) “Financial Sanctions Impact Russian Oil, Equipment Export
Ban’s Efects Limited,” Oil and Gas Journal, Vol. 113, No. 8, pp. 66–72, https://www.academia.
edu/15717548/Sanctions_Impact_Russian_Oil; I. Overland (2017) “The Hunter Becomes the Hunted: Gazprom Encounters EU Regulation”, in S. Andersen, A. Goldthau and N. Sitter (eds) Energy
Union: Europe’s New Liberal Mercantilism?, Basingstoke: Palgrave MacMillan, pp. 115-130.
II. Mechanisms
incentivize better tax collection systems due to the small, fragmented revenue streams they produce, but the capacity for consumers to move of-grid
(hence out of the tax system) is a risk that states should anticipate.36
hirdly, centralized governments will lose much of their ability to pressure
insurgent or secessionist regions that strive for more autonomy into submission by controlling the supply or price of energy. One such example are
events in Yemen in 2014, when a surge in of-grid energy sources allowed
many individuals and communities to keep power supply stable even as the
capital descended into political chaos. Decentralized electricity production based on renewables could also reduce the ramiications of political
turmoil in speciic regions (when compared to fossil fuels dependence)
since such events would only undermine a small part of total energy
production.37
3)
Cyber Risks
For several reasons, renewable energy technologies may be more vulnerable to cyber attacks than conventional energy systems. For other reasons,
renewable energy technologies may be less vulnerable to cyber attacks. he
balance between these will depend on number of factors.
As a starting point, renewable energy technologies have the same basic
cyber vulnerabilities as any other industry controlled by Supervisory Control and Data Acquisition Systems (SCADA). Critical infrastructure and
the computer systems used to manage energy generation and distribution
must be protected from cyber intrusion and attack to ensure continuity of
service.
However to the extent that large-scale deployment of renewable energy is
associated with development of supergrids, there could be increased vulnerability to cyber-attacks. First, the cyber vulnerabilities of the weakest
36
Kolstad, I. and Wiig, A. (2009) “Is transparency the key to reducing corruption in resource-rich
countries?” World Development 37(3): 521-532.
37
Casertano, Stefano (2012) Risiken neuer Energie—Konlikte durch erneuerbare Energien und
Klimaschutz (Risks of New Energy—Risks Posed by Renewable Energy and Climate Protection).
Brandenburg Institute for Society and Security (BIGS), No. 9.
The Geopolitics of Renewable Energy
23
country on the supergrid are likely inherited by all other countries reliant
upon that grid. Second, a cyber-attack on one country may impact other
countries reliant upon the same supergrid. Finally, a skilled cyber attacker
might be able to use the interconnected nature of the supergrid to selectively generate mistrust or create conlict between nations reliant upon
the same infrastructure. If one nation, among the many that rely on that
supergrid, inds itself without power, it may accuse a neighbor of being
responsible for the shortage, especially in the face of limited or confusing
evidence.
In addition, some renewable energy sources rely on batteries for periods
of limited energy generation. hese systems rely on computers to manage,
charge and discharge the batteries, which has thermal side efects. If
intentionally mismanaged as a result of a cyber intrusion, a battery ire is
possible, which presents signiicant issues in the form of challenging ire
suppression, high cost damage to infrastructure and release of toxins.
However, to the extent that renewable energy technologies are part of
micro-grids or of-grid solutions, they might reduce vulnerability to cyber
attack. Of-grid solutions might survive an attack on the grid, providing
power in emergency situations. Even micro-grids that are not fully islanded
from the main grid could provide backup power in the event large central
generation facilities were disabled by a cyber attack.
24
II. Mechanisms
E) Reduced Oil and Gas Demand
Increasing deployment of solar and wind power could lead to signiicantly
reduced oil and gas demand. However, this is by no means automatic or
guaranteed. First, solar and wind power produce electricity, yet only 5% of
global electricity generation comes from oil and 22% comes from natural
gas.38 In many places, solar and wind power may be more likely to displace
coal than oil and gas. Moreover, solar and wind power cannot displace oil
in the transportation sector unless they are accompanied by widespread
deployment of electric vehicles. Finally, natural gas-ired generation is
one of the leading tools for managing the intermittency of solar and wind
power, so in some places the technologies may grow together.
However to the extent that solar and wind power, together with biofuels,
reduce demand for oil and gas, there could be signiicant geopolitical consequences. We explore these below.
1)
Impacts on Producers
A world in which renewables become a dominant source of energy would
involve some obvious challenges for oil and gas producers, particularly
those which have long relied heavily on oil and gas exports. he sharp
oil price decline of the past several years provides an example of those
challenges. Oil producers including Saudi Arabia, Russia and Venezuela
have faced signiicant iscal challenges from declining oil revenues. In the
United States, the oil price drop has created signiicant unemployment
in oil producing regions. he renewable energy industry certainly has
potential to ill that gap, but with inevitable time lags and geographical
adjustments that may prove disruptive to labor markets. A further question
to consider is the position of oil majors vis-à-vis producer and consumer
states.
38
http://www.tsp-data-portal.org/Breakdown-of-Electricity-Generation-by-Energy-Source#tspQvChart
The Geopolitics of Renewable Energy
25
For oil and gas producers, a signiicant shit toward renewables could have
two possible efects. First, the decline in revenue generated from fossil
fuel energy exports can and has provided a huge impetus for political and
economic reform and for the diversiication of the economies of these
countries. Second, a decline in these revenues, if not spurring economic
and other reforms, could create signiicant short-term strains and have
adverse implications for political stability. For example, some current oil
and gas producers, such as Russia or Nigeria, may face both relative losses
vis-à-vis fast-advancing competitors and absolute declines in their growth
rate. In these countries and elsewhere, the failure of government to maintain spending could lead some to question the government’s authority and
lead to pressures on regime survival.
he relationship between renewables, low oil prices and the so-called
decline of the rentier state is far from clear, and may not be as automatic as
oten described. In some cases, lower oil prices have spurred serious eforts
at economic reform in Saudi Arabia, the UAE, Malaysia and Indonesia.
Yet in other producing countries, real eforts to diversify have not been
observed, including Russia, Iraq, Venezuela, Libya, Nigeria and Angola. In
Azerbaijan’s case, the state has invested heavily in strengthening its security
apparatus over the course of the price decline. Another group of states to
consider is those with signiicant undeveloped oil and gas resources that
may ind production pathways close of as the energy transition progresses.
Regardless of whether eventual diminished demand for oil, gas, and coal
lead to successful reform and diversiication, or severe strains, or regime
stabilization, a transformed energy mix would afect the relationships
between and among countries. his could potentially afect the relative
balance of power between countries, increasing the relevance of Graham
Allison’s hucydides Trap. (Allison’s theory postulates that big shits in the
balance of power oten spurs global conlict; even simply the fear of the rise
of a new power at the expense of an oil producer can be enough to spur
conlict.)
Finally, one cannot conclude deinitively that a world in which renewable
energy is dominant is necessarily one in which the region of the Middle
East loses inluence or importance. Many scenarios anticipate that with less
26
II. Mechanisms
demand for oil, high cost resources will no longer be commercial to be produced. As a result, the world’s remaining oil production will be concentrated
in low-cost regions of the world, most notably the Middle East. Such a concentration could well bring new geopolitical power to that part of the world.
2)
Impacts on Consumers
At the same time, countries formerly dependent on imported fossil fuels could
see an alleviation of this burden and a consequent augmentation in domestic
and international political power, or at least freedom. IRENA’s “Renewable Energy Beneits” shows that the economic beneits of a transition to
renewables—though overwhelmingly positive for most countries—are oten
unequally distributed. Nevertheless, many of the countries to date that have
made signiicant progress in scaling up the deployment of renewables, including Morocco, Chile, Jordan and several island states, are big importers of fossil
fuels. he development of renewable indigenous energy sources is a game
changer for these countries and others in terms of energy security.
REmap 2030 inds that USD 275-315 billion p.a. in fossil fuel imports
could be reduced in the G7 countries by 2030 and highlights the important
role renewable energy can play in improving “the robustness of the energy
system to external energy security shocks by exploiting economic, domestic renewable energy sources for electricity and to meet energy demand in
the transport, industry and residential and commercial sectors.” Related,
the socio-economic beneits associated with the renewable energy sector
from job creation, drivers of innovation, and in some cases enhancing the
access to critical resources such as food and water, are also important to
highlight. hese serve as opportunities for countries with a high penetration of renewables to demonstrate domestic and international political
strength, while also creating incentives for countries dependent on fossil
fuel exports to take steps toward more sustainable energy diversiication.
