《大西洋理事會：2024天然氣與能源轉型研究報告：安全、公平與實現凈零排放（英文版）（24頁）.pdf》由會員分享，可在線閱讀，更多相關《大西洋理事會：2024天然氣與能源轉型研究報告：安全、公平與實現凈零排放（英文版）（24頁）.pdf（24頁珍藏版）》請在三個皮匠報告上搜索。

1、IN TURKEY GLOBAL ENERGY CENTERNatural Gas and the Energy Transition:Security,Equity,and Achieving Net ZeroPhillip CornellThe Atlantic Council in Turkey aims to promote dialogue and strengthen transatlantic engagement with the region through research,programming and high-level discussion forums to ad

2、dress critical issues around energy,economics,business,and security.The Atlantic Council Global Energy Center develops and promotes pragmatic and nonpartisan policy solutions designed to advance global energy security,enhance economic opportunity,and accelerate pathways to net-zero emissions.IN TURK

3、EY GLOBAL ENERGY CENTERThe Atlantic Council would like to thank our donor,alk Enerji,for supporting our work on this project.Cover:Gas pipes are seen at Gas Connect Austria in Baumgarten,Austria,September 28,2022.REUTERS/Lisa LeutnerISBN:978-1-61977-326-4This report was written and published in acco

4、rdance with the Atlantic Councils policy on intellectual independence.The author is solely responsible for its analysis and recommendations.The Atlantic Council and its donors do not determine,nor do they necessarily endorse or advocate for,any of this reports conclusions.April 2024IN TURKEY GLOBAL

5、ENERGY CENTERNatural Gas and the Energy Transition:Security,Equity,and Achieving Net ZeroPhillip CornellNatural Gas and the Energy Transition:Security,Equity,and Achieving Net ZeroIIATLANTIC COUNCILTable of Contents Executive Summary 11.Introduction:The Energy Trilemma and Gas in a Net-Zero World 32

6、.The Role of Natural Gas in a Global Net-Zero Energy System 6Natural Gas in a Decarbonized Power System 6Natural Gas for Industrial Uses 7Low-Hanging Fruit:Abatement Costs by Decarbonization Measure 83.Market and Regional VariationsOne Size Wont Fit All 10Gas-Producing Developing Countries 10Energy-

7、Importing Developing Countries 114.Financing Sustainable and Equitable Development in Line with Energy Transitions 14Finance Restrictions from North onto South 155.Conclusions 17About the Author 18Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero1ATLANTIC COUNCILExecutive

8、Summary1 Daniel Yergin,“Bumps in the Energy Transition,”International Monetary Fund,December 2022,https:/www.imf.org/en/Publications/fandd/issues/2022/12/bumps-in-the-energy-transition-yergin.The energy trilemma of energy security,affordability,and sustainability has gained newfound relevance in the

9、 presence of inflation and geopolitical con-flict,and has complicated the global pathway to net-zero emissions.Navigating this trilemma underscores the challenge of sufficient investment in cleanest-possible fossil fuel resources,and particularly natural gas.Power infrastructure must ensure stabilit

10、y across an in-creasingly complex and intermittent grid marked by high penetration of renewable electricity,while also coping with significant growth in energy demand(particularly in the de-veloping world).And in some industrial applications where direct electrification is not feasible,alternative e

11、nergy sources are still cost prohibitive or simply unavailable at scale.Stringent regulatory and public policy requirements to restrict fossil fuel production raise the risk of choking off supply before cleaner alternatives are sufficiently scaled,with significant effects on prices and reliability.H

12、owever,political events have caused many Western governments to rebalance their priorities.As Daniel Yergin wrote for the International Monetary Fund(IMF)in December 2022,“The energy shock,the economic hard-ship that ensued,skyrocketing energy prices that could not have been imagined 18 months ago,a

13、nd geopolitical conflictsall these combined to force many governments to reassess strategiesand recognize that the energy transition needs to be grounded in energy securitythat is,adequate and reasonably priced supplies.”1The protracted supply crisis in 2022 was exacerbated by the Russian invasion o

14、f Ukraine,and prompted developed countries to revise their energy transition messaging.Many highlighted the need to access and invest in fossil fuels during moments of economic and political crisis,soften-ing their rhetoric around emissions.That shift complicated an ongoing debate about whether to p

15、hase out(or simply end)public financing for fossil fuels.At the same time,de-veloping countries are increasingly unwilling to allow their economic development or security goals to be marginal-ized as the world builds a pathway to reach the goals of the Paris Agreement.The persistent need for energy

16、resources to meet growing demand while advancing the energy transition highlights a continued need for natural gas.Abundant and energy dense,natural gas is a valuable source of firm power and industrial fuel for both developing and developed economies.It is much less emissions intensive than fossil

17、substitutes like coal or fuel oil,and it competes at cost to displace those fuels where they are used to generate power or heat.The emissions that remain are increasingly manageable,thanks to methane-abatement technologies and carbon capture,utilization,and storage(CCUS).Some of the infrastructure f

18、or delivering and burning natural gas can also be converted for hydrogen use once it is avail-able on a large and sustainable scale.Put simply,even as policymakers move to aggressively deploy renewable and zero-carbon energy resources,natural gas remains a valuable tool in limited volumes to manage

19、the context de-pendencies of a transitioning energy system in the short,medium,and long terms.Effectively managing natural gas investment will require some nuance from policymakers,industry leaders,and those advocating for the rights of vulnerable populations.Regulatory and policy efforts to curtail

20、 supply in the name of carbon reduction raise the risk of stranded natural gas assets,and also of choking off supply before cleaner al-ternatives are sufficiently scaled.Both underscore the im-portance of policy stability.For natural gas in particular,technologies and business models to decarbonize

21、pro-cesses and manage emissions are prerequisites to avoid locking in decades of additional emissions,and depend on clear policy signals.The January 2024 pause on US liquefied natural gas(LNG)export projects imposed by the Joe Biden administration highlights the impact of oscillat-ing public policy,

22、with ramifications for investment in clean-est-possible gas solutions.When it comes to financing the natural gas investments necessary to stabilize net-zero power systems and enable industrial growth,issues abound across private investment,financing structures,and the construction of gas assets.Sove

23、reign and multilateral support for energy-related financing in emerging markets and less-developed countries(LDCs)is especially sensitive given its outsized impact on the livelihoods of so many.Those concerned with equity and the welfare of vulnera-ble populations should consider the impacts of abso

24、lutist climate advocacy,and empower those populations to de-cide for themselves.These issues were at the forefront of COP28 in Dubai,where the results of the United Nations Framework Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero2ATLANTIC COUNCILConvention on Climate Ch

25、ange(UNFCCC)-mandated global stocktake of progress toward the Paris Agreement was underwhelming.At the same time,a multitude of cri-ses within the energy system gives voice to those at the sharp end of the energy trilemmawhether Europeans facing deindustrialization,or those in developing countries e

26、xperiencing acute deprivation and being blocked from key sectors.Navigating the balance between enabling eq-uitable development while transitioning away from fossil fuels will require thoughtfulness with regard to the oppor-tunitiesand limitationsnatural gas presents in a decar-bonizing energy syste

