By Eric Vandenbroeck
and co-workers
Energy
and commodities lie at the dark heart of Vladimir Putin’s regime and its
threat to the world. Four trillion dollars of oil and gas exports over the
two decades of his rule have paid for the tanks, guns, and Grad missiles now
killing Ukrainians.
Energy insecurity is
a multi-dimensional construct that describes the interplay between physical
conditions of housing, household energy expenditures, and energy-related coping strategies.
As recently as 18
months ago, many policymakers, academics, and pundits in the United States and
Europe were waxing lyrical about the geopolitical benefits of the coming
transition to cleaner, greener energy. They understood that moving away from a
carbon-intensive energy system that relied on fossil fuels would be difficult
for some countries. But on the whole, the conventional wisdom held that the
shift to new energy sources would not only aid the fight against climate change
but also end the troublesome geopolitics of the old energy order.
Such hopes, however,
were based on an illusion. The transition to clean energy was bound to be
chaotic in practice, producing new conflicts and risks in the short term. By
the fall of 2021, amid an energy crisis in Europe, skyrocketing natural gas
prices, and rising oil prices, even the most optimistic evangelist of the new
energy order had realized that the transition would be rocky at best. Any
remaining romanticism evaporated when Russia invaded Ukraine in
February 2022. The war revealed not only the brutal character of Russian
President Vladimir Putin’s regime and the dangers of excessive energy
dependence on aggressive autocracies but also the risks posed by a jagged,
largely uncoordinated scramble to develop new energy sources and to wean the
world off old, entrenched ones.
A fire at an energy facility in Kyiv.
One result of this
turmoil has been the revival of a term that had come to seem anachronistic
during the past two decades of booming energy supplies and utopian visions of a
green future: energy security. To many, that phrase is redolent of the 1970s,
conjuring images of boxy sedans and wood-paneled station wagons lined up for
miles, waiting to fill their tanks with gasoline at sky-high prices thanks to
the Arab oil embargo of 1973 and the Iranian Revolution of 1979. But energy
security is hardly a thing of the past: it will be crucial to the future.
Energy security has
historically been defined as the availability of sufficient supplies at
affordable prices. But that simple definition no longer captures reality; the
world's risks are more numerous and complicated than in earlier eras. To handle
these new challenges, policymakers must redefine the concept of energy security
and develop new means of ensuring it. Four broad principles should guide this
process: diversification, resilience, integration, and transparency. Although
these principles are familiar, the traditional application methods will prove
insufficient in this new era; policymakers will need new tools.
There is no reason to
despair just yet. After all, the oil crisis of the 1970s sparked a great deal
of innovation, including the development of today’s wind and solar
technologies, greater efficiency in vehicles, and new government and
multilateral institutions to make and coordinate energy policy. The policies
and technologies that now seem old and outdated were once shiny and new.
Today’s crisis may likewise lead to novel ideas and techniques as long as
policymakers fully grasp the new realities they face.
The Future Arrived Early
The past year and a
half have dramatically revealed the many ways the energy transition and
geopolitics are entangled. Dynamics once seen as theoretical or hypothetical
are now concrete and evident to even the casual observer.
First, the past 18
months have highlighted the “feast before famine” dynamic facing traditional
oil and gas producers, whose power and influence will increase before it wanes.
In 2021, for example, Russia and other oil and gas producers had a
banner year in revenue as extreme weather and the world’s emergence from
pandemic slowdowns boosted demand for natural gas. Such shocks had outsize
impacts on a market with a meager cushion. In previous years, poor returns,
uncertainty about future energy demand, and pressure to divest from fossil
fuels all contributed to diminished investment in oil and gas, resulting in
inadequate supplies. Russia took advantage of these tight energy markets by
draining its European gas storage sites and slashing spot gas sales even as it
met long-term contractual commitments. Average natural gas prices tripled from
the first to the second half of 2021. Combined with rising oil prices, these
developments granted Russia a feast of annual revenues 50 percent higher for
oil and gas than the Kremlin had expected.