Volatility in crude oil and gas prices is a major consideration for consumers, adding a signiicant premium on investment in either commodity and
uncertainty. As national climate policies evolve, policy uncertainty is likely
to be a signiicant factor.
The Geopolitics of Renewable Energy
27
F)
Avoided Climate Change
Large-scale deployment of renewable energy can help mitigate climate
change by reducing greenhouse gas emissions below levels that they might
otherwise achieve. his, in turn, would avoid some of the geopolitical consequences of a changing climate.
In recent years, experts from a range of disciplines have devoted increased
attention to the potential geopolitical consequences of climate change,
including those experts engaged in national security planning and defense
in countries around the globe.39 here has been increasing concern that
accelerating climate change will exacerbate resource scarcity (particularly water and food insecurity), lead to increases in the incidence and
severity of sudden-onset natural disasters, and drive involuntary internal
displacement and cross-border migration, especially among vulnerable
populations. Any of these factors could lead to political instability, intraand inter-state violence and even state failure. Attribution to climate
change of speciic cases of severe weather or even long-lasting droughts
is a source of considerable dispute in the scientiic community, but many
researchers are prepared to point to climate change as the clear underlying cause of large-scale human privation. To date, the most emblematic
such case has been the Syrian civil war. he scientiic literature shows that
the historic drought from 2006 to 2011 drove rural-to-urban migration
throughout the country.40 Subsequently, newly-arrived migrants formed
a core of the anti-Assad movement in the early days of the Arab Spring.41
his is not to say that climate change alone caused the uprising in Syria,
28
39
See, inter alia, National Security Council (2015). National Security Strategy. National Security
Strategy Archive. http://nssarchive.us/national-security-strategy-2015/, accessed 19 February
2017; G7 (2015). A New Climate for Peace: Taking Action on Climate and Fragility Risks. G7 https://
www.newclimateforpeace.org/#report-top, accessed 19 February 2017; Australian Department of
Defence (2016). Defence White Paper. Australian Department of Defense, http://www.defence.gov.
au/WhitePaper/Docs/2016-Defence-White-Paper.pdf, accessed 19 February 2017.
40
Colin P. Kelley et. al. (2015) Climate change in the Fertile Crescent and implications of the recent
Syrian drought. Proceedings of the National Academy of Sciences 112.11, http://www.pnas.org/content/112/11/3241.abstract; Peter H. Gleick, “Water, Drought, Climate Change, and Conlict in Syria,”
1 July 2014, American Meterorological Society, http://journals.ametsoc.org/doi/abs/10.1175/
WCAS-D-13-00059.1; Benjamin Cook, et al (4 March 2016), “Spatiotemporal drought variability in
the Mediterranean over the last 900 years”, Journal of Geophysical Research, http://onlinelibrary.
wiley.com/doi/10.1002/2015JD023929/full
41
Caitlin E. Werrell and Francesco Femia (editors), The Arab Spring and Climate Change: A Climate
and Security Correlations Series, https://climateandsecurity.iles.wordpress.com/2012/04/climatechangearabspring-ccs-cap-stimson.pdf; John Wendle, “The Ominous Story of Syria’s Climate
Refugees,” Scientiic American, 17 Dec 2015 https://www.scientiicamerican.com/article/ominous-story-of-syria-climate-refugees/
II. Mechanisms
which arose from a wide variety of factors, but that the complexion of the
conlict would likely be diferent had it not been for those climate change
impacts.42
As a result of the increased focus on climate change and national security,
the imperative for international eforts to reduce greenhouse gas emissions
as much possible (the Paris Agreement calls for policies and measures suficient to limit climate change to “well below” 2 degrees Celsius) takes on
an important conlict prevention dimension. Strategies to greatly expand
the amount of low and-zero carbon energy sources could reduce conlict
risk. Such calculations would likely become an increasingly important part
of state strategies in international climate negotiations. In fact, it is reasonable to expect that champions of a high-renewables or other low-emissions
future could over time enjoy signiicant sot power and credibility advantages over states not prepared to respond adequately to the threat of climate
change.
hus, to the extent that high penetration of renewables leads to a reduction in greenhouse gas emissions, the probability of conlict and instability
could fall, or could fail to rise as much as they might otherwise do. Regardless of the challenges of “attribution” today, reducing greenhouse gas
emissions could help avoid runaway climate change, which would make
conlict prevention substantially more diicult.43
Renewables themselves also have the potential to be an important source of
sustainable development, including in countries badly needing to alleviate
energy poverty. Renewable energy development can contribute directly
or indirectly to achieving all the Sustainable Development Goals (SDGs).
As analysis from IRENA notes, “Renewables contribute to SDGs aimed at
environmental sustainability by mitigating the local and global environmental impacts of energy consumption. hey support human development
by facilitating access to basic services, improving human health and supporting income generation activities. Finally, renewables also contribute to
sustainable economic growth by generating economic beneits such as new
42
Colin P. Kelley et. al. (2015) at note 40.
43
World Bank, Turn Down the Head: Confronting a New Climate Normal, (2014) http://hdl.handle.
net/10986/20595
The Geopolitics of Renewable Energy
29
jobs and industries.”44 he case for renewables, in turn, can be bolstered by
important—but politically complex—policy choices. Most signiicantly, the
removal of economically-ineicient subsidies supporting the development
and consumption of fossil fuels would create a level playing ield in which
renewable energy projects could thrive, bringing all the attendant climate
and economic beneits.
One region where wide-scale deployment of renewable energy may have
especially signiicant geopolitical consequences is Africa. Few if any parts
of our world are more vulnerable to climate change and its attendant risks,
including mass migration and conlict. In Africa, the impetus for poverty
alleviation and economic development intersects with the need to increase
resilience against a variety of potential climate change impacts.45 Furthermore many African nations have not made fossil fuel legacy investments
and can thus avoid carbon “lock-in.” States on the continent enjoy several
opportunities for accelerating the clean energy transition. An Overseas
Development Institute report on the low-carbon transition cites sub-Saharan Africa’s solar radiation potential.46 Many states with robust oicial
development programs have focused on bridging energy gaps in Africa
and that focus is likely to continue with the implementation of the Paris
Agreement.
One important challenge to be recognized is that a sense of urgency over
the response to climate change may not only stimulate the efective use of
renewable energy and other low-carbon energy systems. Some may call for
geoengineering solutions out of a belief that we need to apply emergency
measures to limit climate change. his could lead to challenging—perhaps
intractable—policy debates, with adherents asserting that geoengineering
will help buy time with less aggregate climate change, and opponents arguing that it will introduce still further uncertainty in our climate system.
30
44
IRENA, Rethinking energy 2017, p. 95-96.
45
African Development Bank (2011), “Low Carbon Development and Energy Access for Africa,”
ADB, accessed 1 March 2017, https://www.afdb.org/en/cop17/programme/low-carbon-development-and-energy-access-for-africa/
46
James Ryan Hogarth, Caroline Haywood, and Shelagh Whitley (2015), Low-carbon development in
sub-Saharan Africa: 20 cross-sector transitions, ODI, accessed 1 March 2017, https://www.odi.org/
sites/odi.org.uk/iles/odi-assets/publications-opinion-iles/9878.pdf.
II. Mechanisms
G) Access to Sustainable Energy
Access to modern forms of energy is one of the key preconditions for
achieving sustainable development. Yet, some 1.06 billion people worldwide still have no access to electricity and some 3.04 billion people still do
not have access to clean cooking.47 he situation is particularly critical in
sub-Saharan Africa and developing Asia, the two regions characterized by
the highest levels of energy poverty. Africa, for example, represents 16%
of the global population but less than 6% of the global energy demand.48
Widespread energy poverty stands in stark contrast to large energy
reserves in Africa, including oil, natural gas, coal and various sources of
renewable energy.49
he implications of energy poverty are manifold.50 First and foremost they
include adverse efects on human health, economic development, employment opportunities and the environment. Access to energy is also essential
for the provision of education and the participation in the internet and
more broadly telecommunication services. As such there are at least two
aspects to take into account when assessing geopolitical implications. First,
energy poverty has been described as a “threat multiplier”, which means
that it can enhance already existing challenges and lead to political instability and unrest.51 Second, poverty and instability are two crucial push
factors leading to an increase in global migratory pressures. It follows that
by providing sustainable livelihoods, access to modern energy sources can
reduce both the risk of internal unrest and the need for people to emigrate
from poverty. his energy-security-nexus has not received suicient attention in research and policy and should be further assessed in more detail.