27、m.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero3ATLANTIC COUNCIL1.Introduction:The Energy Trilemma and Gas in a Net-Zero World2 The 2022 and 2023 G7 communiqus were both the result of debates over public investment in natural gas.Germany and others insisted that both i

28、nclude language on the need for it.3“How Misfiring Environmentalism Risks Harming the Worlds Poor,”Economist,June 29,2023,https:/ Yergin,“Bumps in the Energy Transition.”Within the short span of three years,the glob-al economy has needed to contend with the COVID-19 pandemic,subsequent inflation,the

29、 Russian invasion of Ukraine,and the im-pact of that conflict on commodity shortages,rising ener-gy costs,and declining energy security.Russias invasion precipitated a reinvigoration of supply security concerns,while higher inflation and interest rates have underscored the importance of affordabilit

30、y and complicated the invest-ment landscape.As a result,short-term reliance on fossil fuels has increased,fewer resources are available for the energy transition,and coordination among regional and global partners has become more complicated.In the longer term,the crisis underscored the dangers of r

31、eliance on fossil fuel imports and exposure to price vol-atility.That is the case both in Organisation for Economic Co-operation and Development(OECD)countries like Germany whose former complacency over gas imports was exposed,and also in developing economies like Bangladesh from which LNG cargoes w

32、ere redirected to richer customers amid skyrocketing prices.All of this augers broadly for accelerating the energy tran-sition.Yet the whiplash nature of shifting public discourse around energy reinforces the notion that one size does not fit all,and that the path to decarbonizing the energy sector

33、is not always linear.Faced with a protracted supply crisis in 2022,rich countries shifted their energy transition messag-ing for both energy producers and developing economies,suddenly highlighting the need to access and invest in fos-sil fuels during moments of economic and political crisis.While a

34、ppropriate,the pivot came with important caveats about ensuring that investments are short term,flexible,and as clean as possible to avoid locking in decades of emissions.2 However,the renewed lifeline for fossil fuel in-vestments,even if only for the near term,underscores the status-quo bias and eg

35、ocentrism in the original messaging,as well as the implication that tradeoffs are suddenly rele-vant when their impacts are felt by rich countries.Indeed,purist or ideological approaches to energy tran-sition inevitably cause more harm than good.They might prioritize rapid decarbonization without ad

36、equately considering the socioeconomic realities of different re-gions,resulting in uneven employment impacts and det-rimental effects on livelihoods and local economies.In economies experiencing rapid industrialization,a sudden shift away from fossil fuels could exacerbate poverty and inequality.A

37、singular focus on certain renewable technolo-gies might overlook the immediate energy needs of poorer communities or those that lack access to reliable electric-ity.In the developing world,growth is still carbon intensive,and tying limited development-assistance resources to strict decarbonization t

38、argets can force countries to make hard choices about the poor,breeding resentment.As the Economist wrote in June 2023,“As well as facing stingier health-care and education budgets,developing econo-mies might find scant funding for expanding a gas-pow-ered electricity grid,even though nobody stands

39、ready to pay for a new one.African governments rightly resent being told to cut emissions rather than help people in des-perate needespecially given that Westerners continue to belch carbon.”3Narrow approaches to the transition run the risk of cur-tailing existing energy sources before viable altern

40、atives are sufficiently scaled and integrated.Yergin wrote that underinvestment has constrained sufficient supplies of oil and gas,thanks to“government policies and regulations;environmental,social,and governance(ESG)consider-ations by investors;poor returns caused by two price collapses in seven ye

41、ars;and uncertainty about future demand.”He describes the underinvestment as“preemp-tive”because it was rooted in the idea that low-carbon energy sources were already replacing fossil fuels at scalethey werent.4 In their crudest form,policies to incentivize investment into decarbonization are based

42、on categorizing energy sources as either“clean”or“dirty”despite a wide range of emissions implications depending on the particular en-ergy source.Legal efforts to taxonomize energy sources underpin future emissions-based trade and industrial pol-icy regimes,particularly in Europe.Yet those efforts a

43、lso cause headaches when technical complexities contend with blunt policy measures.In 2022,Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero4ATLANTIC COUNCILdebate raged in the European Union(EU)over whether gas and nuclear could qualify as“green”under the tax-onomy.That a

44、rgument was fraught with questions about perceptions and public messages,and ultimately ex-posed the necessary tradeoffs between some of the EUs sustainability criteria(particularly in the case of nuclear,where zero emissions also come with nuclear waste).In the United States,the Biden administratio

45、ns pause on gas export projects is set to spark a similar public debate about whether gas is“dirty”ahead of the 2024 election,with technical differentiations and gradations likely to be drowned out in a simplistic political fight.Such debates further stoke ideological division,as complex topics are

46、reduced to a duopoly of opposing talking points.In the case of natural gas,the reality is that there are gra-dations of“clean.”Technologies,business models,and use cases exist to mitigate emissions at points of produc-tion,processing,and use.The carbon intensity of natural gas depends on many differ

47、ent parts of the value chain,from extraction to burning,and rates of leakage or flaring.5 Calculating carbon intensity and encouraging its reduction,in turn,require transparency within the value chain,which is often lacking,particularly for Russian gas(with high 5 For example,analysis by the North S

48、ea Transition Authority shows that gas extracted domestically from the UK continental shelf has an average production emissions intensity of 21 kilograms of carbon dioxide per barrel of oil equivalent(kgCO2/boe),whereas imported LNG has a significantly higher average intensity of 79 kgCO2/boe by the

49、 time it reaches the UK point of consumptionalmost four times higher.“Natural Gas Carbon Footprint Analysis,”North Sea Transition Authority,July 2023,https:/www.nstauthority.co.uk/the-move-to-net-zero/net-zero-benchmarking-and-analysis/natural-gas-carbon-footprint-analysis/.fugitive emissions rates)

50、and LNG(with liquefaction and transport emissions).Transparency allows customers to prioritize lower-emissions natural gas,and for public policy to differentiate it.Emerging technologies such as“digital natural gas”can provide a digital record for a specific unit of natural gas production at the wel

51、lhead and at the point of consumption.Alternatives also matter.Gas replacing coal or upgrading older gas-fired turbines to highly efficient modern ones are major wins.But greenfield unabated gas-fired generation will not be sustainable and will often be more costly than the renewable alternative.Eve

52、n under a credible net-zero scenario,gas demand will likely persist,both for technical reasons and to create low-carbon fuels like blue hydrogen.In the medium term,natural gas can be part of a solution in which sustainable economic development is a corollary(or prerequisite)to climate action.In deve

53、loping countries where industrial activities are a source of growth and are particularly effec-tive at addressing poverty,such development can equip societies with the resources and space to address climate concerns.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero5ATLANTI

54、C COUNCILUncomfortable Truths about Equity and Energy PolicyEnergy demand is rising fast as the global middle class expands,demanding cleaner energy and much more of it.However,the massive resources needed to drive an accelerated uptake of renewable energy alternatives and curtail relatively cleaner

55、 fossil fuels are not forthcoming from those who can most afford it and who emit the most carbon.The top 10 percent of carbon emitters worldwidemost of whom live in wealthy countriesaccounted for nearly half of energy-related carbon-dioxide(CO2)emissions in 2021.The bottom 10 percent of emitters wer

