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A Green and Just Recovery from COVID-19?

Government Investment in the Energy Transition during the Pandemic

Published online by Cambridge University Press:  20 October 2023

Kyla Tienhaara
Affiliation:
Queen's University, Ontario
Tom Moerenhout
Affiliation:
International Institute for Sustainable Development
Vanessa Corkal
Affiliation:
International Institute for Sustainable Development
Joachim Roth
Affiliation:
International Institute for Sustainable Development
Hannah Ascough
Affiliation:
Queen's University, Ontario
Jessica Herrera Betancur
Affiliation:
Queen's University, Ontario
Samantha Hussman
Affiliation:
Queen's University, Ontario
Jessica Oliver
Affiliation:
Queen's University, Ontario
Kabir Shahani
Affiliation:
Queen's University, Ontario
Tianna Tischbein
Affiliation:
Queen's University, Ontario

Summary

Stimulus spending to address the economic crisis brought on by the COVID-19 pandemic has the potential to either facilitate the transition away from fossil energy or to lock in carbon-intensive technologies and infrastructure for decades to come. Whether they are focused on green sectors or not, stimulus measures can alleviate or reinforce socio-economic inequality. This Element delves into the data in the Energy Policy Tracker to assess the extent to which energy policies adopted during the pandemic will expedite decarbonization and explores whether governments address inequities through policies targeted to disadvantaged, marginalized and underserved individuals and communities. The overall finding is that the recovery has not been sufficiently green or just. Nevertheless, a small number of policies aim to advance distributive justice and provide potential models for policymakers as they continue to attempt to 'build back better'. This title is also available as Open Access on Cambridge Core.
Type
Element
Information
Online ISBN: 9781009319782
Publisher: Cambridge University Press
Print publication: 16 November 2023
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - ND
This content is Open Access and distributed under the terms of the Creative Commons Attribution licence CC-BY-ND 4.0 https://creativecommons.org/cclicenses/

1 Introduction

At the Carbis Bay G7 Summit in June 2021, governments of some of the richest countries in the world committed to ensuring that their economic recoveries would be green. They also pledged that “no place or person, irrespective of age, ethnicity or gender” would be “left behind.” They acknowledged that “[t]his has not been the case with past global crises,” but added that they were “determined that this time it will be different” (G7 2021).

In this Element, we explore energy policies adopted by governments (including those in the G7) during the COVID-19 pandemic that have the potential to reduce both greenhouse gas (GHG) emissions and inequality. Our overarching research question is: To what extent did governments consider the distributional effects of the energy policies adopted in 2020–1 and promote their policies as benefiting low-income households and other marginalized and underserved groups?

There have been several assessments of the “greenness” of the COVID-19 economic recovery (Reference O’Callaghan and MurdockO’Callaghan and Murdock 2021; Reference Nahm, Miller and UrpelainenNahm, Miller, and Urpelainen 2022). Our research adds to the literature by providing a preliminary assessment of the extent to which the green policies adopted have also been just, and by highlighting notable examples where equity has been incorporated into policy design. As governments are likely to continue to invest in COVID-19 recovery in the near term, and as they must continue to invest in the energy transition for the next thirty years at least, it is worth drawing attention to those policies that can potentially provide a model for addressing climate change and inequality simultaneously. The research also responds to the call to “develop research that sharpens our understanding of inequality as a theoretical concept and its concrete implications for earth system governance” (Reference Burch, Gupta and InoueBurch et al. 2019, 5).

We have two key objectives with this Element. First, we clearly articulate what a green and just economic recovery requires in policy terms. This is achieved through a review of the literature on green Keynesianism, green industrial policy, climate justice, and just transitions (Section 2). In addition to these broad literatures, we delve into the specific investment needs and justice/equity issues that are identified in the literature in five key areas: renewable energy, energy access, low-carbon mobility, energy-efficient buildings, and support for fossil fuel–dependent communities through worker retraining and reclamation activities. Second, we utilize data from the Energy Policy Tracker (EPT) to assess the extent to which governments adopted green and just energy policies in these five areas in the first two years of the COVID-19 pandemic (January 1, 2020–December 31, 2021) (Section 3). In addition to a quantitative assessment, we describe some examples of policies that endeavor to reduce GHGs and address inequality in greater detail.

1.1 A Green Recovery?

COVID-19 undeniably dominated politics, economics, and the everyday lived experience of most of the world’s population over the course of 2020–1. However, it was not the sole crisis confronting humanity in this period. The year 2020 tied with 2016 for the warmest year on record (Reference BrownBrown 2021) and temperatures reached an alarming 38°C in the Arctic in June (World Meteorological Organization 2021). The Atlantic experienced a record-breaking thirty named hurricanes (National Oceanic and Atmospheric Administration 2021). Australia and California suffered through their worst fire seasons in recorded history (Reference AnguianoAnguiano 2020; Reference PhillipsPhillips 2020). In 2021, hundreds of people on the West Coast of Canada died during a “heat dome” event (Reference WooWoo 2021). Parts of Europe were devastated by flooding and the Chinese city of Zhengzhou received a year’s worth of rain over the course of only three days (Reference MackMack 2021). Parts of Africa suffered instead from a lack of precipitation, with the multiyear Horn of Africa drought commencing in 2020 (Reference Kimutai, Barnes and ZachariahKimutai et al. 2023). Climate change, long thought of in abstract terms and as primarily a problem for future generations, established itself during the pandemic as a clear threat to the present.