Fossil fuels are likely to continue to play a role in providing energy access,
especially where on-grid generation is feasible. However, renewable energy
sources have signiicant potential for providing sustainable and reliable
services to the poor. In particular, decentralized renewable energy systems
47
GTF (2017) Global Tracking Framework. http://gtf.esmap.org/data/iles/download-documents/
eegp17-01_gtf_full_report_for_web_0511.pdf
48
IEA (2016), World Energy Outlook 2016, IEA/OECD, Paris.
49
BP (2016), BP Statistical Review of World Energy, June 2016.
50
Behrens, A. et al. (2012), Escaping the Vicious Cycle of Poverty: Towards Universal Access to Energy
in Developing Countries, CEPS Working Document No. 363, March 2012, Brussels
51
Bazilian, M. D. (2015), Power to the Poor, Foreign Afairs, Volume 94, Number 2, March/April 2015.
The Geopolitics of Renewable Energy
31
such as hydro, solar, wind and modern biomass can provide the opportunity for clean and cost-efective electricity and heat generation especially in
rural of-grid areas. According to UNEP, 70% of people without access to
electricity can be reached through such decentralized of-grid solutions.52
hese kinds of small-scale, mini-grid and of-grid solutions in sparsely
populated rural areas oten turn out to be more successful and cheaper
than providing large-scale and on-grid solutions.53 In this way, renewables can provide for cheaper alternatives and avoid an unnecessary rise
in greenhouse gas emissions and the related “carbon lock-in”. In addition,
they can provide direct rural employment opportunities and reduce urbanization pressures.
All of this is also linked to the achievement of the Sustainable Development
Goals (SDGs). SDG7 calls for universal access to afordable, reliable, sustainable and modern energy services and can be considered as an “enabling
factor” for sustainable development due to its links with progress towards
other SDGs. he SE4All initiative lists some of the positive impacts of
energy access on “eradicating poverty, increasing food production, providing clean water, improving public health, enhancing education, creating
economic opportunity, and empowering women”.54 he geopolitical
impacts of access to energy are thus important, as it contributes to lasting
solutions to instability and conlict.
32
52
UNDP (2016), UNDP Support to the Implementation of Sustainable Development Goal 7, http://
www.undp.org/content/undp/en/home/librarypage/sustainable-development-goals/undp-support-to-the-implementation-of-the-2030-agenda/
53
Behrens, A. et al. (2012), Escaping the Vicious Cycle of Poverty: Towards Universal Access to Energy
in Developing Countries, CEPS Working Document No. 363, March 2012, Brussels
54
SE4All (2014), SE4All Energy Access Committee Report, 20 August 2014, http://www.se4all.org/
sites/default/iles/l/2014/12/Energy-Access-Committee-Report.pdf
II. Mechanisms
III. Uncertainties
Increased use of renewable energy may bring greater predictability in some
ways, but greater uncertainty in others. Oil markets are notoriously unpredictable, but in some ways renewable energy may bring new uncertainties
even compared to oil. First, although the oil price is inherently diicult
to forecast and is afected by numerous exogenous factors, it is at least
dependent on international oil markets, an established and familiar system
that has existed for a long time. Second, similar to most other commodity
markets, the oil trade is subject to cycles of oversupply and undersupply;
highs are ultimately followed by lows, and lows by highs. With the current
growth of renewable energy, we are instead dealing with the disruption of
old markets and the creation of new ones, which are not known yet. hird,
while there is considerable technological uncertainty in the petroleum
sector—as exempliied by the unexpected improvements in fracking (and
in the future, possibly the use of microwaves to exploit oil shale or technologies for extracting gas hydrates)—the technological uncertainty of
renewable energy is signiicantly greater. his is because it involves several
entirely separate types of energy sources, and energy generation, transportation and storage.
The Geopolitics of Renewable Energy
33
IV. Options for Further Analysis
here are several options for further analysis of the geopolitical consequences of a transition to renewable energy:
Scenario building
Foresight methodology was developed by Shell to deal with the uncertainties in the petroleum sector. his approach makes some sense when it is
not possible to make more accurate predictions, and its main purpose is to
raise consciousness about the range of possible outcomes, the interaction
between diferent factors and ways in which one might position oneself
for the future or try to shape it. Despite its lack of rigor, this approach
has become the default for handling large-scale, complex and unpredictable systems and processes, especially when large inancial values are at
stake. Foresight scenarios are oten most useful to those who participate
in their making, while they can be diicult to communicate to an external
audience.
Modeling
For some academics and policy makers, formal modeling of the global
energy system and its transformation would be preferable to the subjectivity of foresight methodology. However, it is diicult to model a situation
where a system is not only afected by some factors, but the entire system is
transformed into something else. It is also generally more diicult to model
politics than economics, and availability of relevant data may be a significant challenge. An attempt at modeling the geopolitical consequences of
a transition to renewable energy would require relevant competence and
a large amount of funding, and might be most appropriate for an international inancial institution.
34
IV. Options for Further Analysis
Index of geopolitical vulnerability
It would be possible to create an index to map the geopolitical sensitivity
of diferent countries to a full makeover of the global energy system. his
would have the advantage of being more rigorous than foresight scenario
building, while also being more feasible than modeling. Such an index
could be based on indicators drawn from secondary data, for example:
•
Business climate for renewable energy
•
Innovation capacity
•
Governance capacity
•
Renewable energy resource potential (wind, solar, hydro, geo, bio)
•
Trade surplus/deicit related to hydrocarbons, consumption, reserves
Geographically based review
It would be possible to do a more qualitative, geographically based review
of the possible consequences of a transition to renewable energy, country-by-country, or region-by-region. Such a review would have to focus on
selected countries and regions, for example:
•
African oil producers (Angola, Nigeria)
•
East Asia (China, Japan, Korea)
•
Latin American oil producers (Brazil, Colombia, Mexico, Venezuela)
•
EU
•
MENA oil and gas producers
•
Post-Soviet oil and gas producers (Azerbaijan, Kazakhstan, Russia,
Turkmenistan)
•
USA
•
Major industrialized oil and gas exporters (Canada, Netherlands,
Norway)
The Geopolitics of Renewable Energy
35
If one were to select two highly relevant geographical areas to focus on,
they might be Russia and MENA. Russia because it is the only (former/
potential) great power that is a major oil and gas exporter; MENA because
it has such a high concentration of petroleum resources, such a long history of foreign intervention and such great solar power potential.
Such an analysis could also attempt to identify signiicant dyadic trade relationships, both those that exist in the current energy system (and which
might fade with a transition to renewable energy) and those that might
emerge in a future energy system dominated by renewable energy.
•
EU—Russia
•
EU—Maghreb
•
Russia—post-Soviet neighbors
•
Saudi Arabia—US
•
Saudi Arabia—Iran
•
China—Gulf
•
China—Russia
Analytical distinctions
Cutting across the analytical design options outlined above are several different analytical distinctions. hese could be used to structure the analysis,
or choices could be made to focus on some and exclude others.
36
•
Changes in the energy system itself versus geopolitical consequences of
these changes.
•
Fading of old versus emergence of new energy system.
•
Risks versus beneits.
•
Transition period versus end state.
•
Shits in geopolitical power versus interests versus alliances.
•
Winners versus losers.
IV. Options for Further Analysis
•
Typological distinctions (oil exporters, oil importers, major coal producers, countries with large renewable energy resources, low and high
governance capacity).
•
Assumptions versus uncertainties.
V. Conclusion
It has long been evident to strategists and policymakers that energy is a
signiicant driver of foreign afairs. For nearly a century, the intersection
between energy and geopolitics has centered around fossil fuels. As this
preliminary paper suggests, the importance of renewables as a signiicantly
growing portion of the global energy mix could have signiicant implications for geopolitics as well. his will include both opportunities and
challenges.
Having highlighted the considerable uncertainty involved in anticipating
how a transition to renewable energy will afect the political situation in
the world, it is worth noting that uncertainty does not necessarily mean
conlict. here are reasons to believe that at least in the long term, a global
energy system dominated by renewable energy will be more stable, peaceful and just than one dominated by fossil fuels and nuclear technology.
he geopolitical path towards this end state is, however, unknown. Further developing the ideas above, as well as new ones not set forth in this
paper, is the irst step in helping the world anticipate the new geopolitics of
renewable energy.