56、e responsible for only 0.2 percent of emissions.1 Even within wealthy countries,the burden of climate responsibility should be narrowly targeted.Young and marginalized people who struggle economically and are responsible for low amounts of carbon emissions will bear the worst impacts of climate chan

57、ge,and their tolerance for shouldering the costs of mitigation(for example through higher prices)will be limited.The Grantham Institute estimates that rich countries and development banks will need to provide at least$1 trillion each year to help close a$3.4-trillion annual shortfall between current

58、 figures and where combined spending on climate and human development should be.2 Yet they have been failing to meet the much lower$100-billion annual target they set in 2019.New policies and financing commitments must make up for this massive shortfall.In the best-case scenario,the energy transitio

59、n will require simultaneous scaling across value chains at breakneck speed.The chances of economic mismatches,localized volatility,and discrete deprivations are high,however,and their impact will fall disproportionately on less developed countries and the poor.While the transition to net zero is ult

60、imately deflationary and improves resilience,the near-term reality of“green-flation”risks undermining public support for the transition and raises larger questions about inequality and the burden of paying for it.3 Losers from the energy transition,even in the short term,will require compensation an

61、d support for the world to progress in the broad enterprise of decarbonization.All of this suggests the need for shifting the financing risk burden,with its near-term costs and long-term pay-offs,onto the richest people in the richest countries.1 Laura Cozzi,Olivia Chen,and Hyeji Kim,“The Worlds Top

62、 1%of Emitters Produce over 1000 Times More CO2 than the Bottom 1%,”International Energy Agency,February 22,2023,https:/www.iea.org/commentaries/the-world-s-top-1-of-emitters-produce-over-1000-times-more-co2-than-the-bottom-1.2 Vera Songwe,et al.,“Finance for Climate Action:Scaling Up Investment for

63、 Climate and Development,”London School of Economics and Political Science,November 8,2022,https:/www.lse.ac.uk/granthaminstitute/publication/finance-for-climate-action-scaling-up-investment-for-climate-and-development/.3 This has also been referred to as a“green premium”by Bill Gates and others.“Th

64、e Green Premium,”Breakthrough Energy,last visited February 13,2024,https:/breakthroughenergy.org/our-approach/the-green-premium/.The top 0.1 percent of US households,numbering 131,000,hold$18.7 trillion,almost twice as much wealth as the 65 million households in the bottom 50 percent.The top 10 perc

65、ent of US households are also responsible for 40 percent of the countrys human-caused planet-heating pollution.Source:Jared Starr,et al.,“Income-Based U.S.Household Carbon Footprints(19902019)Offer New Insights on Emissions Inequality and Climate Finance,”PLOS Climate,August 17,2023,https:/journals.

66、plos.org/climate/article?id=10.1371/journal.pclm.0000190.Figure:Mean US Household CO2e Emissions(2019)per Income GroupNatural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero6ATLANTIC COUNCIL2.The Role of Natural Gas in a Global Net-Zero Energy System 6 As of 2022,gas has replace

67、d coal as the primary resource for electric generation,supplying nearly 40 percent of US power.The IEA estimated that coal-to-gas switching globally avoided more than 500 million tons of CO2 emissions between 2010 and 2018,which is roughly equivalent to the total energy-related emissions of all Cent

68、ral American countries over the same period.“The Role of Gas in Todays Energy Transitions,”International Energy Agency,July 2019,https:/www.iea.org/reports/the-role-of-gas-in-todays-energy-transitions7 John E.T.Bistline and David T.Young,“The Role of Natural Gas in Reaching Net-Zero Emissions in the

69、 Electric Sector,”Nature,August 12,2022,https:/ John E.T.Bistline,“Roadmaps to Net-Zero Emissions Systems:Emerging Insights and Modeling Challenges,”Joule 5,10,25512563(2021),https:/ Bistline and Young,“The Role of Natural Gas in Reaching Net-Zero Emissions in the Electric Sector.”10 Daniel Bush,“Th

70、e Future of Gas Generation in an Increasingly Decarbonized World,”Burns McDonnell,November 21,2022,https:/ Maintaining reliable electricity delivery within a specific price threshold is also a legal mandate in many markets.12 Bistline and Young,“The Role of Natural Gas in Reaching Net-Zero Emissions

71、 in the Electric Sector.”Note:The International Energy Agency calculates this figure at 55 percent.Gas is important for todays energy system,repre-senting about a quarter of total energy demand in Europe and a third in the United States,while de-livering a flexible and reliable supply of electricity

72、 and heat.It is also largely responsible for emissions reduc-tions over the past twenty yearsspecifically by replacing coal,underscoring its role to date as a transition fuel.6 Yet as energy systems move toward deep decarboniza-tion,legitimate questions remain about the role of gas within viable pat

73、hways to meet the targets of the Paris Agreement.Indeed,it is important to differentiate between the role of gas during the bridge or transition period and its function in the long term.When it comes to the former,the shorter the transition period,the more important gas is to achieving net zero.The

74、evidence shows that accel-erating decarbonization to reach net zero in 2035 entails greater contributions from natural gas than delaying that goal to 2050.7Natural Gas in a Decarbonized Power SystemNatural gas(combined with CCUS)underpins the timely achievement of a net-zero power system,which is ke

75、y to economy-wide decarbonization.8 The target dates set by some major countries to reach net-zero emissions in the power system are little more than a decade offin the United States,Canada,the EU,and the United Kingdom(UK)by 2035.Gas capacity and generation can play key roles in decarbonizing these

76、 electricity systems both during the transition and in the decarbonized system.The extent to which gas will contribute to decarbonization de-pends on policy design,availability of carbon removal,abil-ity to mitigate upstream methane emissions,and transition risks related to technological change.9 Bu

77、t fundamentally,decarbonization and degasification are not the same thing.Gas will continue to provide key flexibility for balancing a decarbonized grid.Gas-fired power units can provide firm and flexible capacity to ensure system dependability with additional renewable energy and meet rising elec-t

78、ricity demand as end-use electrification spreads across the economy.As the share of variable renewable energy(VRE)increases,intermittency becomes a more seri-ous issue across the grid,and firm capacity is needed to step in when lack of sun or wind means production drops below demand.Maintaining powe

79、r quality by reg-ulating rapid swings in voltage and frequency is also key.Synchronous condensing equipmenta standard option on certain types of gas turbinescan resolve power-qual-ity issues by keeping alternating current and voltage waves properly synced on the grid.10 Upgrades to existing gas-powe

80、red infrastructure would reduce emissions and help cope with the variation and fluctuation brought by renewables.If it is to succeed,the energy transition needs to maintain the reliability and affordability of power delivery,and so the role of gas-fired power must be considered and com-pared within

81、the context of alternative tools for flexibility,such as large-scale energy storage.11 In that context,the costs of achieving net zero without gas rise very quickly,especially as the timeline is shortened,or in regions with lower-quality renewable resources.In their 2022 study for the Electric Power

82、 Research Institute(EPRI),John Bistline and David Young compared investment and cost outcomes for net-zero decarbonization in the United States against a carbon-free scenario in which generation from natural gas and CCS are prohibited,and found that the latter scenario requires more than 1300gigawat