The COVID-19 crisis, climate change, and the broader ecological crisis also intersect in multiple ways. It is widely acknowledged that continued encroachment on wild areas increases opportunities for pathogens to make the jump from animals to humans (Reference TollefsonTollefson 2020). Warming also expands the geographic scope of vector-borne diseases such as Lyme disease and malaria (Reference Bouchard, Dibernardo and KoffiBouchard et al. 2019; Reference Ryan, Lippi and ZermoglioRyan, Lippi, and Zermoglio 2020). Air pollution that results from burning fossil fuels causes health problems such as asthma that can increase the severity of impacts felt by individuals infected with viruses such as COVID-19 (Reference BernsteinBernstein 2020; Reference Chen, Wang and KwongChen et al. 2022).

Government measures adopted to contain the coronavirus also had impacts on air pollution, climate change, and biodiversity. As lockdowns curtailed economic activities worldwide, global GHG emissions dropped dramatically – by 17 percent in April 2020 (Reference Quéré, Corinne and JonesLe Quéré et al. 2020). Reductions in transport also led to a 60 percent drop in nitrogen dioxide and 31 percent drop in particulate matter levels in thirty-four countries, dramatically reducing local air pollution (Reference Venter, Aunan, Chowdhury and LelieveldVenter et al. 2020). The decline in traffic also substantially reduced wildlife mortality on roads (Reference Shilling, Nguyen and SalehShilling et al. 2021).

Pandemic restrictions destabilized several carbon-intensive industries, exacerbating challenges that they were experiencing prior to the crisis. For example, limits on international travel had a dramatic impact on aviation (McKinsey & Company 2022). Reductions in economic activity depressed oil prices, compounding the impacts of earlier economic contractions and price wars and leading to a “scale of the collapse in oil demand … [that] is well in excess of the oil industry’s capacity to adjust” (IEA 2020c). The reduction in energy demand also caused financial trouble for the coal sector, which was already struggling in many countries before the pandemic (Reference RowlattRowlatt 2020). Although these are industries that need to be rapidly phased-out to keep warming below 1.5°C, a completely unmanaged decline would have devastating impacts for many communities and a destabilizing effect on the global economy.

However, it now appears that these impacts were, by and large, temporary. Emissions began rebounding as soon as the first set of restrictions were eased in the major economies (Reference HarveyHarvey 2020). The fossil fuel industry recovered quickly, with coal power generation reaching an all-time high in 2021 (IEA 2021a). Demand for gas rose over 4 percent in 2021, erasing the losses in 2020 (IEA 2022a). While the oil market was considered less likely to return to “normal” post-pandemic (IEA 2021c), prices reached their highest levels in six years even prior to the war in Ukraine, which may increase investment in the sector. The recovery for the airline industry has been slower, but the International Air Transport Association expects the industry to return to profitability in 2023 (Reference JosephsJosephs 2021).

In addition to being short-lived, the environmental effects of the restrictions imposed on economic activity were insufficient to address the ecological crisis. Even though emissions were 6.4 percent lower in 2020 than they were in 2019 (Reference TollefsonTollefson 2021), this is still less of a drop than the 7.6 percent annual reduction required to meet the Paris Agreement 1.5°C objective (UNEP 2019). In effect, the pandemic starkly illustrated that emissions reductions on the scale required to keep below 1.5°C or even 2°C of warming cannot be induced through behavior changes (like driving less) alone and will require sustained government intervention to facilitate a fundamental transition away from fossil fuel production and consumption, toward low-carbon energy sources.

In this respect, potentially the most important impact of the pandemic is that it created an opportunity for governments to invest in measures that would simultaneously address the economic crisis and accelerate the energy transition. The acknowledgment early on by many economists, governments, and international organizations that substantial government spending would be required not only to keep businesses and individuals afloat during lockdowns but also to stimulate an economic recovery when activity was permitted to resume led to proposals for “green stimulus.” In March 2020, a survey of 231 finance ministers, central bank officials, and economists from across the G20 showed substantial support for green stimulus measures such as government spending on clean energy infrastructure (Reference Hepburn, O’Callaghan, Stern, Stiglitz and ZenghelisHepburn et al. 2020). Calls for a “green recovery” and to “build back better” were made by numerous international organizations, including the International Energy Agency (IEA), Organisation for Economic Cooperation and Development (OECD), World Bank, and International Monetary Fund. In late 2020, the EU set a target of 37 percent of its recovery to be focused on a green transition (Reference TaylorTaylor 2020).

In addition to the desire to address the climate crisis, experts noted that green stimulus can deliver more “bang for the buck” than traditional carbon-intensive industries, because renewable energy and energy efficiency are very labor-intensive sectors (Reference Pollin, Garrett-Peltier, Heintz and HendricksPollin et al. 2014; Reference Garrett-PeltierGarrett-Peltier 2017; Reference Pollin and ChakrabortyPollin and Chakraborty 2020). Green stimulus can also lead to economic savings (through lower energy costs) and spur innovation (Reference Allan, Donovan and EkinsAllan et al. 2020). Experts also emphasized that decisions taken in response to the COVID-19 crisis were critical because they would determine the world’s development patterns for decades to come. A green recovery was, therefore, not just about investing in green sectors but also about not providing further subsidies to carbon-intensive sectors (Reference Johnson, Shawoo, Talebian, Kemp-Benedict and LindblomJohnson et al. 2020; Reference Sanchez, Bridle and CorkalSanchez et al. 2021).