The past year and a
half also demonstrated that some oil and gas producers were still prepared to
use their energy prowess to advance their political and geostrategic objectives
ruthlessly; hopes that the world had moved beyond such behavior were dashed
with the brutal Russian invasion of Ukraine in February 2022. In the following
months, Russia gradually cut its pipeline gas deliveries to Europe by over
three-quarters, triggering a crisis that led European governments to spend a
staggering 800 billion euros shielding companies and households from higher
energy costs. The world’s dependence on Russia for energy initially
weakened the global response to the invasion: for many months, Russian oil
flows were exempt from European sanctions. To this day, the EU has not
sanctioned Russian gas sales; its members continue to import significant
volumes of Russian liquefied natural gas. Tight energy markets allowed Russian
oil and gas revenues to soar and gave Moscow a potential means of dividing a
newly united Europe.
The mismatch between
declining supplies and rising demand had already tightened the oil market by last
year. Prices leaped even further, to a 14-year-high, on market fears that the
delivery of millions of barrels per day of Russian oil would be disrupted even
as demand surged. At the beginning of the war in Ukraine, the International
Energy Agency (IEA) predicted that Russian production would decline by three
million barrels per day. Fears of supply shocks drove up oil prices and boosted
the income and the geopolitical heft of major oil producers,
particularly Saudi Arabia. The United States had thought its days of
begging Saudi Arabia to increase oil output had passed. But in the face of high
prices, old patterns reasserted themselves, as Washington pleaded—mostly in
vain—for more output from Saudi Arabia, the only country with any meaningful
spare oil production capacity.
The tremors of the
last 18 months also illustrate how the geopolitical environment can affect the
pace and scope of the transition to clean energy. Before the Russian invasion
of Ukraine, European countries and the United States were committed
to transforming their economies to achieve net-zero carbon emissions in the
coming decades. The brutality of Russia’s actions and the knowledge that fossil
fuel receipts funded those actions reinforced the determination among many in
Europe and the United States to move away from oil, gas, and coal. In
Washington, one result was landmark climate legislation in the form of the
Inflation Reduction Act. Europe also expedited its green plans, notwithstanding
some small near-term increases in coal use.
Many officials worry
that a more accelerated energy transition will necessarily involve greater
dependence on China, given its dominance of clean energy supply chains. U.S.
Senator Joe Manchin, a Democrat from West Virginia, warned that he did not want
to wait in line to buy car batteries from China the way he waited in line in
the 1970s to buy gasoline made with oil from the Middle East. Such fears led
Congress to create incentives for the domestic production, refining, and
processing of critical minerals now centralized in China. Rather than praising
Washington for finally passing meaningful climate change legislation, however,
much of the world resented these moves as acts of U.S. protectionism, stirring
talk of climate-provoked trade wars.
Finally, the energy
crisis of the last 18 months has widened the rift between rich and poor
countries. Many countries in the developing world became more strident in
objecting to pressure to diversify away from fossil fuels, noting the rise in
food and energy costs emanating from a European war. Developing countries have
also denounced what they perceived as the hypocrisy inherent in how the
developed world has responded to the crisis. After years of citing climate
change as a reason to avoid funding natural gas infrastructure in lower-income
countries, for example, European countries were suddenly racing to secure new
supplies for themselves and building new infrastructure to accept them. Making
matters worse, as Europe bid up the price of gas, demand for coal spiked in
Asia and drove prices to record levels, leaving developing and emerging-market
countries, such as Pakistan and Bangladesh, struggling to afford energy in any
form. These tensions were fully displayed at the UN climate conference in Egypt
in November 2022. Biden arrived to take a victory lap over the passage of a
historic domestic climate law but found that poorer countries were unimpressed.
Instead, they asked why the United States was not doing more to finance
climate-change adaptation and clean energy outside its borders and demanded
that their richer counterparts compensate them for the damage that climate
change has already caused to their cities, agriculture, and ecosystems.