83、ts(GW)of cumulative in-vestments in solar,wind,new nuclear,hydrogen,and bat-tery storage by 2035,along with$300 billion of additional annual generation expenditures($1.6 trillion total)and an extra$100 billion in bulk transmission investment per year.12 Natural Gas and the Energy Transition:Security

84、,Equity,and Achieving Net Zero7ATLANTIC COUNCILAs the transition progresses,the value of natural gas shifts from providing energy itself to providing capacity for grid flexibility,thus requiring less gas overall.Natural gas ca-pacity factors decline by roughly 50 percent from current levels under Bi

85、stline and Youngs deep-decarbonization scenario,as natural gas plants are deployed as peakers rather than as baseload suppliers.13 This will require new business models to make operating peaker plants viable.Their function is to quickly add power to the grid when needed to make sure that electricity

86、 is readily available.In a grid marked by high shares of VRE,peaker plants will be critical,if only occasionally needed,making it neces-sary to maintain low-utilization gas-generation capacity as insurance.Who will pay for that value to an increasingly disaggregated system is an ongoing issue.Natura

87、l Gas for Industrial UsesWhile the power sector is crucial for keeping open the path to a net-zero economy,it represents only about a quarter of global emissions.Industrial emissionsand those from agriculture,transportation,and heatingalso need to be addressed.Natural gas plays a role in all of them

88、,and is an important feedstock for the production of chemicals and fertilizers.Three heavy industriescement,chemicals,and steelmak-ingare particularly tricky to clean up.They require very high temperatures for chemical processes,which today are generated almost exclusively by burning fossil fuels.Fo

89、r example,producing certain high-value chemicals re-quires temperatures close to 1,000 degrees Celsius and blast furnaces producing steel operate at temperatures even above 1,500 degrees Celsius.In a net-zero economy,energy efficiency and technologies like CCUS can be applied to reduce industrial em

90、issions from natural gas.But ideally,switching to zero-emissions alternative fuels or sources like hydrogen or bioenergy would provide a clean alternative.Yet when it comes to fuel switching in these sectors,mov-ing away from coal and oil is relatively easy,while switching away from gas in the immed

91、iate term(while attractive on its face)would be difficult.The use of bioenergy solids,liquids,or gases,such as biomethane,is promising in some appli-cations,and making them with sewage sludge,food waste,13 Ibid.14 Elena Verdolini,et al.,“Industrial Deep Decarbonization:Modeling Approaches and Data C

92、hallenges,”Resources for the Future,August 16,2023,https:/www.rff.org/publications/reports/industrial-deep-decarbonization-modeling-approaches-and-data-challenges/.15“First electric cars.Next,electric factories?”Economist,February 15,2024.https:/ DW Documentary,“Power Failure in Germany:Horror Scena

93、rio or Genuine Possibility?”YouTube video,September 1,2023,https:/ decaying matter is a positive example of circularity.But their production process emits carbon and their supply at scale faces significant challenges,including the availability of land for bioenergy crops,water needs,the necessity to

94、 adapt crops to a changing climate,and the ability to trans-port and store large quantities of such crops.14 Additionally,one must not lose sight of the scale of po-tentially electrifying heavy industry.Direct electrification may play a part if nascent technologies can improve and scale,but for now

95、electrifying the hardest industrial pro-cesses means making molecules from electricity.15 BASF,a German chemical and plastics firm,uses about 6 ter-awatt hours(TWh)at its Ludwigshafen production site,which includes three onsite gas plantsabout 1 percent of Germanys energy consumption.If it and its d

96、omestic competitors were totally electrified,they would need three times their current energy-generation capacity,and the sectors energy consumption would reach 600 TWh,or as much as all of Germany uses today.To electrify Germanys chemical industry,the entire countrys power consumption would need to

97、 double.16 Domestic renewable energy will be part of the solution,as will complex international physical networks of power in-terconnectors,pipelines,and ships to bring in clean energy produced abroad,such as in the form of hydrogen.Those are huge investments to make,build,and scale in decades,much

98、less years.Their similar physical state means that much of the gas midstream infrastructure system can be shared or possibly repurposed for hydrogen in the future,but an international clean hydrogen economy simply does not currently exist.And yet the most promising zero-emissions alternative for suc

99、h“hard-to-abate”sectors is indeed hydrogen,which can be produced from various sources including natural gas with CCS(called blue hydrogen)and renewable en-ergy via electrolysis(green hydrogen).While green hy-drogen is ultimately the optimal solution,its enormous renewable energy generation capacity

100、needs and produc-tion costs mean that,over the next ten years,blue hydro-gen will present an attractive cost of abatement.In the coming years,the utilization of blue hydrogen has the potential to boost hydrogen demand and expand mar-kets,expediting the process of decarbonization.Looking ahead to 205

101、0,there will be a gradual phase-out of natural Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero8ATLANTIC COUNCILgas,with blue hydrogen increasingly making way for green hydrogen and renewable methane.17 The rate at which green hydrogen can supplant blue depends partly on

102、how fast all direct electricity demand can be met by renewable sources(as each marginal kilowatt will do more good on the grid),and the rate of the subsequent build-out of re-newables.Any substantial increase in green hydrogen production prior to achieving full renewable coverage for direct electric

103、ity leads to an indirect rise in fossil-fired gen-eration.Of course,the calculus would shift if policymakers were to limit the use of blue hydrogen by law.Low-Hanging Fruit:Abatement Costs by Decarbonization Measure In a fully decarbonized net-zero economy,there will still be an important role for n

104、atural gas,even if the demand 17“Gas for Climate:The Optimal Role for Gas in a Net-Zero Energy System,”Navigant,March 2019,iv,https:/www.europeanbiogas.eu/wp-content/uploads/2019/11/GfC-study-The-optimal-role-for-gas-in-a-net-zero-emissions-energy-system.pdf.18“Net Zero Emissions by 2050 Scenario(NZ

105、E),”International Energy Agency,last visited February 13,2024,https:/www.iea.org/reports/global-energy-and-climate-model/net-zero-emissions-by-2050-scenario-nze.19 In its 2022 update,the IEA clarified that decarbonizing the energy system begins with changes in demand,which lead to significant reduct

106、ions in fossil-fuel use by 2030 in the Net-Zero Scenario.This“demand-led”shift is not about reducing supply preemptively.“An Updated Roadmap to Net Zero Emissions by 2050,”International Energy Agency,last visited February 13,2024,https:/www.iea.org/reports/world-energy-outlook-2022/an-updated-roadma

107、p-to-net-zero-emissions-by-2050.will be smaller than todays.Overall,the IEAs Net-Zero Scenario(NZE)sees gas demand peaking before 2030,and by 2050 falling to 55 percent below current levels.18 While the IEA insists,as it does with oil,that a net-zero tra-jectory should not require new gas-field deve

108、lopment,that concept is often misunderstood to mean that new devel-opment should be curtailed.The point is that,under such a scenario,alternatives are scaled and in place(currently,they are not).19 In the crucial transitional period,sequencing matters.While some in civil society might simply advocat

109、e for doing all things immediately no matter the cost,or cutting off supply of entire fuel categories,those approaches would have de-monstrably negative impacts on poorer,marginalized,and less-developed communities.In the real world of limited re-sources and trade-offs between communities,the impuls