1.2 A Just Recovery?

The COVID-19 pandemic both highlighted and exacerbated long-standing health and social inequities across the globe. While this alone would explain why there is a need for the economic recovery to be just as well as green, it is also increasingly apparent that the ecological crisis is driven by socioeconomic inequalities. In addition to the fact that the richest segments of society are responsible for the largest share of GHGs, wealthy elites also work to obstruct and undermine public support for climate policy through their influence in government and the media (Green and Healy 2022). Thus, in addition to the moral argument that it is “unfair to allow disproportionate burdens to continue to fall on already marginalized groups (current or future), or to suppress their voices and values” (Reference Martin, Teresa Armijos and CoolsaetMartin et al. 2020, 20), there are also practical reasons to address social inequality and emissions reductions at the same time. Policy measures will only succeed if the public believes that they are fair and legitimate (Reference Martin, Teresa Armijos and CoolsaetMartin et al. 2020). Measures seen as hurting rural communities, the working class, and the poor, such as the fuel taxes in France that sparked the yellow-vest movement, are likely to be met with resistance (Reference Dimitris, Morena, Dunja, Morena, Krause and StevisStevis, Morena, and Krause 2019). Indeed, many green stimulus measures adopted following the global financial crisis (GFC) were unpopular because they were seen to primarily benefit large corporate actors and/or wealthier members of society (IEA 2020e). As noted by the IEA (2020e), “the broader social and distributional impacts of any stimulus programme will receive increased scrutiny” in the COVID-19 context because the pandemic has disproportionately impacted low-income earners.

Many groups appealed to governments to make the COVID-19 recovery not only green but also just and equitable. For example, in Canada and the United States, hundreds of environmental, justice, labor, and movement organizations agreed to a set of principles for a just recovery (see www.justrecoveryforall.ca). International organizations, such as the OECD, also made special mention of “well-being and inclusiveness” in their recovery proposals (OECD 2020a).

Our conceptualization of a “green and just recovery” draws on climate/energy justice and just transition literatures, which are explored in Section 2. While much of the just transition literature is focused on ensuring support for regions and communities economically dependent on fossil fuels as the world shifts to renewable energy, such a conceptualization is too narrow for our purposes. We do give particular attention to these communities, but in our view a green and just recovery must consider all populations that are vulnerable to the impacts of climate change and to the costs of the transition; existing inequities should be mitigated rather than reinforced. We therefore adopt the broader approach articulated by the Intergovernmental Panel on Climate Change (IPCC) that justice requires that “no people, workers, places, sectors, countries or regions are left behind in the move from a high carbon to a low-carbon economy” (IPCC 2022, 36).

1.3 Tracking the Recovery

The fact that there were numerous calls for a green and just recovery from the COVID-19 crisis from respected economists, academics, influential financial organizations, and civil society does not mean that this is what governments will deliver. As Reference Gunn-Wright, Prakash and GirgentiGunn-Wright (2020, 70) points out, “Policymaking is not a science. It is a fight over whose problems get addressed, how those problems are addressed, and how public power and resources are distributed.” In many countries around the world, key challenges related to complex energy reforms are political rather than technical. Stakeholders act to advance their own interests in power relationships associated with resource allocations. They support and block reforms accordingly. Lobbying for bailouts by fossil fuel firms and carbon-intensive industries such as aviation began almost as soon as the first COVID-19 lockdowns (see, e.g., Reference Speers-RoeschSpeers-Roesch 2020).

The GFC stimulus experience provides important lessons in this regard. The IEA (2020e) has noted that, overall, the recovery from the GFC was energy- and carbon-intensive. Reference TienhaaraTienhaara (2018) has demonstrated that in addition to the “dirty” stimulus funding, stakeholders, including large mining firms in Canada, the construction industry in Korea, and the fossil fuel industry in Australia and the United States, influenced the design and implementation of stimulus measures that were labeled “green.”

Initial indications are that the COVID stimulus is not an improvement on the GFC stimulus and may in fact contribute even less to emissions reductions (Reference O’Callaghan, Yau and HepburnO’Callaghan, Yau, and Hepburn 2022). The OECD (2020b) noted early on that governments were adopting a variety of concerning measures, including “plans to roll back existing environmental regulations … reductions or waivers of environmentally-related taxes, fees and charges, unconditional bailouts of emissions-intensive industries or companies … and increased subsidies to fossil-fuel intensive infrastructure … and electricity consumers.”

Several research groups and organizations have engaged in efforts to track the fiscal, monetary, and other policy measures that governments have developed in response to the COVID-19 pandemic. As these groups use different methodologies for determining what counts as a recovery measure, cover different countries, and define categories of green policies differently, they are difficult to compare (see Table 1). Nonetheless, the consensus appears to be that the outcome of recovery efforts to date has been disappointing and that the opportunity to “build back better” has been largely squandered. In October 2021, the groups behind four separate trackers signed a joint statement, noting that only 10–20 percent of stimulus could be classified as green and that “more effort is needed to secure a just and green recovery globally” (Energy Policy Tracker et al. 2021). The most recent study published (Reference Nahm, Miller and UrpelainenNahm, Miller, and Urpelainen 2022) found that the G20 group of the twenty largest economies spent at least $14 trillion on recovery measures, but only 6 percent of that (about $860 billion) was allocated to areas that will also cut emissions, and almost 3 percent went to activities that are likely to increase global emissions. Indeed, the IEA estimated in July 2021 that the implementation of economic recovery measures would result in record-level CO2 emissions in 2023 with “no clear peak in sight” (Reference FrangoulFrangoul 2021). On the other hand, it is worth noting that over time the amount of green stimulus has gradually increased (Reference Welker, Roth and GerasimchukWelker, Roth, and Gerasimchuk 2022) and there were substantial commitments to green spending made in the United States in 2022 that fall outside of the coverage of several trackers and this study (see brief discussion in Section 4).