The energy crisis may
have eased in recent months, but it is still far too early for complacency. The
vast majority of Europe’s reduction in gas demand last year arose from
unusually warm weather and the idling of industrial production, as opposed to
intentional conservation that can be sustained.
Moreover, Europe may
only be able to rely on a little, if any, Russian gas to refill its storage
facilities over the coming year. The flow of piped Russian gas into Europe
throughout 2022, albeit in shrinking volumes, has now halted and seems unlikely
to resume; the Russian liquefied natural gas still flowing to Europe could come
under pressure and be curtailed in the months ahead.
Meanwhile, with
growing risks to Russian oil output, global demand is expected to rise nearly
twice as much as supply in 2023, according to the IEA. Washington’s primary
tool for cushioning supply disruptions, the U.S. Strategic Petroleum Reserve,
is vastly diminished. If prices begin to soar again, Western countries will
have few options but to turn once more to Saudi Arabia and the United Arab
Emirates, which also has some spare capacity. Ironically, by the time the UAE
hosts the next major UN climate conference at the end of 2023, the
world may also be turning to Abu Dhabi for climate leadership and more oil.
Sources Of Stress
Three main factors
driving the new energy insecurity are the return of great-power rivalry in an
increasingly multipolar and fragmented international system, the efforts of
many countries to diversify their supply chains, and the realities of climate
change.
Russia’s invasion of
Ukraine and its broader confrontation with the West offer a striking example of
how the ambitions of a single leader can create energy insecurity for broad
swaths of the world’s population, and the war serves as a reminder that
great-power politics never really went away.
The U.S.-Chinese contest, however, may ultimately prove more
consequential. The intensifying desire of the United States and China to not
rely too much on each other is remaking supply chains and reinvigorating
industrial policy to a degree not seen in decades. Despite redoubled efforts to
produce more clean energy at home, the United States and others will still
depend on China for critical minerals and other clean energy components and
technologies for years, creating vulnerabilities to Chinese-induced shocks. For
instance, in recent months, China has suggested that it may restrict the export
of solar energy technologies, materials, and know-how in response to
restrictions Washington imposed last year on the export of high-end
semiconductors and machinery to China. If Beijing were to follow through on
this threat or curtail the export of critical minerals or advanced batteries to
major economies (just as it cut off rare earth supplies to Japan in the early
2010s), large segments of the clean energy economy could suffer setbacks.
Traditional energy
heavyweights are also recalibrating their positions in response to the changing
geopolitical landscape in ways that increase energy security risks. Saudi
Arabia, for instance, now sees its global stance differently than it did in the
decades that followed the famous “oil for security” bargain struck by U.S.
President Franklin Roosevelt and Saudi King Abdulaziz ibn Saud on
Valentine’s Day in 1945. Riyadh is now far less concerned with accommodating
Washington’s requests, overt or implied, to supply oil markets in ways
consistent with U.S. interests. In the face of a perceived or real decrease in
U.S. strategic commitment to the Middle East, Riyadh has concluded it must tend
to other relationships—especially its links to China, the single largest
customer for its oil. The kingdom’s acceptance of China as a guarantor of the
recent Iranian-Saudi rapprochement bolsters Beijing’s role in the region and
its global status. Relations with Moscow have also become particularly
important to Saudi Arabia. Regardless of the invasion of Ukraine, the Saudi
government believes that Russia remains an essential economic partner and collaborator
in managing oil-market volatility. It will therefore be extremely reluctant to
take positions that pit the Saudi leadership against Putin.
The new energy
insecurity is also shaped by forceful moves many countries have made to
domesticate and diversify their supply chains since the invasion of Ukraine and
the global pandemic. Such moves are understandable and wise, given the now
evident risks of excessive dependence on certain countries, notably China, in
this new geopolitical era. Yet an interconnected global energy system remains
the cornerstone of energy security; markets are still the most efficient way to
allocate supplies. Increased self-sufficiency may give countries an increased
sense of resilience but could also make them vulnerable; an interconnected
global market can ease disruptions caused by extreme weather or political
instability. More segmented energy markets will inevitably have fewer options
to tap in such circumstances. The U.S. Inflation Reduction Act and Europe’s
Green Deal industrial plan are intended to accelerate the drive to net-zero
emissions. They also reduce energy insecurity by curbing dependence on globally
traded hydrocarbons exposed to geopolitical risks. Yet they also increase
insecurity since promoting domestic industries risks stoking protectionism and
fragmentation, which can make economies less energy secure.