110、e should be to focus first on the lowest-hanging fruit while Figure 1.GHG abatement costs for selected measures of the Sustainable Recovery PlanSource:“GHG Abatement Costs for Selected Measures of the Sustainable Recovery Plan,”International Energy Agency,last updated June 18,2020,https:/www.iea.org

111、/data-and-statistics/charts/ghg-abatement-costs-for-selected-measures-of-the-sustainable-recovery-plan.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero9ATLANTIC COUNCILasking tough questions about how to equitably expand the available resources(so that those who have the

112、means should pay and assume the financing risk).20Abatement costs can provide a simple,if rather crude,met-ric to identify these low-hanging fruit.21 In many cases,ap-plying CCS to existing facilities(such as power generation or industrial plants)presents the cheapest(or only)abate-ment option on th

113、e basis of a dollar per metric ton of CO2,while alternatives are much more expensiveespecially 20 This is generally true,with myriad caveats about sequencing;there are cases in which abatement potential and cost of abatement capital also play a role beyond the marginal cost of abatement.For further

114、analysis,see:Adrien Vogt-Schilb,Guy Meunier,and Stephane Hallegatte,“When Starting with the Most Expensive Option Makes Sense:Optimal Timing,Cost and Sectoral Allocation of Abatement Investment,”Journal of Environmental Economics and Management 88(2018),210233,https:/ Stephane Hallegatte,“What You N

115、eed to Know about Abatement Costs and Decarbonization,”World Bank,April 20,2023,https:/www.worldbank.org/en/news/feature/2023/04/20/what-you-need-to-know-about-abatement-costs-and-decarbonisation.“It is essential to understand that this approach is fundamentally marginal.It was designed to reduce ma

116、rginal emissionsBut the climate objective is to reduce emissions to almost zero in order to achieve carbon neutrality.In this case,this approach no longer meets the requirements and the abatement cost can lead us to select very inefficient options,especially marginal improvements that prevent us fro

117、m radically changing our modes of production.”Assessing the levelized cost of carbon abatement is a slightly better alternative.For further analysis,see:Julio Friedman,et al.,“Levelized Cost of Carbon Abatement:An Improved Cost-Assessment Methodology for a Net-Zero Emissions World,”Center on Global

118、Energy Policy,October 19,2020,https:/www.energypolicy.columbia.edu/publications/levelized-cost-carbon-abatement-improved-cost-assessment-methodology-net-zero-emissions-world/.22 Adam Baylin-Stern and Niels Berghout,“Is Carbon Capture too Expensive?”International Energy Agency,February 17,2021,https:

119、/www.iea.org/commentaries/is-carbon-capture-too-expensive.where flexible gas power plants are performing valuable functions like managing seasonal variations in renewable generation.22 In the wider scheme,focusing on electrified public trans-port,building retrofits,and improving industrial energy ef

120、ficiency have a much greater impact on the marginal emissions reduction per dollar than efforts to eliminate all natural gas.That is particularly pertinent in places where resources and financing are constrained.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero10ATLANTIC C

121、OUNCIL3.Market and Regional Variations One Size Wont Fit All23“Financing Clean Energy Transitions in Emerging and Developing Economies,”International Energy Agency,June 2021,https:/www.iea.org/reports/financing-clean-energy-transitions-in-emerging-and-developing-economies.24 Ibid.25“The Choice betwe

122、en a Poorer Today and a Hotter Tomorrow,”Economist,June 27,2023,https:/ Gas Development in Low-Carbon Energy Transition,”Commonwealth Secretariat,2023,https:/production-new-commonwealth-files.s3.eu-west- to varying geographies,power market mod-els,and development trajectories,it is necessary to appr

123、oach decarbonization pathways in a tai-lored manner.That is especially the case when it comes to natural gas,which presents very different cost implications and trade-offs depending on where and for which applications it is being used.Emerging and developing countries represent a very di-verse group

124、.They typically consume low amounts of en-ergy per capita(sometimes as low as 3 percent of that of North Americans),but economic growth and rising in-comes hold significant potential for future growth.As a result,absent strong action to transform their energy sys-tems,these countries will account fo

125、r the bulk of emissions growth in the coming decades.The challenge is to embark on a more sustainable growth trajectory,with development models that adequately address the aspirations of their citizens while avoiding the emissions-intensive activities of historical economic growth.The falling cost o

126、f key clean energy technologies offers a tremendous opportunity to chart a new,lower-emissions pathway for growth and prosperity.23 Rapid advancements in renewable energy,efficiency,and widespread electrification play a pivotal role in cli-mate-driven scenarios.However,these measures alone cannot en

127、sure achieving the necessary emissions reduc-tions.Complementary transitions in fuels and emissions-in-tensive sectors are crucial,but also particularly difficult in emerging and developing economies undergoing rapid industrialization and urbanization.Plus,some of those sec-tors are referred to as“h

128、ard to abate”precisely because options for emissions reduction are less mature and still expensive.24Gas-Producing Developing CountriesEmerging and developing countries include some of the largest hydrocarbon producers.Gas producers in devel-oping countries are typically low greenhouse-gas emitters,

129、have comparatively low levels of electricity access,use sig-nificant proportions of gasoline and heavy fuel oil for off-grid electricity generation,and have relatively low access to clean fuels and technologies for cooking.They also rely on the revenue from fossil fuelswithout it,at least a dozen po

130、or countries would face unmanageable debt burdens.25 The comparatively modest levels of emissions from some low-income and lower middle-income economies(with high reserve-to-production ratios and pressing developmental needs,such as poverty eradication or closing the energy access gap)can justify po

131、licy approaches that allow for continued gas development alongside sustainable mea-sures for curbing carbon emissions.26 In some gas-rich countries,such as Iraq and Libya,wars have devastated national infrastructures,creating an ur-gent need for baseload power and grid improvements,es-pecially to me

132、et their summer peak demand.In the case of Iraq,the rate of electrification is relatively high,but is pow-ered mostly by off-grid fossil fuels.The country has one of the highest per-capita usage levels of diesel generators.Repairing existing infrastructure to deliver natural gas over oil-fired gener

133、ators would expand access and raise service quality,while significantly lowering emissions and benefit-ing a key domestic industry and employer.However,in developing countries,gas producers and investors in those sectors must also recognize the risks.Depending both on gas economics dictated by the s

134、peed of the global transition and on policies that could impact access to markets and finance,long-term gas projects risk becoming stranded assets.Where gas exports represent a particularly high share of export and government revenues,the potential for demand and revenue shocks expose the country to

135、 vulnerabilities at the hands of global markets.Indeed,demand shocks represent the exporters corollary to the volatility exposure felt by importers after the recent invasion of Ukraine.Finally,countries that depend on gas production could face emissions-related challenges,like missing their own targ

136、ets or pledged nationally determined Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero11ATLANTIC COUNCILcontributions(NDCs).That reinforces the need to couple any gas production with a mitigation strategy that might include using domestic gas to replace high-polluting coal

137、 or heavy fuel oil,increasing energy efficiency,and improv-ing energy access.Energy-Importing Developing CountriesAmong developing country consumers and importers,the value of using natural gas(and thus its relative alternative abatement cost)depends on factors like the power mar-ket model and the r