Table 1 Comparison of green stimulus trackers

Name of tracker/weblinkDates coveredCountries coveredTotal stimulus analyzed (US$ trillion)Green stimulus (US$ billion)Proportion green
Energy Policy Tracker2020 and 2021G20+16+EU (+ 8 MDBs)1.3 (energy-related only)50339% of energy related
https://www.energypolicytracker.org
OECD Green Recovery DatabaseUp to end of March 2022OECD+63.3 (recovery spending)1.133%
www.oecd.org/coronavirus/en/themes/green-recovery
Vivid EconomicsUp to end of June 2021G20+1017.21,80010.5%
www.vivideconomics.com/casestudy/greenness-for-stimulus-index/
Global Recovery ObservatoryUp to mid-December 2022Fifty largest economies18.2 (total spending)9705% of total spending, 31.2% of recovery
https://recovery.smithschool.ox.ac.uk/tracking/3.1 (recovery spending)
Green Recovery Tracker2020 and 2021EU (18)0.86 (€0.72)252 (€225)29%
https://www.greenrecoverytracker.org/
IEA Sustainable Recovery TrackerUp to end of March 2022Fifty (IEA members +)18.27104%
www.iea.org/reports/sustainable-recovery-tracker
Nahm et al. study2020 & 2021G20148606%

Notes on coverage: EPT = G20 + Bangladesh, Chile, Colombia, Egypt, Estonia, Finland, Kenya, the Netherlands, New Zealand, Nigeria, Philippines, Poland, Spain, Sweden, Ukraine, and Vietnam; Vivid = G20 + Colombia, Denmark, Finland, Iceland, Norway, Philippines, Singapore, Spain, Sweden, and Switzerland; OECD = OECD + Costa Rica (Accession), Brazil, China, India, Indonesia, and South Africa.

1.3.1 The Energy Policy Tracker

For this Element we utilize the EPT, developed by the International Institute for Sustainable Development (IISD) in partnership with the Institute for Global Environmental Strategies, Oil Change International, Overseas Development Institute, Stockholm Environment Institute, and Columbia University. The EPT covers investments and other relevant policies adopted in thirty-seven countries and the European Union as well as eight multilateral development banks (MDBs) (we focus on countries). The EPT showcases publicly available information on public money commitments for different energy types, and other policies supporting energy production and consumption in the following sectors: resources (e.g., extraction of oil, gas and coal, pipelines as well as restoration of extractive sites), power, buildings, mobility (e.g., airlines, airports, car manufacturing, rail and public transport, and cycling and walking), and other energy-intensive sectors.

The EPT was generated through a bottom-up approach, which involved collecting data on individual policies at an individual country level, and then aggregating them. The database was regularly updated between January 1, 2020, and December 31, 2021. Only new policies or amendments of existing policies were included in the EPT, and the majority of policies represent government responses to the COVID-19 pandemic. However, policies that had been designed before the crisis and introduced as planned after January 1, 2020, were also included. Even though these policies may not be directly linked to the COVID-19 pandemic, the fact that they were introduced despite sociopolitical disruptions and economic downturn is noteworthy. Both the date a policy is announced and when it is passed are registered in the EPT. The amount of funding committed to a policy is tracked, as well as the amount dispersed. However, given the data available at the time of our analysis, we only report funds committed.

Policies in the EPT are classified according to different criteria. One of the key criteria is a policy’s environmental profile that depends on (1) which energy types it benefits, and (2) whether it has any environmental conditionality attached. Throughout the tracker, information is split across five categories: fossil unconditional, fossil conditional, clean unconditional, clean conditional, and other energy (see further Table 2).

Table 2 Policy categories

CategoryDescription
Fossil unconditionalPolicies that support production and consumption of fossil fuels (oil, gas, coal, “grey” hydrogen, or fossil fuel–based electricity) without any climate targets or additional pollution reduction requirements
Fossil conditionalPolicies that support production or consumption of fossil fuels (oil, gas, coal, “blue” hydrogen, or fossil fuel–based electricity) with climate targets or additional pollution reduction requirements. The conditionality includes climate and pollution reduction targets as well as support to measures reducing environmental damage through carbon capture, utilization and storage, and end-of-the-pipe solutions such as reduction of methane leakages, extractive sites cleanup, and other measures
Clean unconditionalPolicies that support production or consumption of energy that is both low-carbon and has negligible impacts on the environment if implemented with appropriate safeguards. These policies support energy efficiency and renewable energy coming from naturally replenished resources such as sunlight, wind, small hydropower, rain, tides, and geothermal heat. “Green” hydrogen, and active transport (cycling, walking) are also included
Clean conditionalPolicies that are stated to support the transition away from fossil fuels, but unspecific about the implementation of appropriate environmental safeguards. Examples include large hydropower; rail public transport and electric vehicles (electric cars, bicycles, scooters, boats, etc.) using multiple energy types; smart grids and technologies to better integrate renewables; hydrogen in the case of mixed, but predominantly clean sources; and biofuels, biomass, and biogas with a proven minimum negative impact on the environment (sometimes referred to as “advanced,” or “second,” or “third generation”). Without appropriate environmental safeguards, such policies can still have significant impacts. For instance, if powered with coal- or gas-based electricity, electric vehicle (EV) use is associated with significant emissions. Large hydropower has a negligible carbon footprint but can damage ecosystems. And even “advanced” biofuels can have a significant water footprint
Other energyPolicies outside of the two “fossil” and two “clean” buckets, or in both, fall in this umbrella category. These policies support nuclear energy (including uranium mining), “first-generation” biofuels, biomass and biogas (with proven negative impact on the environment), incineration, hydrogen of unspecified origin, and multiple energy types, for example, intertwined fossil fuels and clean energy (a sizable group, since many policies benefit both fossil and clean energy across the board)

1.4 Areas of Focus

For this research, we focus on policies in five areas that we identified as being the most significant for achieving decarbonization and reducing inequality: renewable energy, energy access, low-carbon mobility, energy-efficient buildings, and support for fossil fuel–dependent communities through worker retraining and environmental reclamation activities. Each of these categories is briefly explained below.