Finally, climate
change will be a major threat to energy security in the coming decades, posing
risks to infrastructure old and new. Warmer waters and severe droughts will
make it harder to cool power plants, transport fuels, and rely on hydropower.
In 2022, California lost half its hydroelectric output because of drought,
and Brazil was nearly forced to ration electricity after losing much
of its hydropower. These events will become more common as the world
decarbonizes because an energy system less reliant on hydrocarbons will depend
more heavily on electricity; the cheapest way to decarbonize sectors such as
transportation and heating will be to use electricity instead of gasoline
engines or natural gas boilers. The IEA estimates that if the world is to reach
the goal of net-zero carbon emissions by 2050, 50 percent of global energy
consumption will need to be met by electricity, up from only 20 percent today.
And nearly all that electricity will need to be produced from zero-carbon
sources, up from only 38 percent today.
Climate change will
place much of the infrastructure for this electricity generation, transmission,
and distribution at greater risk since fragile grids and overhead wires are
often more vulnerable to extreme weather, wildfires, and other climate-related
risks. Climate change can also harm renewable sources of electricity, with the
UN Intergovernmental Panel on Climate Change projecting that by 2100, average
global wind speeds could fall by 10 percent as climate change reduces the
differences in atmospheric temperatures that generate wind.
Diversification Dilemmas
One solution to these
problems is to diversify supply. Diversification remains as central to energy
security as it was in 1913, when Winston Churchill, then the first lord of the
Admiralty, declared that “in variety, and variety alone” would the United
Kingdom find a solution to vulnerabilities created by his decision to shift the
British navy from reliance on Newcastle coal to less secure sources of oil from
Persia.
In the long run, the
clean energy transition will often improve energy security by diversifying fuel
sources and suppliers. For example, transportation, most of which currently
runs on oil, will be less vulnerable to fuel supply disruptions in a world
where roughly two-thirds of vehicles are electrified since electricity can be
generated from multiple energy sources. And because most electricity is produced
close to where it is consumed, a more electrified world will also be less
subject to import disruptions caused by country disputes.
Yet as the transition
progresses and consumers diversify away from fossil fuels, new vulnerabilities
and threats to energy security will arise. Even as oil use wanes, geopolitical
risks may increase as global production becomes further concentrated in
countries that can produce at low cost and with low emissions, many of which
are in the Persian Gulf. In the IEA scenario in which the world reaches
net-zero carbon emissions by 2050, the share of global oil supply from OPEC
producers rises from around one-third today to roughly one-half. The oil giant
BP anticipates an even greater global dependence on these producers, estimating
that by 2050, they will account for nearly two-thirds of the global oil supply.
In the long run, that will be a large share of a tiny pie, but oil demand will
remain very high and consequential for decades even if annual demand is
falling.
U.S. policymakers may
ask themselves how comfortable they would feel if global oil production were to
be even more heavily concentrated in OPEC countries than today. Faced with that
outcome, they might consider several options, such as extending the
increasingly popular concept of “friend shoring” to oil by more actively
supporting production at home and in countries such as Norway and Canada, which
are perceived as less risky than say, Iran, Libya, and Venezuela. Some
officials might even advocate penalizing less friendly oil sources through
import taxes or sanctions.
A facility that processes methane into natural gas in
Pixley, California.