The Geopolitics of Renewable Energy
37
Annex I: Literature review
Oil and gas have long been the main object of geopolitical analysis. Unconventional oil and gas developments led to a lurry of analysis of the possible
impacts on oil and gas markets, as well as political and geopolitical consequences. Although unconventional oil and gas has had a dramatic efect
on supply and demand in the global oil market and on US import dependency, these efects are still shits within the current energy system. A
large-scale transition to renewable energy would likely be far more disruptive, but paradoxically this prospect has received much less attention. his
diference between the attention to the geopolitics of oil and the geopolitics
of renewable energy is illustrated supericially in Table 1 with some results
of queries in ISI Web of Science, Google Books and Google Scholar.
Table 1. Searches for geopolitics, oil and renewable energy
(January 9th, 2017)
Search string A:
“geopolitics AND oil”
Search string B:
“geopolitics AND
renewable energy”
Ratio, search
string B / A
ISI Web of
Science
132
12
0.09
Google Books
29 600
1 840
0.06
Google Scholar
48 000
23 000
0.48
here is a literature on the geopolitics of climate change, but this is
a broader issue and only sometimes relevant for the geopolitics of a
transition to renewable energy. And much of this literature ignores the geopolitics of the replacement of fossil fuels by renewable energy. For example,
a special issue of the journal Climate Policy from 2013 on the geopolitics of
climate change pays scant attention to the question of how climate policy
will afect petroleum exporters and importers or oil companies (Streck and
Terhalle, 2013). he topic has also been ignored in other analyses of geopolitics and climate change that might have been expected to cover it (e.g.
Falkner, 2010).
38
Annex I: Literature Review
In sum, it is paradoxical how little analysis has been done of the geopolitical consequences of renewable energy compared to the geopolitics of
oil. However, as Table 1 shows, it would also be erroneous to claim that no
research has been done on the geopolitics of renewable energy. In the following sections we provide an overview of the existing research.
Overview
Researchers from Germany and the Netherlands have taken the lead in
examining the geopolitics of renewable energy. his may be due to the
emphasis on a transition to renewable energy in the domestic energy policies of these two countries, as this is likely to raise both consciousness
about the potential consequences and lead to funding opportunities. Scholars and experts based at German research institutes and think tanks and
other institutions dealing with energy issues pioneered the ield: Krewitt
et al. (2009), Westphal (2011), Casertano (2012), Westphal and Droege
(2015) Huebner (2016), Strunz and Gawel (2016). hey were later followed
by scholars based in the Netherlands who have done some of the most
substantial work to date: Bosman and Scholten (2013), De Ridder (2013),
Sweijs et al. (2014), Scholten (2016).
he most thorough research on the renewable energy–geopolitics nexus
today is that by Criekemans (2011), Scholten and Bosman (2013), Sweijs et
al. (2014) and Paltsev (2016). A reader interested in getting an overview of
the central issues might turn to those works.
Much of the existing research in this ield is in the form of gray literature,
i.e. working, papers, reports, dissertations, etc. he work that has been
published by proper journals and book publishers is spread among many
diferent publishing outlets, suggesting that so far no journals or book publishers have focused on this issue-area over time.
In the next sections we survey the literature in thematic clusters.
The Geopolitics of Renewable Energy
39
Geopolitical beneits
Peters (2002) was one of the irst scholars who argued that developing
renewable energy would lead to a more equitable energy distribution and
lower geopolitical tensions. hus Peters was a pioneer in this ield, but it
should also be noted that given the fast pace of change in the petroleum
and renewable energy sectors, as well as in climate policy, any literature
more than a few years old is likely outdated.
Verrastro et al. (2010) and Johansson (2013) argue that, contrary to the
assumptions of actors who are concerned about intermittency, renewable energy may strengthen energy security while at the same time it will
inevitably lead to the emergence of new interdependencies between the
countries. According to Kostyuk et al. (2012), renewable energy expansion is likely to lessen the role of geopolitics in international relations. In
their view, renewable energy will increase the availability of energy and
thus make it less prone to political tension. hey conclude that the world
is presently at an important crossroads in terms of the future energy path.
Hoggert (2014) notes that small-scale photovoltaics (and nuclear power)
technologies are likely to promote a secure low carbon transition with
reduced geopolitical risks. Krewitt et al. (2009: 23) indicate that the creation of international solar energy partnerships would have geopolitical
advantages because they could “reduce economic imbalances between the
North and the South and create global markets for future-oriented energy
technologies without having to fear conlicts over scarce resources.”
Ministerio de la Defensa (2015: 11–12) argues that a world in which
renewables are the main sources of energy will allow a high degree of
energy self-suiciency in all countries, shiting the focus from securing an
external supply of fossil fuels to managing the internal supply of renewable
energy. According to Casertano (2012), decentralized electricity production based on renewable energy can greatly reduce the risks compared to
fossil fuels because local events can only undermine a small part of total
energy production. Renewables are less geographically concentrated than
traditional energy sources, making it diicult for individual countries to
control or limit the energy supply and manipulate the market price.
40
Annex I: Literature Review
Sweijs et al. (2014: 73) note that
… the pathway to a renewable energy transition on a global
scale is not only a story of painful adjustment and social unrest.
If extractive rentier regimes in countries highly dependent on
fossil fuel exports are toppled, it could pave the way towards
more inclusive forms of government, provided there is enough
‘critical mass’ among the general population. his could open
the door towards greater democratization in rentier states. In
this sense renewable energy can act as a beacon of opportunity
for impoverished nations whose economies thrive on a single
commodity and who are ruled by secretive, non-accountable,
extractive regimes.
Geopolitical downsides
Other authors note that energy transition generates new types of conlicts
and that renewable energy may take over the role that has been played by
fossil fuels and become a driver of new geopolitical tensions in its own
right (Sujatha 2013; Laird 2013). Dirmoser (2007) notes that the increased
use of renewable energy and energy eiciency had made little impact on
energy security yet. However, the picture may look diferent now.
In case of a large-scale renewable energy production and transportation
across borders in the form of electricity (rather than for example hydrogen), the principle of territorial control will be similar to that for oil and
gas pipelines. Potential renewable energy exptoring countries like Algeria,
Mexico or Morocco, or transit countries, or actors such as the Islamic State,
could still try to leverage their geographical position and in case of conlict
they could threaten to interrupt electricity supplies.
Various scholars argue speciically that the transition phase between
the old energy system(s) and one dominated by renewable energy poses
numerous geopolitical risks (Rothkopf 2009; Westphal and Droege 2015;
Westphal 2011). For Westphal and Droege 2015), the metamorphosing
The Geopolitics of Renewable Energy
41
global energy mix will bring more diversity, but also less security. Paltsev
(2016) argues that supply and demand for energy will remain an important factor inluencing the global balance of power in the future. Rothkopf
(2009: 1) argues that while energy transition will eliminate some conventional security risks, other new risks will emerge and geopolitical tensions
will intensify. He notes that the energy transition causes instability and that
while oil wars are likely to come to an end, “…there will be new types of
conlicts, controversies, and unwelcome surprises in our future (including
perhaps a last wave of oil wars as some of the more fragile petrocracies
decline).” He concludes that the decline of the petrostates will have complex consequences.
Vulnerable states
Mecklin (2016) notes that transition to a global energy system dominated
by renewable energy will create new geopolitical winners and losers. De
Ridder (2013) notes that the main losers of the new geopolitics of minerals
for renewable energy are the resource-poor countries of the developing
world which have limited inancial resources available to purchase new
technologies. Numerous studies explore risks related to stranded fossil
fuel assets and assess the imperative for divestment (Caldecott et al. 2015a;
Caldecott et al. 2015b; Ansar et al. 2013; Generation Foundation 2013;
OECD 2015; Caldecott et al. 2014; Carbon Tracker Initiative 2013). Except
for Rothkopf (2009), Sweijs et al. (2014) and Hache (2016), this literature is
however focused on companies and inancial risks for investors rather than
the power and survival of states and is thus not always directly relevant for
geopolitics.
Table 2 summarizes the work by Sweijs et al. (2014) on the short-,
medium- and long-term impacts of energy transition on international
security dynamics. We should note that Sweijs et al. focus more on the
end state of a transition to renewable energy and premise that the whole
world adopts more renewable energy, while acknowledging that the path to
increased renewable energy “is likely to be bumpy” (Sweijs et al 2014: 15).