138、ole of industrialization in the countrys specific development phase.In countries with low levels of energy access outside of major cities and far from grid connections,distributed and off-grid renewable energy(DRE)can provide a cost-effec-tive solution to accelerate clean energy access.Over the last

139、 ten years,20 percent of all new electric connections 27“Off-Grid Solar Market Trends Report 2022:Outlook,”World Bank,2020,https:/www.lightingglobal.org/resource/off-grid-solar-market-trends-report-2022-outlook-part-2/.28 As a result,most gas-plant additions in Africa are combined-cycle gas turbines

140、,that cost more to build and cannot be ramped up so quickly,but use fuel more efficiently and run at higher capacity.in sub-Saharan Africa have been through DRE systems,and that is expected to rise to 50 percent over the next decade.27 However in most cases,energy poverty will still be allevi-ated b

141、y expanding grid access,especially in the contexts of population growth and rapid urbanization.Due to the extraordinary decline in renewable costs,and with rising demand in places like sub-Saharan Africa,renewables(at grid scale)are often cheaper in these cases as well.While accompanying grid flexib

142、ility is needed to enable such renewable growth,so is generation capacity itself.In advanced economies,the question might be whether and how to run gas peakers.But in many African countries,where there is often a lack of access to reliable energy,building a gas plant that will run only 20 percent of

143、 the time would be difficult to justify.28 In a 2021 paper by the CDC Group,the authors explain why decarbonization in many African countries is different Population with access to electricity(%):Under 10%10%to 49.9%50%to 99.9%100%Not applicapleTop 20 access-deficit countriesFigure 2.Share of Popula

144、tion with Access to Electricity in 2021Source:“Tracking SDG7:The Energy Progress Report 2023,”World Bank,2023,13,https:/cdn.who.int/media/docs/default-source/air-pollution-documents/air-quality-and-health/sdg7-report2023-full-report_web.pdf.Natural Gas and the Energy Transition:Security,Equity,and A

145、chieving Net Zero12ATLANTIC COUNCILfrom the energy transition in other emerging markets,cit-ing the very low base from which many of them start and the need to rapidly expand generation capacity to meet urgent development objectives.Advanced economies,by contrast,face relatively flat demand and alre

146、ady have so-phisticated power systems.Over time,these countries can decommission fossil generation while adding VREs.Many African countries do not have this opportunityrather,they need to multiply their output several times in just a couple of decades.29 Among the models for system transition in Afr

147、ica that aim for net zero by 2050 while rapidly expanding generation capacity for economic development,all include a com-bination of power-generation technologiesincluding cleaner fossil fuels.Under one model that takes a strin-gent approach to controlling emissions,between 2030 and 2050 Africa woul

148、d need to add 24 GW of solar,20 GW of wind,and 18 GW of gas.30 Other models come to similar conclusions.31 All scenarios require rapid and sustained investment in wind,solar,batteries,national and international transmission infrastructure,and net-work-management technologies.But some investments in

149、firm and dispatchable capacity(on which rich countries all currently rely)will also be key.Countries lacking large hydropower or geothermal resources that could other-wise provide that capacity will require some investments in natural gas-fired generation.32 As the president of the African Developme

150、nt Bank(AfDB)wrote in a recent IEA report,“As we accelerate the development of our massive 29 Martin Kitetu,et al.,“Decarbonizing Africas Grid Electricity Generation,”CDC Group,May 2021,https:/ Bob van der Zwaan,et al.,“An Integrated Assessment of Pathways for Low-Carbon Development in Africa,”Energ

151、y Policy 117(2018),387395,https:/ Gregor Schwerhoff and Mouhamadou Sy,“Developing Africas Energy Mix,”Climate Policy 19,1,(2019),108124,https:/ideas.repec.org/a/taf/tcpoxx/v19y2019i1p108-124.html.32 van der Zwaan,et al.,“An Integrated Assessment of Pathways for Low-Carbon Development in Africa.”33“F

152、inancing Clean Energy in Africa,”International Energy Agency,September 2023,https:/ Kitetu,et al.,“Decarbonizing Africas Grid Electricity Generation.”renewable energy sources,Africa must also be given time to transition and allowed to use its natural gas as a tran-sition fuel.”33 In the context of r

153、apidly rising electricity demand(known as a vertical transition),additional gas resources will be needed to enable large-scale renewable energy outlays before being phased out in the future.However,in econ-omies where overall demand stays flat(a horizontal tran-sition,as in most OECD countries),gas

154、phaseout should begin now.34 High rates of population growth,urbanization,and de-velopment all contribute to very high rates of energy de-mand growth in sub-Saharan Africa.Consumption patterns will also vary within Africa according to geography,and depending on the local types of economic activity,g

155、ov-ernance capacity,and development trajectory.As coun-tries develop,electricity demand will rise fastest on the grid where productive activity and incomes are relatively higher,and also based on the probability of electricity up-take by small and medium enterprises(SMEs)in the region.Meeting that d

156、emand will require 30 GW of natural gas power generation capacity additions by 2030 under the IEAs Sustainable Africa Scenario,alongside major renew-able energy expansion.It is worth noting that in developing countries like Indiawhere the government has avoided rapidly expanding natural gas to displ

157、ace coal,and instead focuses on 05001000150020002020202520302035204020452050Horizonal Transition CoalGasRenewablesTotalRenewables shareTWh05001000150020002020202520302035204020452050Vertical Transition CoalGasRenewablesTotalRenewables shareTWhTWhFigure 3.Stylized depiction of a horizontal(left)versu

158、s a vertical(right)grid energy transitionSource:Kitetu,et al.,“Decarbonizing Africas Grid Electricity Generation,”4.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero13ATLANTIC COUNCILrenewable energy outlays to meet growing demand and address energy accessaddressing shortf

159、alls and secu-rity means reverting to the worst possible option.As the country heads into elections during April and May,Prime 35 Askshat Rathi,“Indias Plans to Double Coal Production Ignore Climate Threat,”Bloomberg,January 9,2024,https:/www.bnnbloomberg.ca/india-s-plans-to-double-coal-production-i

160、gnore-climate-threat-1.2019558.Minister Narendra Modi is keen to avoid any risks of power shortages,and so the government has pledged to add 88 GW of thermal plants by 2032 while doubling coal output by 2030.35Source:“African Energy Outlook 2022,”International Energy Agency,2022,92,Figure 2.21,https

161、:/ 30 80 130GW2021-302011-202021-302011-20RetirementsAdditionsCoalNaturalHydroWindSolar PVOilOtherlow emissionsFossil fuelsLow emissionsFigure 4.Power generation capacity additions and retirements by source in the IEA Sustainable Africa ScenarioNatural Gas and the Energy Transition:Security,Equity,a

162、nd Achieving Net Zero14ATLANTIC COUNCIL4.Financing Sustainable and Equitable Development in Line with Energy Transitions 36 Miles McCormick,“Rising Costs and Competition Threaten US Boom in LNG Projects,”Financial Times,April 17,2023,https:/ Ibid.38 Gautam Jain and Luisa Palacio,“Investing in Oil an