However, taking such
measures to subvert the market and bolster oil production in preferred
locations would carry significant risks. It would undermine the benefits of the
ability to reroute oil supplies in case of disruption. It would also risk
backlash and retaliation from major global oil producers in OPEC, which can
increase prices by restricting output. Subsidizing domestic supply would also
counter efforts to encourage consumers to move away from fossil fuels. A better
approach would be embracing global markets but boosting defenses against
inevitable shocks and volatility with larger, not smaller, strategic oil
reserves.
Meanwhile,
diversifying the inputs of clean energy will be even more difficult than doing
so for fossil fuels. The sources of the requisite technology and components,
notably the critical minerals needed for batteries and solar panels, are even
more heavily concentrated than oil. The world’s largest supplier of lithium
(Australia) accounts for around 50 percent of the global supply, and the
leading suppliers of cobalt (the Democratic Republic of the Congo) and rare
earth (China) each account for around 70 percent of those resources. In
contrast, the world’s largest producers of crude oil—the United States, Saudi
Arabia, and Russia—each account for just 10 to 15 percent of the global supply.
The processing and refining of these minerals are even more concentrated, with
China currently performing around 60 to 90 percent. Meanwhile, Chinese
companies manufacture over three-quarters of electric vehicle batteries and a
similar proportion of the wafers and cells used in solar energy technology.
U.S. policymakers
have recently awakened to these vulnerabilities and the fact that they will
become more acute as the transition progresses. The Inflation Reduction Act
encourages the production of critical minerals in the United States and
elsewhere by providing tax credits and loan guarantees for domestic producers,
among other measures. The Biden administration recently signed
agreements with Congo and Zambia to increase U.S. imports of their clean-energy
minerals. And the U.S. International Development Finance Corporation (DFC) has
pursued debt transactions to support the development of solar cell
manufacturing outside China. But to get more of the minerals from more of the
countries it prefers, Washington will need to strike many more bilateral and
multilateral trade agreements and sharpen instruments such as the U.S.
Export-Import Bank, which can fund overseas mining operations in friendly
countries such as Indonesia. For its part, the U.S. Congress should increase
the DFC’s authority and expand its investment ability.
Another area that
badly needs more diversification is enriched uranium, which will become more
important as the use of nuclear power increases globally to meet low-carbon
electricity needs. Given the current geopolitical realities, Russia’s role as a
dominant supplier of nuclear fuel services to many countries, including the
United States, is a source of great discomfort and vulnerability. Boosting
uranium production, conversion, and enrichment in the United States and among
its Western allies and substantially ramping up their fabrication of the fuel
assemblies for Russian-made reactors will be critical to maintaining the
existing nuclear fleet and keeping decarbonization goals within reach.
Building Resilience
A secure energy
system must withstand and bounce back quickly from unexpected shocks and
disruptions. At the most fundamental level, reliable energy infrastructure is
the key to that sort of resilience. Governments and private companies have long
worked to protect energy infrastructure from dangers of all kinds, from
terrorist attacks to hurricanes. As the transition proceeds, they will need to
step up such efforts. Moreover, as the clean energy economy becomes more
digitized and electrified, it will be exposed to a growing threat of
cyberattacks. Private companies and governments must coordinate and cooperate
to deter and respond to threats such as the 2015 cyberattack that took out
large swaths of the grid in western Ukraine.
Resilience also
requires flexibility, which in the energy sector is measured by the ability of
every part of a system to cope with losses in other parts. Because renewable
sources such as solar power and wind are highly variable, the energy they
generate must be stored or backed up by other sources, with delivery systems
making minute-by-minute adjustments. That is already a difficult task, and it
will become even harder in a grid with more intermittent energy sources and
more variable electricity demand. According to the IEA, the global power
system’s need for flexibility—measured as the amount the rest of the system
needs to adjust to handle changes in demand and in solar and wind output—will
more than quadruple by 2050 if all countries fulfill their climate
pledges. Today, plants that run on coal or gas perform most of these
adjustments. But as the transition progresses, the number of such plants—and thus
their ability to serve as backstops—will progressively diminish.