42
Annex I: Literature Review
Table 2. Impact assessment of energy transition on global
security dynamics
Drivers
Security
implications
Examples
Short- and
medium-term
impact
Long-term
impact
Positive impact
on overall
energy-related
conlict worldwide if rest
of world also
makes transition
to renewable
energy
Structural
inequalities
reduced by EU
renewables
policy
More fossil fuels
resources available for rest of
the world
More fuels to
burgeoning
economies in
Asia and Africa
EU: gradually
less need to
be involved in
international
disputes, but
international
tensions over
energy could still
increase
Developing and
accessing new
resources
Less pressure
to secure new
resources of- or
onshore
Less tensions
in South China
Sea, Arctic Sea
Tensions concerning access
to new resources
could increase if
demand goes up
Tensions could
decrease if
supply outstrips
demand
Energy as
a coercive
instrument
Energy will be
less useful as
stick or carrot
Russia,
Gulf States,
Venezuela
No price
decreases
expected now,
energy as
coercive element
remains useful
Should prices
decrease, energy
less useful to
coerce other
countries
Source: Sweijs et al. (2014: 60).
Sweijs et al. (2014) also analyze the degree of dependency and vulnerability
of diferent countries to the EU energy transition and conclude that the following countries are the most exposed to vulnerability:
•
Russia (most exposed)
•
Algeria
•
Egypt
•
Qatar
•
Saudi Arabia
•
Kazakhstan
•
Libya (least exposed out of these countries)
Table 3 lists the risks and impact of the energy transition on security
dynamics in rentier states. In addition to the impact of the EU’s energy
transition, transitions in major non-European importing countries such
as China, India, and the US can be expected to have a signiicant efect
The Geopolitics of Renewable Energy
43
on other countries. he rise of shale gas and oil in the US had a powerful impact on US oil imports and on natural gas and especially oil prices
around the world. A transition to renewable energy in the US might have
an even greater impact.
Table 3. Impact assessment of EU energy transition on rentier states
Drivers
Lower demand
for fossil fuels in
Europe
Lower attractiveness to establish
access to and
permanent control over
oil and gas
resources
Downward pressure on oil price
Examples
Short- and
medium-term
impact
Long-term
impact
Russia, Algeria
and Libya lose a
signi cant share
of their export
revenues
Erosion of
government in
Algeria, Libya,
Russia. Risk of
social unrest.
Other exporters
may limit efects
by rerouting
exports to
emerging
economies.
Erosion of
government in
countries such
as Qatar, Saudi
Arabia if emerging economies
adopt similar
energy transition
Less government focus on
wealth accumulation from oil
and gas. Fewer
energy-driven
conlicts, coup
d’́tats and
secessions.
Fewer long term
tensions in West
Africa, Sub-Sahara Africa, Latin
America, and the
Middle East
Could in short
term lead to
social unrest
as tacit dissatisfaction
with the ruling
regime rises
to the surface,
possibly toppling autocratic
governments
Opportunity
cost for overthrowing the
government to
gain control over
the country’s
‘prize’ is raised.
Could open door
towards greater
democratization
Fuel subsidies
become untenable. Slashing
subsidies out of
austerity raises
risk of popular
unrest
Weaker purchasing power in
MENA, Russia,
Caspian Region,
West Africa,
Sub-Sahara
Africa
Street protests
over erosion of
living standards,
possibly toppling autocratic
governments
Less authoritarianism in
rentier states as
attractiveness of
control over natural resources
declines. Incentive to diversify
the economy.
Efect
Loss of export
revenue for
hydrocarbon
producer countries that export
to Europe
Source: Sweijs et al. (2014: 73).
Dreyer (2013: 1) argues that “the politics of renewable energy has remained
largely connected to national boundaries and has had few international
ramiications” and that despite potential beneits, “it is hard to identify
a geopolitically signiicant ‘renewables’ dimension to global security or
energy politics.” She claims that renewable energy is not currently providing a foundation for EU diplomatic action, as other energy sources
previously did, but can and should be used more actively in the future. For
44
Annex I: Literature Review
her, increasing renewable energy imports to the EU from the neighboring
countries would help orient these countries towards Europe rather than the
Middle East. hus, increased interdependence with those countries would
beneit of the EU. Dreyer calls for a more active role for international organizations such as the OECD (including the IEA) and the WTO.
Uncertainty
Paltsev (2016: 394) holds that the future geopolitics of renewable energy
will be similar to the post-cold-war situation, where it was oten uncertain
“what the next challenge will be, what form it will take, or where it will
come from.” One of the reasons for this is that energy transition forces
many countries with low technological competence to take decisions that
have geopolitical ramiications. Bradshaw (2010) notes that energy transition brings uncertainty in terms of energy supply and demand and that it is
unclear how energy transition will be attained. According to Stang (2016)
and Umbach (2016), the geopolitical implications for energy markets of the
Paris climate agreement are numerous and need to be better understood.
Bosman and Scholten (2013: 1) argue that an energy system based on
renewable energy sources has implications which remain “highly uncertain.” hey conclude that “while a large-scale utilization of renewables
diminishes energy scarcity and lowers various kinds of pollution, their
potential to address energy-related geopolitical tensions among producer,
consumer, and transit countries remains to be seen.” Hache (2016) notes
that the challenges posed by energy transition could be as complex as the
present geopolitics of fossil fuel energy. He notes that the combination of
local and decentralized relations as well as technical, economic, sociological, behavioral, spatial and legal dimensions add to the overall complexity
and create new unexpected and unexplored interdependencies among the
states.
The Geopolitics of Renewable Energy
45
Changes in the international system
Casertano (2012: 6) notes that renewable energy “democratizes” the energy
supply and creates new network structures that can be called “Internet of
Energy”. Rikin (2011: 37) argues that deployment of renewable energy can
lead to a “hird Industrial Revolution” and democratize the international
energy system. Criekemans (2011: 8) indicates that “from an external-geopolitical perspective, those countries that today invest in renewable energy
sources and technology may become the dominant geopolitical players
tomorrow… Some predict a duo-multipolar order (led by the US and
China), others think that the external-geopolitical landscape of a world run
on renewable energy will be more in terms of a multipolar world where
power is spread more equally across the globe.”
Ladislaw et al. (2014) and Chevalier and Geofron (2013), frame energy
transition as the emergence of new geopolitics. Paltsev (2016) notes that
the expansion of renewable energy on a global scale will inevitably lead
to the emergence of new hubs of geopolitical power with supply-side geopolitics being sidelined. He argues that low-carbon energy geopolitics,
perhaps to an even greater extent than oil and gas, depends on a multitude
of factors (e.g. access to technology, power lines, rare earth materials, patents, storage, unpredictable government policies), thus making renewable
energy governance more complex. He emphasizes that in a new energy
system the players are more decentralized compared to the players in the
old system driven by fossil fuels. Scholten and Bosman (2016) draw up scenarios and conclude that most likely we will see a mix of the characteristics
of the old system and new characteristics.
De Ridder (2013: 19–20) envisages that an energy transition will lead to the
emergence of new players and will move the international system towards
greater multipolarity. She lists three major geopolitical implications: 1)
countries with reserves of important industrial minerals will become more
powerful; 2) parts of the world with major mineral reserves, such as the
Arctic and the South China Sea, will rise in strategic importance; 3) there
will be a gravitational shit towards countries that control technologies and
know-how on minerals and technologies for renewable energy. De Ridder
notes (2013: 20) that “countries with high R&D expenditures on renewable
46
Annex I: Literature Review
energy, such as Japan and China, and countries with strong growth in
renewable energy capacity such as Denmark and Germany, will gain [geopolitical] power.”
Huebner (2016) explains that renewable energy will have an important role
to play in the global energy supply, but only in the medium term. He lays
out a vision in which renewable energy leads to new forms and levels of
regional cooperation. hus, he sees a transition to renewable energy as still
involving trade, but at a regional rather than a global level. Endeo (2014)
highlights the potential for cooperation between the states on the northern
coast of the Mediterranean coast and those on the southern coast, as well
as the potential contribution to EU energy supplies.
Scenarios and typologies
Bosman and Scholten (2013) and Scholten and Bosman (2016) present
what they refer to as scenarios for renewable energy expansion based on
thought experiments, dividing countries into diferent groups according
to their renewable energy potential. hey conclude that, compared to a
fossil-fuel dependent energy system, in a system dominated by renewables
infrastructure management is more important than access to resources.
Geopolitical tensions and risks should therefore recede, due to falling
energy imports and reduced interdependence between countries. Scholten
and Bosman (2016: 281) note that the “presence of ‘prosumer countries’
lessens cross-border energy trade and in turn reduces geopolitical tensions
to those related to clean generation technology imports.”