1.4.1 Renewable Energy

To facilitate an energy transition and achieve net-zero emissions by 2050, renewable energy technologies (e.g., solar, wind, hydro, tidal, and geothermal power) need to be developed and deployed on a large scale. In the IEA’s Net-Zero by 2050 pathway, renewable energy generation needs to triple by 2030 and increase more than eightfold by 2050 (IEA 2021 g). While this is a formidable challenge, the economics are favorable. Costs of renewable energy have fallen by an average of 18 percent annually since 2010 (Carbon Tracker Initiative 2021), undercutting the cheapest fossil fuels in many countries (IEA 2020h; IRENA 2021b). Although costs rose during the pandemic due to increased commodity prices and shipping costs, fossil fuel prices increased faster and thus the cost competitiveness of renewables still increased in this period (IEA 2022c). The International Renewable Energy Agency (IRENA 2021b) estimates that the 534 gigawatts of renewable energy capacity added since 2010 in emerging economies will reduce electricity generation costs up to $32 billion in 2021. Furthermore, the replacement of 800 gigawatts of coal-fired capacity would save $32 billion annually (IRENA 2021b). As electricity demand increases in emerging economies and new capacity is needed, renewable power generation projects will reduce costs by a minimum of $6 billion annually compared to the cost of adding the same capacity of fossil fuel–fired generation (IRENA 2021b). In addition to economic savings and GHG reductions, replacement of fossil fuels with renewable energy will reduce local air pollution, which in turn has positive impacts for human health and local environmental quality.

1.4.2 Energy Access

The IEA (2020g) defines energy access as “a household having reliable and affordable access to both clean cooking facilities and to electricity, which is considered enough to supply a basic bundle of energy services initially, and then increasing the level of electricity over time to reach the regional average.” Universal energy access is necessary to fulfill both social and economic development, to satisfy needs for health, lighting, cooking, space, comfort, mobility, and communication (Reference Edenhofer, Pichs-Madruga and SokonaEdenhofer et al. 2011). In 2022, 775 million people lacked access to electricity, which was an increase of 20 million people compared with 2021, reversing the downward trend of the previous decade (Reference Cozzi, Wetzel, Tonolo and HyppoliteCozzi et al. 2022). Sub-Saharan Africa is the region with the lowest levels of energy access and greatest need for international support.

1.4.3 Low-Carbon Mobility

Redesigning the transport sector is considered vital to global climate change mitigation strategies (US EPA n.d.; IEA 2021f). Transport accounts for 37 percent of CO2 emissions from end-use sectors and is more reliant on fossil fuels than any other sector (it is responsible for 57 percent of global oil demand) (IEA 2021e). Despite the stringency of COVID-19 lockdowns, which accounted for a 50 percent reduction of global road transport activity at the end of March 2020 and a 75 percent reduction in airline traffic in mid-April 2020 (IEA 2020d), mobility still accounted for 23 percent of energy-related CO2 emissions at the end of March 2021 (IEA 2021f). The high emissions rate of carbon-intensive transportation in all its forms not only exacerbates climate change but also comes with well-documented risks to human health, as PM 2.5 pollution contributes to poor air quality, which in turn impacts morbidity and mortality rates (IPCC 2014; Reference Mullen and MarsdenMullen and Marsden 2016). Shifting transportation regimes away from a reliance on fossil fuels has benefits that extend beyond GHG emissions reductions. Improving public transit systems likewise improves road safety and increases employment, while also decreasing traffic congestion, urban sprawl, and various forms of noise and air pollution (Reference Banister, Anderton, Bonilla, Givoni and SchwanenBanister et al. 2011; Reference Russo and BoutueilRusso and Boutueil 2011; IPCC 2014).

1.4.4 Energy-Efficient Buildings

The construction and operation of buildings account for 35 percent of global energy use and 15 percent of CO2 emissions (Global Alliance of Buildings and Construction 2021; IEA 2021d). Direct and indirect emissions from electricity and commercial heat used in buildings rose to 10 GtCO2 in 2019, the highest level ever recorded before dropping to 9Gt in 2020. The rise was driven by improved access to energy in developing countries, greater ownership and use of energy-consuming devices, and rapid growth in floor area. The drop in emissions in 2020 was primarily the result of less activity in the services sector during COVID-19 lockdowns and it is likely that emissions from this sector rebounded in 2021 (IEA 2021d). While space heating is currently responsible for around 45 percent of building-related emissions, energy demand for space cooling has more than tripled since 1990, making it the fastest-growing end use in buildings (Abergel and Delmastro 2020). The average temperature rise that comes with climate change is one of the factors contributing to increasing cooling service demand. There are clear links between building efficiency and inequality as low-income individuals and families are the most likely to live in inefficient homes, leading to higher heating and cooling costs as well as health impacts and reductions in quality of life.

1.4.5 Support for Fossil Fuel–Dependent Communities

While restructuring the energy sector to address climate change is likely to have a net-positive impact on employment, because more jobs will be created in sectors like renewable energy and energy efficiency than will be eliminated in sectors like fossil fuels, it is important to recognize that these shifts will create profound disruptions for affected workers and for communities and regions that are highly dependent on a single industry (UNFCCC Secretariat 2020). New green jobs may not appear at the same time or in the same location as old jobs are lost (UNFCCC Secretariat 2020). There are also understandable concerns from workers that they will be transitioning from unionized, high-paying jobs in the fossil fuel sector into nonunionized workplaces with lower wages and fewer benefits (Reference SahaSaha 2020). Policies in areas like worker retraining and income support are therefore needed to buffer the impacts of the energy transition and minimize human suffering (UNFCCC Secretariat 2020). In addition to lost employment opportunities, decades of resource extraction have left legacies for fossil fuel–dependent communities in terms of ongoing environmental and health impacts. Reclamation of these sites is critical from an environmental perspective as well as to meet health and equity objectives.