163、d Gas Transition Assets en Route to Net Zero,”Center on Global Energy Policy,March 2023,https:/www.energypolicy.columbia.edu/publications/investing-in-oil-and-gas-transition-assets-en-route-to-net-zero-2/.The financing needed to provide enough natural gas to meet demand while reducing emissions is e

164、normous.Even under the IEAs NZE,which op-timistically foresees no necessary investments in new oil and gas fields,more than$120 billion per year is still needed for upstream gas investment through 2030.An additional$100 billion is needed each year for the trans-port networks.Broadly,natural gas proj

165、ects in more mature markets are financed partly from gas companies own balance sheets(particularly when they are flush,as they are today),and partly from equity or debt financing.In the United States,intense competition among developers along with esca-lating costs are complicating efforts to bring

166、new LNG online,despite a huge appetite for US fuel exports.36 Dramatic cost increases for large energy infrastructure projects and higher interest rates mean that financing needs are even greater,while struggles to secure the necessary commitment from offtakers force financiers to weigh long-term de

167、mand as the world commits to rapid decarbonization.Hesitancy by off-takers is not because the gas isnt in high demand;rather,it is due to anxious European buyers who elect to secure near-term LNG supplies rather than lock in the multi-decade contracts that developers need in order to secure financin

168、g for their projects.37 At the same time,the cash windfall to private oil and gas majors(IOCs)in 2022 has scarcely been reinvested in production,because of efforts to maintain profitability and capital discipline after years of poor returns for equity investors.Consequently,higher profits have been

169、allocated to debt reduction,div-idend payments,and repurchasing stocks.These choices highlight a firm commitment to capital discipline,and also reflect a degree of pessimism among some shareholders regarding the long-term value of oil and gas assets.38State-owned energy companies(NOCs)in the Middle

170、East and other emerging economies have been reinvesting more heavily in production,accounting for well over half of total investments in 2022.In richer parts of Asia and Europe,some public financing support for domestic gas projects might come from national or regional govern-ments,or from home-base

171、d development banks.200 4001991-20012001-20102011-20202021-20302031-20402041-2050Billion USD(2019)TransportExistingNewFieldsSource:“Net Zero by 2050,”International Energy Agency,May 2021,103,Figure 3.4,https:/www.iea.org/reports/net-zero-by-2050.Figure 5.Investment in natural gas supply in the NZENa

172、tural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero15ATLANTIC COUNCILGas projects in developing countries,such as those in Africa,are typically financed through a combination of sources,including private investment,international oil and gas companies,export credit agencies,and

173、 devel-opment banks.The role of multilateral or national devel-opment banks is significant in providing financial support and promoting sustainable development in these projects.Export credit agencies(ECAs)from the home countries of investors or buyers may provide financing or insurance to support t

174、he export of gas or related products.All this helps to de-risk projects and make them attractive to private fi-nance,which is still difficult to attract for independent and local players across regions including Africa.Compared to the oil and gas majors,which were squarely driving activity on the co

175、ntinent in 2023 thanks to their balance sheets,smaller or project-specific companies must demonstrate excellent cost,management,and ESG credentials(inclu-sive of efforts to reduce emissions)in order to attract any lending as international banks continue their retreat.Finance Restrictions from North

176、onto SouthPolicies of public financing institutions send clear signals to private markets,and so the policy-based financing 39 Among global private-sector investors,major global banks have committed to aligning their lending and investment portfolios to meet net-zero emissions by 2050.A significant

177、number have also committed to meeting intermediate targets as part of the Glasgow Financial Alliance for Net Zero(GFANZ),which aims to reduce their financed emissions in the oil and gas sector by 2030.Such targets imply increased scrutiny of fossil-fuel activities,but an Economist Impact study found

178、 that among the largest banks around the world,only a few were actively phasing out high-emitting projects.Even so,very little went to projects in developing countries,as the same banks and major asset managers reassess their risk profiles and follow policy signals.40 BPI France;Swedish EKN;UK Expor

179、t Finance(UKEF);Spanish CESCE;Swiss SERV;Finnvera Finland.41 Sarah George,“UK Export Finance Marks First Fossil-Fuel-Free Allocation Year,Sets New Emissions Targets,”edie,July 1,2022,https:/ that risk curtailing even net-zero compliant gas investments get compounded.39 European ECAs are broadly stri

180、ct on the issue,but some make exceptions for gas-fired power generation“which improves a countrys en-ergy mix,”“has documented and realistic transition plans,”“intends to follow best practice,”“includes CCS,”“is viable at a shadow carbon price,”“replaces production with higher emissions,”and broadly

181、 which meets the EUs Taxonomy(hence the importance of the European Commissions 2022 decision).40 Some ECA decisions are contingent on the presence of specific national regulations,such as a net-zero target to 2050,and risk becoming inflexible box-checking exercises that exclude entire countries whil

182、e failing to ac-count for a projects emissions contribution.Projects that meet some combination of these requirements might re-ceive support,but in cases such as in the UK,the result is still an effective freeze on natural gas financing overseas.41 The largest multilateral development banks are even

183、 stricter,coming very close to outright bans while still pro-viding avenues in theory.In November 2019,the European Investment Bank(EIB)announced its intention to stop fi-nancing fossil fuel projects,including natural gas,by the end of 2021.The World Bank ended upstream gas financ-ing after 2019 and

184、 has been under extreme pressure to Figure 6.Selected MDBs commitments to the gas sector,2008-2021-2 4 6 8 10 12 14 16 182008201020112012201320142015201620172018201920202021Billion USDCDBCDB-CHEXIM Co-financingCHEXIMADBAfDBAIIBEBRDEIBIADBNDBWorld Bank2009Source:Cecilia Springer,“Who Funds Overseas G

185、as Projects?Comparing Development Finance from China and Major Multilateral Development Banks,”Boston University Global Development Policy Center,June 2022,8,Figure 1,https:/www.bu.edu/gdp/files/2022/06/GEGI_PB_020_EN.pdf.Data is from the 2022 edition of the Chinas Global Energy Finance Database.Nat

186、ural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero16ATLANTIC COUNCILend all financing of fossil fuelsbut is apparently reconsid-ering gas projects that meet strict criteria,including some in Mozambique,where 30.6 percent of people had access to electricity in 2020.In practice,

187、financing from these institutions has stoppedand even ones backed by China have essentially elimi-nated their commitments.Yet there are some exceptions among development fi-nance institutions.For instance,certain regional develop-ment banks,such as the Africa Finance Corporation and Afreximbank,are

188、more lenient than their larger counter-parts and continue to support financing of gas projects,including upstream field developments.Such regional banks,including the AfDB,seem more willing to take into account Africas infrastructure deficit and challenging op-erating environment.In some cases,restr

189、ictive development financing poli-cies might represent a lack of understanding about coun-try-specific realities.Some institutions,like the World Bank,contend that their aim is to maximize regional financing for energy transition and enhance the role of local and regional banks.On the other hand,it

190、is also the result of an epic fight for resources within such institutions between those who believe development banks should focus on alleviating poverty and those who want to retool the in-stitutions as wholehearted instruments of climate change mitigation.42As the IEA states,“Natural gas occupies