Metals and industrial minerals scarcity
Grandell et al. (2016) argue that a shit to renewable energy is inevitable
and model the global transition of the energy sector taking into account
the availability of critical metals. hey conclude that the scenarios put
forward by 5th Assessment Report of the International Panel on Climate
The Geopolitics of Renewable Energy
47
Change (IPCC) are partly unrealistic from the perspective of critical metals
as they “do not consider material availability aspects” (Grandell et al. 2016:
61). Exner et al. (2015), Hurd et al. (2012) and Rothkopf (2009) argue that
while renewable energy helps reduce dependence on oil and gas, it also
increases dependence on metals (which are also geographically concentrated resources). De Ridder (2013) argues that the ambitious renewable
targets set by diferent countries boost demand for certain minerals, which
in turn raises international competition and may also have geopolitical
implications. According to a report of the International Council of Mining
and Metals (2012: 6), various metals are needed as inputs for low carbon
technologies (including renewable energy) but “[T]he exact nature of the
low carbon transition on both minerals and metals demand will difer
depending on which technologies are favored.”
Other aspects
Several scholars discuss other implications of an energy transition.
Overland (2015) provides a comprehensive overview of the geopolitical
consequences of climate policy, many of which are also relevant for a transition to renewable energy. Salzman (2016) argues that energy transition
and climate change policies in Europe may have serious geopolitical efects
but this will hardly have any impact on the EU–Russia relationship. Szarka
(2016) discusses that prospects of energy transition in the EU, including a switch to 100% in renewable energy and its implications. He notes
that some of the EU member states have difering visions and plans on
energy transition compared to that of the EU Commission—ambitious
vs modest plans. Pascual (2015), taking the case of the US as his starting
point, highlights the existing gaps in our understanding of the new energy
geopolitics driven by climate change. Fischhendler et al. (2015) note how
geopolitical arguments relating to the energy independence of Israel are
used to mobilize decision-makers in favor of renewable energy. Strunz and
Gawel (2016) use the example of Germany’s Energiewende and conclude
that renewable energy reduce energy import dependence for the country
without elaborating on potential implications of that trend. Overland and
Kjaernet (2009: 1) present the transition to renewable energy as a “global
48
Annex I: Literature Review
strategic race”, in which successful countries will gain an economic advantage over other countries.
Methodological note
he literature search was carried out using ISI Web of Science, Google
Scholar and Google. We searched in English, French, German, Russian,
and Spanish. (Adding Arabic, Chinese, and Japanese might have enabled us
to further expand the literature review.) We covered the period 2000–2015
and the same keywords and combination of keywords were used in each
language. In addition to searching these databases, we examined the bibliographies of those works we found.
References (literature review)
Ansar, A., Caldecott, B. and Tilbury, J. (2013) Stranded Assets and the Fossil Fuel Divestment Campaign,
Smith School of Enterprise and Environment (SSEE) / Stranded Assets Program, University of
Oxford. Working Paper.
Bosman, Rick and Daniel Scholten (2013) How Renewables Will Shift the Balance of Power. Available
at: http://reneweconomy.com.au/2013/how-renewables-will-shift-the-balance-of-power-78579
(Accessed 5 January 2017)
Bradshaw, Michael J. (2010) In Search of a New Energy Paradigm: Energy Supply, Security of Supply
and Demand and Climate Change Mitigation, Mitteilungen der Osterreichischen Geographischen
Gesellschaft, 152, 11–28.
Caldecott, B., Dericks, G., and Mitchell, J. (2015a) Stranded Assets and Subcritical Coal: The Risk to
Companies and Investors, Smith School of Enterprise and Environment (SSEE) / Stranded Assets
Program, University of Oxford. Working Paper.
Caldecott, B., Lomax, G., and Workman, M. (2014) Stranded Carbon Assets and Negative Emissions
Technologies, Smith School of Enterprise and Environment (SSEE) / Stranded Assets Programme,
University of Oxford. Working Paper.
Caldecott, B., Guy Lomax and Mark Workman (2015b) Stranded Carbon Assets and Negative Emissions
Technologies. Smith School of Enterprise and Environment (SSEE) / Stranded Assets Program,
University of Oxford. Working Paper.
Carbon Tracker Initiative (2013) Unburnable Carbon 2013: Wasted Capital and Stranded Assets. London,
UK.
Carbon Tracker Initiative (2015a) Coal: Caught in the EU Utility Death Spiral. London, UK.
Carbon Tracker Initiative (2015b) Lost in Transition. London, UK.
Casertano, Stefano (2012) Risiken neuer Energie—Konlikte durch erneuerbare Energien und Klimaschutz
(Risks of New Energy—Risks Posed by Renewable Energy and Climate Protection). Brandenburg
Institute for Society and Security (BIGS), No. 9.
Chevalier, J., P. Geofron (2013) The New Energy Crisis: Climate, Economics and Geopolitics. Palgrave
Macmillan UK.
The Geopolitics of Renewable Energy
49
Criekemans (2011), The Geopolitics of Renewable Energy: Diferent or Similar to the Geopolitics of Conventional Energy? ISA Annual Convention, 19 March, 2011, Montŕal, Qúbec, Canada, Global Governance: Political Authority in Transition, the Panel on “Geopolitics, Power Transitions, and Energy”.
De Ridder, Marjolein (2013) The Geopolitics of Mineral Resources for Renewable Energy Technologies,
The Hague Center for Strategic Studies. The Hague Centre for Strategic Studies.
Dirmoser, Dietmar (2007) Energiesicherheit. Neue Knappheiten, das Wiederauf- leben des Ressourcennationalismus und die Aussichten für multilaterale Ans̈tze (Energy Security. New Scarcity, The
Resurgence of Resource Nationalism and the Prospects for Multilateral Approaches). Kompass
2020. Deutschland in den internationalen Beziehungen. Ziele, Instrumente, Perspektiven.
Dreyer, Iana (2013) Renewables: Do They Matter for Foreign Policy? Brief Issue, No. 23, European Union
Institute for Security Studies (EUISS).
Endeo, Fabio (2014) La Geopolítica de la en la Región Mediterránea (Geopolitics of the Mediterranean Region), http://www.ieee.es/Galerias/ichero/docs_trabajo/2014/DIEEET03-2014_GeopoliticaEnergia RegionMediterranea.pdf (Accessed January 6, 2017).
Exner, Andreas; Lauk, Christian; Zittel, Werner (2015) Sold Futures? The Global Availability of Metals
and Economic Growth at the Peripheries: Distribution and Regulation in a Degrowth Perspective,
Antipode, 47 (2), 342–359.
Generation Foundation (2013) Stranded Carbon Assets. Why and How Carbon Risks Should Be Incorporated in Investment Analysis. Available at: https://www.genfound.org/media/pdf-generation-foundation-stranded-carbon-assets-v1.pdf
Grandell, Leena; Lehtila, Antti; Kivinen, Mari; et al. (2016) Role of Critical Metals in the Future Markets of
Clean Energy Technologies, Renewable Energy, 95, 53–62.
Hache, Emmanuel (2016) La géopolitique des énergies renouvelables: amélioration de la sécurité
énergétique et / ou nouvelles dépendances? (The Geopolitics of Renewables: Does more Energy
Security Come with more Energy Dependencies?), Revue Internationale et Stratégique, 1 (101),
36–46.
Hoggett, Richard (2014) Technology Scale and Supply Chains in a Secure, Afordable and Low Carbon
Energy Transition, Applied Energy, 123, 296–306.
Huebner, Christian (2016) Politische Agenda. Globale Energiewende–Geopolitik (Political Agenda. Global
Energy Transition and Geopolitics), Konrad Adenauer Stiftung. Regional Program for Energy Security and Climate Change in Latin America (EKLA).
Hurd, Alan J.; Kelley, Ronald L.; Eggert, Roderick G.; et al. (2012) Energy-Critical Elements for Sustainable Development, MRS Bulletin, 37 (4), 405–410.
Fischhendler, Itay; Nathan, Daniel; Boymel, Dror (2015) Marketing Renewable Energy through Geopolitics: Solar Farms in Israel, Global Environmental Politics, 15 (2), 98–120.
Falkner, R. (2010) The New Geopolitics of Climate Change After Copenhagen, World Economic Forum:
Industry Vision, http://personal.lse.ac.uk/Falkner/_private/2010%20-%20Falkner%20-%20
New%20Geopolitics%20of%20Climate%20Change.pdf (accessed 6 May 2014).