1.5 Methodology

For this research we had access to a more detailed database than that provided on the EPT website. This database included longer descriptions of policies and notes made by those inputting the data. This information was provided in English, with translation from other languages provided by those inputting the data.

We started by isolating policies that were coded in the EPT as “power generation,” “mobility,” and “buildings.” We then calculated the overall amount of spending in those areas. Following this, we filtered the data in these categories to only include clean conditional and unconditional policies. In some cases, we also assessed how the funding was distributed to subcategories (e.g., different forms of renewable energy such as wind and solar). To assess whether governments had considered the potential distributive effects of the policies that fall into the clean categories, we developed a list of keywords based on our review of the literature (Section 2) and refined it following initial searches of the policy titles, descriptions, and notes in the database. The keywords were access, affordable/affordability, community(-ies), equity, equality, low income, marginalized, public, poor/poverty, and social. The policies that included these keywords were separated out of the dataset and then checked to ensure that the use of those words indicated that justice and/or equity was considered in policy design.

For energy access, we took a different approach as this was not a category that was pre-coded in the database. While we searched the entire database for references to energy access, we chose to primarily focus on policies in sub-Saharan African countries, given that these are the countries tracked in the EPT with the lowest levels of energy access. For support for fossil fuel–dependent communities, we searched the database for references to worker retraining and reclamation of orphaned/abandoned wells and mines. For this area, we did not exclude policies that fell under the “fossil conditional” or “fossil unconditional” categories.

Many policies did not pass an initial check. For example, a policy description might reference “affordability” but not contain any indication that it was targeted to a particular income bracket. Those policies that did pass were explored in greater depth through desk research, supplemented with twenty-five semi-structured interviewsFootnote 1 (conducted via Zoom) with policy experts. We acknowledge that this method is imperfect, and we may have missed policies in the EPT that have a justice dimension but were not described using any of our keywords. However, we believe that we have captured the majority of relevant policies.

1.6 Limitations of the Research

Our research provides only a preliminary assessment of pandemic-era energy policies, for three key reasons. First, the pandemic had not ended at the time of writing. Although restrictions on economic activity had largely disappeared from much of the world, strict lockdowns were still in place in China and there is uncertainty about how future waves of the pandemic will impact economies and whether further stimulus spending will be required. Furthermore, additional crises, such as the 2022 energy crisis in Europe brought on by the Russian invasion of Ukraine, are adding further impetus for governments to invest in energy production and efficiency. Second, this Element is primarily the result of a desk study and does not provide in-depth case studies that could illuminate justice issues that we have missed or only scratch the surface of, particularly in the realm of procedural justice (i.e., who is and isn’t involved in decision-making, what are the mechanisms for transparency and accountability in the allocation of funds, etc.). Third, many of the policies that we discuss have only recently been announced or rolled out and the implementation of these policies may diverge substantially from stated plans. Successful programs may be injected with further funding, while programs that run into difficulties may be streamlined or canceled entirely. Changes in government or in economic conditions may also result in programs being canceled prematurely. For example, research indicates that much of the GFC green stimulus proposed in 2009 was never actually delivered (Reference TienhaaraTienhaara 2018). Justice issues that are not apparent at the outset of policy plans may also arise during implementation. For all these reasons, this research should be considered exploratory. Further research, in the coming years, to follow up on the rollout and impacts of the COVID-19 recovery programs is merited.

Additionally, as we focus only on energy policies in five areas, we do not comprehensively address the question of whether the COVID-19 recovery has been green and just. There are many nonenergy sectors, such as agriculture, that also need to undergo a transition. Investments in protecting and expanding natural areas and biodiversity are also critical. Furthermore, a green and just recovery is not just about where money flows to but also where it is withheld from. Fossil fuel subsidies are a major economic barrier to reducing emissions as they encourage usage and allow the industry to “expand or build new … infrastructure that locks-in fossil fuel use” (Human Rights Watch 2021). Government subsidies to the sector artificially lowers the costs of fossil fuels and increases their economic viability while also sending the wrong signals to markets (Reference Sanchez, Bridle and CorkalSanchez et al. 2021). Low-income, marginalized ethnic, and/or racial minority groups have experienced the greatest burden from fossil fuel extraction and have benefited the least from carbon-intensive energy production (Reference White-Newsome, Meadows and KabelWhite-Newsome, Meadows, and Kabel 2018; Reference Crear-Perry and McAfeeCrear-Perry and McAfee 2020). A key element of a green and just recovery that we do not address in this Element is for governments to cease public funding of fossil fuel production.

Finally, at a global level, a green and just recovery should involve substantial financial assistance flowing from the Global North to the Global South. The World Bank has emphasized that developing countries were experiencing a fourth wave of debt before the pandemic (Reference Ayhan, Nagle, Ohnsorge and SugawaraKose et al. 2021) and others have noted the long-lasting impacts of COVID-19 could delay an energy transition and the abilities of these countries to build back better (UNEP 2021). By late 2021, recovery spending per capita was almost 20 times higher in advanced economies than in emerging markets and developing economies and 200 times higher than in low-income economies (Energy Policy Tracker et al. 2021). While this aspect of the recovery is not the focus of this Element, we would emphasize that the pandemic only increases the urgency for the Global North to meet (and raise the level of) their commitments to international climate finance (Reference TimperleyTimperley 2021) and to also consider the case for climate reparations (Reference Táíwò and CibralicTáíwò and Cibralic 2020).

2 Literature Review

Research on government investment in green sectors through green stimulus/green economic recovery policy is generally located within the literature on green Keynesianism and green industrial policy, while justice and equity issues are addressed in separate literature on climate justice and just transitions. An emerging literature on “green new deals” attempts to merge some elements from both fields (see, e.g., Reference Green and HealyGreen and Healy 2022; Reference Tienhaara and RobinsonTienhaara and Robinson 2022). In this section, we review and integrate these bodies of literature with specific reference to the five key areas of energy policy that are the focus of our study.