191、 a difficult space in EMDE clean energy transitions.It is seen in many cases by these countries as an ally in the push for national develop-ment and lower-emissions growth,but projects will need to demonstrate a strong alignment with transition objectives;fi-nancing criteria for gas projects are tig

192、htening.Around 90%of project debt for large-scale natural gas infrastructure proj-ects in EMDEs over the last decade has been raised interna-tionally,and 70%of the total came from entities domiciled in countries that now have net zero targets.”4342“How Misfiring Environmentalism Risks Harming the Wo

193、rlds Poor.”43”Financing Clean Energy Transitions in Emerging and Developing Economies.”44 NIMBYs are those with a“not-in-my-backyard”attitude.“The Case for an Environmentalism that Builds,”Economist,April 5,2023,https:/ is true,insofar as wealthy countries and institutions that are actively cutting

194、off such financing are responsi-ble for hindering lower-emissions development plans designed by countries themselves.Higher prices for elec-tricity would dampen economic development,restrict access to essential services that require power(such as healthcare),and lower the standard of living across t

195、he continent more generally.Meanwhile energy-intensive in-dustries,which are especially good at raising living stan-dards,would be effectively shut out of national economic futures.That kind of shifting of risk,cost,and lost oppor-tunity from rich countries onto poor ones appears callous,especially

196、among those who consume 36 percent of the energy per capita that North Americans or rich Europeans do.At the 2022 climate conference in Sharm-el-Sheikh,the recurring message during that“African COP”was that out-siders do not generally appreciate the needs and views of developing countries,whether th

197、ey are idealistic young climate campaigners or Western governments with myriad colonial pasts.The main achievement at COP27 for ad-dressing equity was a new“loss-and-damage”fund;while not large,it was a welcome gesture.More importantly,it was an overdue acknowledgment that Africans should have a voi

198、ce in which energy they make and use,particu-larly if the technology burns cleaner than almost all power plants in OECD countries.Within the environmental activist community,the energy transition has posed trade-offs that can pit internal con-stituents against each otherthe need for massive con-stru

199、ction projects that enrage NIMBYs,the pressing need for rapid expansion of mining with all its social and en-vironmental risks,and the practical(if occasional)conflict between the equitable empowerment of underprivileged communities and an insistence on emissions reductions that might further repres

200、s them.44 Taking a practical ap-proach to comparing the value of abating a ton of CO2 with otherwise noble goals must necessarily be more inclusive of those directly involved.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero17ATLANTIC COUNCIL5.ConclusionsThe pace of the en

201、ergy transition is not solely de-termined by policy and cost.Factors such as in-frastructure,public perception,and availability of financing also play a role.In order to maintain af-fordability and energy security while also decarbonizing,renewable alternatives need to be ramped up quickly be-fore g

202、as supply is curtailed.Outside of the power sector,the alternatives can be too early stage,or require so much renewable generation that could otherwise be cleaning up the grid.The situation calls for maintaining a channel for public in-vestment and de-risking support for gas projects,includ-ing thos

203、e upstream and especially in developing countries.Conditions must ensure that those projects are as clean as possible,while recognizing market and regional variances.Phasing out cleaner and more value-producing natural gas too early can lead to dramatic price volatility,causing sim-ilar energy secur

204、ity and affordability crises to those felt in the wake of the invasion of Ukraine.Price instability can be an additional incentive to decouple the energy system from uncertain fuel markets,adopt renewable alternatives,and ultimately advance the energy transitionbut,in the near term,volatility can re

205、verse progress.Plus,the green transition became an easy target for misinformed voters looking for the cause of inflation and the energy crisis,when it was mostly unrelated.Where decarbonization pol-icies really do cause volatility and deprivations,the publics sensitivity to those trade-offs will bec

206、ome very clear.Natural gas has a limited,but important,role in maintaining both grid and price stability during the crucial transition phase to net zero;it even has a place in fully decarbon-ized economies.In poorer countries,the contribution of efficient natural gas use to development and industria

207、liza-tion has particular value.If limits on multinational financing are too strict,the impact on equitable access to prosperity will be immediate,and might be detrimental to the energy transition itself down the line.Natural Gas and the Energy Transition:Security,Equity,and Achieving Net Zero18ATLAN

208、TIC COUNCILAbout the AuthorPhillip Cornell is a nonresident senior fellow at the Atlantic Councils Global Energy Center.He is a specialist on energy and foreign policy,global energy markets and regulatory issues,critical energy infrastructure protection,energy security strategy and policy,Saudi Arab

209、ian oil policy,Gulf energy economics,and sustainable energy transition policy.He currently leads the global practice for energy and sustainability at Economist Impact,part of the Economist Group.Prior to joining the Atlantic Council,Cornell was a senior corporate planning advisor to the chairman and

210、 chief executive officer of Saudi Aramco,where he provided market analysis and business development support to the executive management during the implementation of Saudi oil price strategy.In that capacity,he also provided advice to the Royal Court in the context of Saudi economic transition and fo

211、reign policy.From 20112014,he was special adviser to the executive director of the International Energy Agency in Paris,responsible for strategic messaging and policy advice to the Executive Office of the IEA.Previously,he developed IEA simulations and wargaming among ministries in preparation for m

212、ajor oil and gas emergencies.Before joining the IEA,Cornell served with NATO as the senior fellow and director of international programs at the NATO School(NSO)in Oberammergau,Germany,where his policy research focused on NATO and energy security.During that period,he also served on the secretary gen

213、erals committee in Brussels to develop NATO policy in the area of energy infrastructure security.Cornell has held research positions at the Naval Postgraduate School(Monterey),the Royal United Services Institute(London),and the Center for International Security and Cooperation(Stanford),and he is th

214、e author of a number of articles and volumes on energy security and security policy.He holds masters degrees with distinction in international economics(energy focus)and European studies(security focus)from the Johns Hopkins School of Advanced International Studies.He received his BA cum laude in in

215、ternational relations from Stanford University.Board of Directors*Executive Committee Members List as of March 27,2024 CHAIRMAN?EXECUTIVE CHAIRMAN EMERITUS?PRESIDENT AND CEO?EXECUTIVE VICE CHAIRS?VICE CHAIRS?TREASURER?DIRECTORS?Jarosaw Grzesiak?HONORARY DIRECTORS?*Executive Committee Members List as

216、 of March 27,2024 CHAIRMAN?EXECUTIVE CHAIRMAN EMERITUS?PRESIDENT AND CEO?EXECUTIVE VICE CHAIRS?VICE CHAIRS?TREASURER?DIRECTORS?Jarosaw Grzesiak?HONORARY DIRECTORS?Natural Gas and the Energy Transition:Security,Equity,and Achieving Net ZeroC4ATLANTIC COUNCILThe Atlantic Council is a nonpartisan organ

217、ization that promotes constructive US leadership and engagement in international affairs based on the central role of the Atlantic community in meeting todays global challenges.2024 The Atlantic Council of the United States.All rights reserved.No part of this publication may be reproduced or transmi

218、tted in any form or by any means without permission in writing from the Atlantic Council,except in the case of brief quotations in news articles,critical articles,or reviews.Please direct inquiries to:Atlantic Council1030 15th Street,NW,12th Floor,Washington,DC 20005(202)463-7226,www.AtlanticCouncil.org