International Council on Mining & Metals (2012) The Role of Minerals and Metals in a Low Carbon Economy. ICMM, InBrief. June 2012.
Johansson, Bengt (2013) Security Aspects of Future Renewable Energy Systems. A Short Overview,
Energy, 61, 598–605.
Kostyuk, Valeriy, Makarov, Alexey and Tatyana Mitrova (2012) Энергетика и геополитика (Energy and
Geopolitics), Energoacademy, 1 (44), 46–59.
Krewitt, Wolfram, Nitsch, Joachim and Kristina Nienhaus (2009) Bedeutung der erneuerbaren Energien
und der Energieeizienz in verschiedenen globalen Energieszenarien (The Importance of Renewable
Energy and Energy Eiciency in Various Global Energy Scenarios). Forschen für globale M̈rkte erneuerbarer Energien. Annual Meeting of the ForschungsVerbunds Erneuerbare Energien (FVEE) in
Cooperation with the Agency for Renewable Energy (AEE), 24–25 November 2009, Umweltforum
Berlin, pp. 18–23.
Ladislaw, Sarah O., Maren Leed, Molly A. Walton (2014) New Energy, New Geopolitics: Background Report
1: Energy Impacts. Rowman & Littleield Publishers: Lanham, MD.
Laird, Frank N. (2013) Against Transitions? Uncovering Conlicts in Changing Energy Systems, Science
as Culture, 22 (2), 149–156.
Llano-Paz, Fernando de; Fernandez, Paulino Martinez; Soares, Isabel (2016) Addressing 2030 EU Policy
Framework for Energy and Climate: Cost, Risk and Energy Security Issues, Energy, 115, 1347–1360.
50
Annex I: Literature Review
Mecklin, John (2016) Introduction: International Security in the Age of Renewables, Bulletin of the Atomic Scientists, 72 (6), 377–377, DOI: 10.1080/00963402.2016.1240927
Ministerio de la Defensa (2010) La Nueva Geopolítica de la Energía (New Geopolitics of Energy), http://
www.defensa.gob.es/ceseden/Galerias/destacados/publicaciones/monograias/ icheros/114_
LA_NUEVA_GEOPOLITICA_DE_LA_ENERGIA.pdf (Accessed January 6, 2017).
Ministerio de la Defensa (2015) Energía y Geoestrategia 2016 (Energy and Geostrategy 2016), http://
www.ieee.es/Galerias/ichero/cuadernos/Energia_y_Geoestragia_2016.pdf (Accessed January 7,
2017).
OECD (2015) Divestment and Stranded Assets in the Low-carbon Transition. Background paper for the
32nd Round Table on Sustainable Development, 28 October 2015, OECD Headquarters, Paris.
Overland, Indra (2015) Future Petroleum Geopolitics: Consequences of Climate Policy and Unconventional Oil and Gas, Handbook of Clean Energy Systems, Chichester: Wiley, pp. 3517–3544.
Overland, Indra and Heidi Kjaernet (2009) Russian Renewable Energy: The Potential for International
Cooperation, Surrey: Ashgate.
Paltsev, Sergey (2016) The Complicated Geopolitics of Renewable Energy, Bulletin of the Atomic Scientists, 72 (6), 390–395.
Pascual, Carlos (2015) The New Geopolitics of Energy. The Center on Global Energy Policy, Columbia,
SIPA.
Peters, S. (2002) Courting Future Resource Conlict: The Shortcomings of Western Response Strategies
to New Energy Vulnerabilities, Energy Exploration and Exploitation, 20–1 (6-1), 29–60.
Rifkin, Jeremy (2011) The Third Industrial Revolution. How Lateral Power is Transforming Energy, the
Economy, and the World. New York: Palgrave Macmillan.
Rothkopf, David J. (2009) Is a Green World a Safe World? Not Necessarily. A Guide to the Coming Green
Geopolitical Crises, Foreign Policy, September/October 2009.
Salzman, Rachel S. (2016) Will Climate-Change Eforts Afect EU–Russian Relations? (Probably not),
Bulletin of the Atomic Scientists, 72 (6), 384–389, DOI: 10.1080/00963402.2016.1240473
Scholten, Daniel (2016) The Geopolitics of Renewables. Exploring Political Implications of Renewable
Energy Systems. Technological Forecasting and Social Change. 103 (2016) 273–283.
Stang, Gerald (2016) Shaping the Future of Energy. European Union Institute for Security Studies (EUISS), Brief Issue, 24, 2016.
Strunz, Sebastian and Erik Gawel (2016) Importabḧngigkeit und Energiewende—ein neues Risikofeld
der Versorgungssicherheit? (Import Dependency and Energiewende—a New Risk for Security
of Supply?) Helmholtz-Zentrum für Umweltforschung (UFZ). Discussion Papers Department of
Economics, 5/2016.
Streck, C. and Terhalle, M. (eds) (2013) Climate Policy, special issue: The Changing Geopolitics of Climate Change, 13(5): 1469–3062.
Sujatha, Raman (2013) Fossilizing Renewable Energies, Science as Culture. 22 (2), 172–180.
Sweijs, Tim; Marjolein de Ridder; Sijbren de Jong; Willem Oosterveld; Erik Frinking; Willem Auping,
Roberta Coelho, Jyothi Bylappa and Ihor Ilko (2014) Time to Wake Up: The Geopolics of EU 2030
Climate and Energy Policies. The Hague Centre for Strategic Studies (HCSS).
Szarka, Joseph (2016) Towards an Evolutionary or a Transformational Energy Transition? Transition
Concepts and Roadmaps in European Union Policy Discourse, Innovation—The European Journal of
Social Science Research, 29 (3), 222–242.
Umbach, Frank (2016) Energy Prices, Climate Change and Geopolitics: What Next?, Presentation and
Background Paper—Plenary 4, Asia-Paciic Roundtable—APR 30, “Cooperation and Contestation in
a Changing Regional Landscape”.
Verrastro, Frank A., Sarah O. Ladislaw, Matthew Frank Lisa A. Hyland (2010) The Geopolitics of Energy.
Emerging Trends, Changing Landscapes, Uncertain Times. A report of the CSIS energy and national
security program.
Westphal, Kirsten (2011) Energy in an Era of Unprecedented Uncertainty: International Energy Governance in the Face of Macroeconomic, Geopolitical, and Systemic Challenges, in: David Koranyi
(ed.), Transatlantic Energy Futures: Strategic Perspectives on Energy Security, Climate Change and
New Technologies in Europe and the United States, Center for Transatlantic Relations, 1–26.
Westphal, Kirsten and Susanne Droege (2015) Global Energy Markets in Transition: Implications for Geopolitics, Economy and Environment, Global Trends 2015, Prospects for World Society.
The Geopolitics of Renewable Energy
51
Annex II: Workshop Program
Workshop—the Geopolitical Implications of Renewable Energy
March 22-23, 2017
German MFA, Kurstrasse 36, Berlin, Germany
Agenda
DAY 1
12:30-14:00
Lunch with Welcoming Remarks
Director General Miguel Berger, Head of the Department of Economic
Afairs and Sustainable Development, Federal Foreign Oice and
Director General Adnan Amin, IRENA
14:00-15:15
Session 1. Renewable Energy Deployment Scenarios: inding an
analytical basis for geopolitical analysis. (See Section I of the
framework paper)
Introductions by Michal Taylor and presentation of the REmap and
G20 Decarbonization Study by Dolf Gielen, IRENA.
DISCUSSION QUESTIONS:
•
What are diferent projections for renewable energy in the future?
•
What are the speciic strengths and weaknesses of the diferent scenarios;
where are they similar and where do they difer?
•
Which scenario provides the best analytical basis for geopolitical analysis?
15:15-15:30
Cofee Break
15:30-16:45
Session 2. Critical Material Supply Chains: the implications of the
unequal distribution of minerals, metals, and technologies needed
for renewable energy. (See Section II.A of the framework paper)
Moderator/Introduction by: David Sandalow, Columbia
DISCUSSION QUESTIONS:
16:45-17:00
52
•
Where are key natural resources for renewable energy located, and how will
the nature of these resources afect energy supply and security in the future?
•
To what extent could mineral inputs needed for renewable energy—as well as
renewable energy technologies and intellectual property—create the potential
for new cartels, threats of scarcity, or conlict over resources?