2.1 Government Investment in Green Sectors

2.1.1 Green Keynesianism

According to Keynesian economics, during severe recession or depression, governments should inject money into the economy through public spending to increase demand for goods and services to achieve full employment. Although the COVID-19 recession differs substantially from previous ones, in that it was not induced by a conventional slump in demand or loss of confidence by the private sector, governments have overwhelmingly relied on fiscal measures to address it (Reference O’Callaghan, Yau and HepburnO’Callaghan, Yau, and Hepburn 2022).

Green Keynesianism first emerged as a concept in Germany in the 1990s but was popularized in 2008 when governments around the world re-embraced Keynesian economics to address the GFC/Great Recession (Reference TienhaaraTienhaara 2018). Green Keynesians argue that governments should direct public spending in a manner that will contribute to environmental goals, such as GHG emissions reductions, in addition to economic ones. The extent to which the economic and environmental goals of green stimulus spending are either mutually reinforcing or at odds is the subject of ongoing debate.

As noted in Section 1.1, green sectors like renewable energy generation and building retrofitting are labor-intensive (Reference Pollin, Garrett-Peltier, Heintz and HendricksPollin et al. 2014; Reference Garrett-PeltierGarrett-Peltier 2017; Reference Pollin and ChakrabortyPollin and Chakraborty 2020). Although the labor intensity of projects in these sectors can change over time (e.g., the maintenance requirements for renewable energy installations are relatively minor), research indicates that they can still outperform projects in traditional energy sectors in terms of both direct and indirect job creation (Reference O’Callaghan, Yau and HepburnO’Callaghan, Yau, and Hepburn 2022). While there are legitimate concerns about the quality and longevity of jobs created through government spending and the ability of displaced fossil fuel workers to enter into green sectors, these issues can be addressed through policy (see further Section 2.3.5).

A greater tension exists between the aim of boosting GDP and of addressing environmental issues. From an economic perspective, the performance of green stimulus measures in this regard has been mixed. The IEA (2020e) found that the overall macroeconomic effect of the GFC green stimulus programs was to boost GDP between 0.1 percent and 0.5 percent, which “could be counted as a success” given the severity of the crisis. However, growth impacts varied greatly by spending program. For example, GFC stimulus provided to renewable energy generation is regarded as having succeeded in reducing the cost of renewable energy technologies but having had little impact on GDP (Reference Agrawala, Dussaux and MontiAgrawala, Dussaux, and Monti 2020). From an environmental perspective, the goal of boosting GDP is inherently problematic due to a lack of evidence that economic growth can be decoupled from environmental harm quickly enough to avert the collapse of systems that support human civilization (Reference Hickel and KallisHickel and Kallis 2020). On the other hand, given that growth of certain economic sectors is necessary in the short term, government spending to induce economic recovery is not necessarily incompatible with a longer-term shift to a steady-state economy (Reference FiorinoFiorino 2017; Reference PettiforPettifor 2019).

2.1.2 Green Industrial Policy

In the last decade, there has been renewed interest in policy circles in public investment in green sectors in the absence of an economic crisis and a subset of this known as “green industrial policy” (Reference MecklingMeckling 2021). As Reference Bentley, Lewis and OatleyAllan, Lewis, and Oatley (2021) note, this approach has even been embraced by conservative governments in countries like Britain.

Economist Reference RodrikDani Rodrik (2014) has been a key proponent of green industrial policy, arguing that public investment in green technologies is critical in the transition to a low-carbon economy. He suggests that green technologies are likely to be particularly prone to market failures because they are novel and involve a high level of investor risk. Furthermore, because the true social cost of carbon is not reflected in dirty forms of energy, the private return on investment in green technologies is significantly less than the social return. For these reasons, the private sector will not invest sufficiently in green technologies and so government subsidies and other forms of support are required, at least in the early stages of their development. Reference RodrikRodrick (2014) dismisses the traditional concern that governments are not good at “picking winners” and will consequently waste resources, suggesting that mistakes are inevitable (and are also made by market actors) and what is needed are mechanisms to recognize and correct mistakes. As for the concern that government intervention in the market invites rent-seeking behavior on the part of firms, this can also be overcome with appropriate policy design (Reference RodrikRodrik 2014).

There are a range of policies that governments can adopt under this approach, including providing financial assistance to the private sector through grants, below market loans, tax breaks, investments in research and development (R&D), local content requirements, and procurement policies (Reference Bentley, Lewis and OatleyAllan et al. 2021). As Reference Meckling, Kelsey, Biber and ZysmanMeckling et al. (2015) argue, green industrial policies can build up support for climate policy by increasing the number of actors that feel that they are benefiting from it.

Reference MecklingMeckling (2021) argues that green industrial policy is primarily focused on increasing the competitiveness of a state in the global economy and contributing to economic growth. Given these goals, it is not clear that it will necessarily lead to the environmental outcomes, such as emissions reductions, that have been adopted as global objectives in treaties such as the Paris Agreement.

The notion of a “Green New Deal,” which first emerged in the context of the GFC but was popularized in 2018 by US Congresswoman Alexandria Ocasio-Cortez and the Sunrise Movement, is often characterized as “a leftist resurrection of federal industrial policy” (Reference MeyerMeyer 2019). However, Green New Deal proponents appear to be more influenced by climate justice and just transition discourses. They tend to take an intersectional approach and consider issues of race, gender, and economic equity as critical in policy design, something which is less evident in discussions of green industrial policy (Reference Tienhaara and RobinsonTienhaara and Robinson 2022). Reference Bentley, Lewis and OatleyAllan et al. (2021) contend that a critical question for the future of green industrial policy is whether it will reduce inequality or, conversely, exacerbate it.