To counteract that
dynamic, U.S. policymakers should ensure that the increasing share of renewable
energy on the grid is matched by adequate balancing resources and storage
capacity. Doing so will require structures such as so-called capacity markets,
which pay generators to be available to meet peak demand even if they are idle
much of the time. Such mechanisms can help ensure that companies whose
resources are needed only infrequently nevertheless stay in business and
support a reliable electricity supply even as their utilization rate falls as
the grid decarbonizes.
Officials can also
use new tools to manage the demand for energy without
massively inconveniencing consumers or creating political headaches. For
instance, digital technology can help consumers shift energy-intensive
activities to low-demand times of the day (such as running dishwashers and
clothes dryers overnight) or prompt them to save energy by lowering thermostats in
unoccupied rooms. Artificial intelligence will also play a growing role—for
example, by reducing the time energy systems are down for maintenance,
forecasting demand, and improving storage. Such tools would have come in handy
in December 2022, when grid operators in Texas badly underestimated how much
electricity customers would need, and the state barely avoided widespread
blackouts. Finally, officials should avoid the early retirement of
fossil-fired electricity sources that can balance the grid and ensure reliability
before alternatives can provide the necessary level of service.
A resilient system
must also weather unexpected shocks and supply disruptions. For decades,
policymakers have relied heavily on two types of buffers: the spare capacity of
oil-producing countries (especially Saudi Arabia) and strategic stockpiles,
which members of the IEA must hold as part of an agreement forged after the
Arab oil embargo in the 1970s. These historical buffers will still matter as
the transition unfolds—even more so if, as likely today, declines in energy
supply and investment are not synchronized with declines in demand, leading to
less slack in the system to handle unexpected shocks and more volatility.
Moreover, Riyadh has become far less willing to dip into its spare capacity
whenever Washington demands it. As coal generation declines in a decarbonizing
economy, power generators will have less opportunity to toggle between natural
gas and coal, as many do now. This new reality could result in more volatility
in natural gas prices. And recent turmoil in the refining sector that
contributed to skyrocketing gasoline and diesel prices in the United States was
a reminder that limited refining investment could bite consumers before vehicle
electrification causes fuel use to drop sharply. For those reasons, other
strategic stocks of all kinds will become more important—not just those that
hold oil but also ones that hold natural gas and oil products such as diesel
fuel and gasoline.
The United States
will also need strategic stockpiles of the building blocks of clean energy,
working with its allies to amass critical minerals such as lithium, graphite,
rare earth, and nickel. Such coordination would be enhanced if the IEA had a
hand in negotiating agreements, assessing which countries are best positioned
to contribute to which stockpiles, and regularly monitoring whether the
composition of stockpiles fits current needs. The IEA has played this role
admirably for oil and oil products and could do so again with critical minerals
if its members chose to expand its mandate.
Integration As Insurance
A desire for greater
security has spurred the decades-long quest for “energy independence” in the
United States and elsewhere. And because of the shale revolution, the United
States has become energy self-sufficient in net terms. Nevertheless, the
country continues to be vulnerable to geopolitical risks because supply shocks
anywhere affect prices everywhere in a global market. Proponents of the
transition to a net-zero carbon system have long heralded the greater
insulation from geopolitics that would likely result from the end of the
fossil-fuel era. But at least for the next few decades, energy security will be
advanced not through more autonomy but more integration—just as it always has
been.
Interconnected and
well-functioning energy markets increase energy security by allowing supply and
demand to respond to price signals so the system can better handle unexpected
shocks. In 2005, when Hurricanes Katrina and Rita disrupted much of the U.S.
Gulf Coast’s vast production and refining operations, energy companies were
able to avert fuel shortages by quickly importing supplies from the global
market. Similarly, after the Fukushima nuclear disaster in 2011, Japan was able
to temporarily shut down its nuclear power sector because it could import other
sources of fuel from the global market.
Meeting at a nuclear power plant near Yuzhnoukrainsk, Ukraine.