Cofee Break
Annex II: Workshop Program
17:00-18:15
Session 3. Topic A: Technology and Finance: a shift in the sources
of power from resources to infrastructure capacity and management system eiciency? (See Section II.B of the framework paper)
Topic B: Resource Curse (Section II.C of the framework paper)
Moderator: Petter Nore, Norwegian MFA and introductions by Melanie Nakagawa, Columbia
DISCUSSION QUESTIONS:
19:00
•
To what extent will increased renewable energy investment or inance for such
investment become a tool of geopolitical leverage?
•
Will trade in technology or the sharing of intellectual property become a basis
for greater cooperation between countries or lead to competition between
them?
•
Do countries who become either big generators of renewable energy or
renewable energy technology run the risk of developmental challenges akin to
“the resource curse?”
Reception hosted by Norwegian MFA/NUPI
Welcome remarks by Director Vegard Kaale, Energy Section,
Norwegian MFA and Director Ulf Sverdrup, NUPI.
Radisson Blu Hotel Berlin, Karl-Liebknecht-Strasse 3
DAY 2
08:45-10:00
Session 4. Electricity Grids: the geopolitical dynamics of super-,
micro- and of-grid solutions and their vulnerability to cyber
attacks. (See Section II.D of the framework paper)
Moderator: Indra Overland, NUPI; introductions by Daniel Scholten, Delft University of Technology; Antonella Battaglini, CEO of
Renewables Grid Initiative
DISCUSSION QUESTIONS:
10:00—10:15
•
Could the regionalization of markets through supergrids increase regional
interdependence and cooperation—or is it more likely to create further geopolitical tensions?
•
What are the potential implications of decentralized grids carrying renewable
energy for the control centralized governments wield over their peripheries?
•
To what extent will new forms of energy infrastructure bring new and potentially unique energy security problems through increased vulnerability to
cyber-attacks?
Cofee Break
The Geopolitics of Renewable Energy
53
10:15—11:30
Session 5. Reduced Oil and Gas Demand: the transformation of
energy markets and the implications for the geopolitical landscape. (see Section II.E of the framework paper)
Moderator: Meghan O’Sullivan, Harvard; introduction by Giacomo
Luciani, Graduate Institute Geneva
DISCUSSION QUESTIONS:
•
In what way could the growth of renewable energy afect global demand for
fossil fuels?
•
What would be the implications of such demand shifts for producer countries
and how can they best prepare themselves for these trends?
•
What would be the implications for consumer countries and how would the
growth of renewable energy usage change the balance of power between producer and consumer countries?
11:30—11:45
Cofee Break
11:45-13:00
Session 6. Avoiding Climate Change: renewable energy and the
geopolitics of climate change. (see Section II.F of the framework
paper)
Moderator: Andris Piebalgs, FSR; introductions by Jonathan
Elkind, Columbia and Peter Fischer, German FFO
DISCUSSION QUESTIONS:
•
To what extent can policies designed to reduce carbon emissions help reduce
the geopolitical risks associated with climate change—such as state failure
and large-scale involuntary migration?
•
Will greater ambition by some countries in addressing climate change confer
more inluence or soft power in the UNFCCC and other forums?
13:00-14:00
Lunch
14:00—15:15
Session 7. Wrap-up and Next Steps. (see Section III in the framework paper)
Moderator: Hans Olav Ibrekk, Norwegian MFA. Input from session
rapporteurs.
54
Annex II: Workshop Program
Annex III: Workshop Participants
Last name
First name
Professional title
Institution
Abdel-Latif
Ahmed
Special Assistant Oice of the
Director General
International Renewable Energy
Agency (IRENA)
Amin
Adnan Z.
Director General
International Renewable Energy
Agency (IRENA)
Battaglini
Antonella
Chief Executive Oicer
Renewable Grid Initiative
Bazilian
Morgan
Fellow
Center for Global Energy Policy,
Columbia University
Behrens
Arno
Senior Research Fellow
Centre for European Policy Studies
(CEPS)
Berger
Miguel
Director General, Head of the
Department of Economic Afairs
and Sustainable Development
Federal Foreign Oice, Germany
Bridle
Richard
Senior Policy Advisor
International Institute for Sustainable Development (IISD)
Clark
Alex
Fellow
Harvard University Kennedy School
Cremer
Tobias
Fellow
Harvard University Kennedy School
de Jong
Sijbren
Strategic Analyst
Hague Centre for Strategic Studies
(HCSS)
Elkind
Jonathan H.
Fellow and Adjunct Senior
Research Scholar
Center on Global Energy Policy,
Columbia University
Fischer
Peter
Deputy Director General for
Energy & Climate Policy and
Export Control
Federal Foreign Oice, Germany
Gielen
Dolf
Director
International Renewable Energy
Agency (IRENA)
Hammbelbo
Kirsten
Senior Advisor
Ministry of Foreign Afairs, Norway
Hongyuan
Yu
Director
Shanghai Institute for International
Studies
Hoshi
Hisashi
Director
The Institute of Energy Economics,
Japan (IEEJ)
Höysniemi
Sakari
Doctoral candidate
University of Helsinki
Ibrekk
Hans Olav
Policy Director
Ministry of Foreign Afairs, Norway
The Geopolitics of Renewable Energy
55
56
Klee
Kerstin
Assistant Desk Oicer, Foreign
Energy and Commodity Policy
Federal Foreign Oice, Germany
Koeppel
Hans
Head of Unit for Foreign Policy
Issues of Energy Transition
Federal Foreign Oice, Germany
Kraemer
R. Andreas
Senior Fellow
Institute for Advanced Sustainability Studies (IASS)
Kuntze
Lennart
Associate Programme Oicer
IRENA
Lemphers
Nathan
Visiting Research Fellow, NUPI
University of Toronto
Lidner-Olsson
Erik
Junior Professional Associate
International Renewable Energy
Agency (IRENA)
Luciani
Giacomo
Professor
The Graduate Institute Geneva
Molier
Eveline
Nakagawa
Melanie
Nehls
Estelle
Noll
George
Counselor for Global Afairs
American Embassy Berlin
Nore
Petter
Chief Energy Analyst
Ministry of Foreign Afairs, Norway
Orpana
Pekka
Ambassador and Senior Adviser
on Energy and Climate Change
Ministry for Foreign Afairs, Finland
O’Sullivan
Meghan
Professor / Director of the Geopolitics of Energy Project
Harvard University Kennedy School
Pedersen
Mikkel Frøsig
Senior Advisor
Norwegian Institute of International
Afairs (NUPI)
Piebalgs
Andris
Senior Fellow
Florence School of Regulation
(FSR), EUI
Radtke
Frank
Analyst
Strategic Energy Security Initiative,
Germany
Sandalow
David
Inaugural Fellow
Center on Global Energy Policy,
Columbia University
Scholten
Daniel J.
Assistant Professor
Delft University of Technology
Schulz
José
Head of Division for Foreign
Energy and Commodity Policy
Federal Foreign Oice, Germany
Scholz
Benjamin
Annex III: Workshop Participants
Ministry of Foreign Afairs, the
Netherlands
Non-resident Fellow
Center on Global Energy Policy,
Columbia University
Federal Foreign Oice, Germany
Wintershall
Stevens
Paul
Professor
Chatham House
Svenningsen
Tobias
Counsellor
Norwegian Embassy, Berlin
Sverdrup
Ulf
Director
Norwegian Institute of International
Afairs (NUPI)
Taylor
Michael
Senior Analyst
International Renewable Energy
Agency (IRENA)
Töpfer
Klaus
Professor
Institute for Advanced Sustainability Studies (IASS)
Vakulchuk
Roman
Senior research fellow
Norwegian Institute of International
Afairs (NUPI)
Velautham
Sanjayan
Executive Director
ASEAN Centre for Energy (ACE)
Westphal
Kirsten
Senior Associate
Stiftung Wissenschaft und Politik
(SWP)
Østevik
Malin
Junior Research Fellow
Norwegian Institute of International
Afairs (NUPI)
Øverland
Indra
Research Professor
Norwegian Institute of International
Afairs (NUPI)
The Geopolitics of Renewable Energy
57
A J O I N T PAPER F ROM
PUB L I S HED BY
Center on Global Energy Policy
Columbia University | SIPA
1255 Amsterdam Avenue
New York, NY 10025
energypolicy.columbia.edu
The Geopolitics of Energy Project
Belfer Center for Science and International Afairs
Harvard Kennedy School
79 John F. Kennedy Street
Cambridge, MA 02138
belfercenter.org/geopolitics