But maintaining and
cultivating interdependence in today’s environment is more difficult than ever
in recent memory, as countries worldwide are embracing industrial policies that
involve increased state intervention in markets. Although those efforts can deliver
benefits, such as minimizing markets’ vulnerability to the whims of
geopolitical adversaries, many policymakers want to go further, promoting such
policies to boost domestic jobs and build political coalitions to support
stronger action on the environment. Indeed, although climate diplomacy has been
premised for years on the assumption that progress depends on transnational
cooperation, some efforts to advance climate action paradoxically risk
undermining cooperation by fueling the forces of fragmentation and
protectionism.
The case for energy
integration has suffered due to Europe’s urgent need to decouple from Russian
energy during the war in Ukraine. Nevertheless, although shocks may be felt
more broadly in an integrated system, they are also felt less intensely.
Integration is a form of insurance that spreads the risk of energy supply
disruptions among many parties. And even if more autonomy were preferable to
more integration, expanding clean energy at the scale and speed needed would
not be possible if each country sought to produce and consume only within its
own borders. According to the IEA, the value of global trade in critical
minerals must triple to achieve net-zero emissions by 2050. Global trade in
low-carbon fuels such as hydrogen and ammonia will also need to grow
exponentially. For the United States, energy security will require fewer trade
barriers and more trade agreements with allies and other countries that meet
certain environmental standards. Washington should also eliminate tariffs on
goods and technologies related to clean energy and help finalize the
Environmental Goods Agreement, which would reduce tariffs on goods that benefit
the environment to lower their costs and increase their trade.
What You Don’t Know Can Hurt You
One of the reasons
that the United States, Canada, Japan, and several European countries created
the IEA in 1974 was that a lack of accurate, reliable data on prices and
supplies had made it hard for governments to craft policies and respond to
crises. The lesson was clear: good data allows markets to function, prevents
panic, and deters speculation from exacerbating price spikes, volatility, and
shortages. Over the decades, IEA data and data assembled by the International
Energy Forum have underpinned decision-making about production levels and
guided actions such as coordinated releases of stockpiled oil.
A clean energy
economy will need the same kind of transparency. Inadequate data in nascent
markets, such as those for green ammonia and hydrogen, can cause supply
disruptions, a lack of liquidity, and poor availability of spot price
assessments, all leading to pronounced price fluctuations. The energy
transition will also depend heavily on the market for critical minerals, such
as nickel. But investors were reminded of how market opacity can trigger
extreme volatility when the price of nickel on the London Metal Exchange almost
quadrupled over just two days in early 2022, owing to massive short-selling
caused partly by a lack of price transparency.
Some private
companies have good price information, but no single entity gathers broad
industrywide data and makes it publicly available. The IEA is the clear
candidate to fill that role. Ideally, the agency would ask governments to share
mineral consumption and production data and make informed inferences about
inventory levels. Such data sharing would be especially important to ensure
compliance if governments agreed to create strategic stockpiles, as with oil.
For such a system to work, however, the IEA would have to bring in countries
that are not members of the organization but produce or consume significant
amounts of those minerals, requiring a new legal framework for the agency. Meanwhile,
to help prevent market manipulation and speculation, national regulators such
as the U.S. Commodity Futures Trading Commission should require greater
transparency in the pricing and trading of commodities.
Security And The Climate
The importance of
energy security never diminished; it had been taken for granted in a world of
abundance and integrated, well-functioning global energy markets. Policymakers
now have the opportunity to look at energy security and climate security
afresh, accord appropriate weight to both, and appreciate that neither can be
achieved without the other.
This effort requires
recognizing that energy security is not a static concept but has evolved a
great deal since the crises of the 1970s. Policymakers must grasp the new risks
to energy security and modernize their toolkits to combat them. Doing so is not
a distraction from addressing climate change but central to it; without this
shift, energy crises might derail the drive to net-zero emissions. In the
not-so-distant past, officials and experts thought that excessive fears about
energy security might hinder the fight for the climate. Today, the opposite is
true: as the transition to a net-zero world proceeds, the bigger danger to the
climate will be insufficient attention to energy security.
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