2.2 Climate Justice and a Just Transition

Discourses on climate justice and a just (energy) transition overlap substantially and are possibly merging in many contexts (Reference Evans and PhelanEvans and Phelan 2016). For example, the definition provided in the most recent IPCC (2022) report that “no people, workers, places, sectors, countries or regions are left behind in the move from a high carbon to a low-carbon economy” goes beyond the traditional focus on workers in just transition discourses. However, given the distinct origins of these concepts, we first explore them separately in Sections 2.2.12.2.3.

2.2.1 Climate Justice

While there are many definitions of climate justice, they have all been influenced to some extent by the broader environmental justice literature and movement (Reference David and CollinsSchlosberg and Collins 2014; Reference NewellNewell 2022). The earliest conceptualization of environmental justice was based on a recognition that marginalized communities are most likely to suffer the negative impacts of environmental damage (Reference SchlosbergSchlosberg 2013). Such inequities arose from various forms of discrimination (e.g., based on race, gender, and/or class) (Reference Galgóczi, Räthzel, Stevis and UzzellGalgóczi 2021). Climate justice applies these findings specifically to the issue of climate change, highlighting that the groups most vulnerable to the impacts of a warming planet (poor and marginalized communities in the Global South) are the least responsible for causing it, and conversely, those with prime responsibility (elites based in the Global North) are most insulated from harm (Reference KennerKenner 2019).

While the North–South dimension is core to the concept of climate justice, increasingly scholars also consider inequality within countries and not only the uneven causes/impacts of climate change but also the distributional effects of the policies intended to address it. As Reference Galgóczi, Räthzel, Stevis and UzzellGalgóczi (2021, 542) argues:

Even within societies, different income groups have different responsibilities for causing climate change and are exposed to its effects in an asymmetrical manner. Lower income households tend to have occupations that are more exposed to climate change, for example in sectors such as agriculture, construction, tourism and health care. The housing conditions of the poor make them also more vulnerable (e.g., inner city “heat islands” vs. green belts).… When the costs and burdens attached to necessary climate policies affect lower income groups more, this may even turn into a “triple injustice.”

A strand of literature specifically focused on energy policy and energy systems has emerged in the last decade (Reference McCauley, Heffron, Stephan and JenkinsMcCauley et al. 2013). Energy justice scholars consider, for example, the distributional injustices that might arise through the siting of energy infrastructure as well as limited access to energy services (Reference Jenkins, McCauley, Heffron, Stephan and RehnerJenkins et al. 2016).

In addition to questions of distributional justice, climate justice and energy justice scholars also consider procedural justice; that is, who is able to participate in decision-making and whether climate policies provide for inclusivity, transparency, and accountability (Reference Jenkins, McCauley, Heffron, Stephan and RehnerJenkins et al. 2016; Initiative for Energy Justice 2019; Reference Siciliano, Wallbott, Urban, Nguyen Dang and LedererSiciliano et al. 2021). Related to this is recognition justice, which is about who is considered a valid participant in climate policy decision-making procedures (Reference NewellNewell 2022).

2.2.2 Just Transition

The concept of a just transition came out of the North American labor movement in the 1970s and is now widely embraced by unions as well as the International Labour Organization (ILO) (Reference Stevis and FelliStevis and Felli 2015). Arguably, it emerged in response to the decline of the social welfare state in the United States and Canada (Reference StevisStevis 2023). While originally centered within unions in the chemicals sector, the just transition is now most associated with fossil fuel industry workers and communities reliant on that industry. At the core of the just transition is the notion of fair burden-sharing (Reference Galgóczi, Räthzel, Stevis and UzzellGalgóczi 2021). In countries where carbon-intensive sectors like fossil fuel extraction are concentrated in specific regions (e.g., the province of Alberta in Canada), a just transition entails job retraining for those active in the sector but also programs to support all those whose livelihood is connected to the industry. In addition to such arrangements, the idea of a just transition also encapsulates the notion that affected workers and communities will be meaningfully engaged in decision-making processes (Reference Santos Ayllón and JenkinsSantos Ayllón and Jenkins 2023).

2.2.3 Our Approach

In our assessment of policies adopted by governments during the pandemic, distributional justice is our primary focus. We aim to assess whether, in addition to aiming to reduce GHGs, governments also aimed to increase the availability and affordability of energy (including through energy-efficient technologies and low-carbon mobilities) for low-income, marginalized and vulnerable communities and/or to create decent jobs for low-skilled workers or workers at risk of unemployment or underemployment in the energy transition. We recognize that procedural justice and recognition justice are also critical. However, given that energy policies adopted during the pandemic are still in the very early stages of development, and the fact that this is primarily a desk-based study, these issues cannot be explored in any depth.

2.3 Public Investment Needs and Justice Dimensions in Specific Focus Areas

2.3.1 Renewable Energy

The pandemic initially had a negative impact on deployment of renewable energy. In the first half of 2020, global renewable electricity capacity additions were more than 11 percent lower than in the first six months of 2019. However, renewable energy developers accelerated installations when restrictions on economic activities were lifted to make up for delays (IEA 2020a). In 2021, a record-breaking 6 percent addition in renewable capacity occurred despite ongoing supply-chain challenges and continued construction delays associated with the pandemic (IEA 2022c).

Although the progress in increasing renewable energy capacity during the pandemic is welcome, much greater investment in the sector is needed. IRENA estimates that investments of $2 trillion toward renewables and other transition-related technologies are needed between 2021 and 2023 and should grow to $4.5 trillion by 2030. This level of investment would increase renewable power generation five times faster than it has in recent years, allowing for a more rapid phaseout of fossil fuels (IRENA 2020).

Governments invest in renewable energy through a wide variety of policy mechanisms. Fiscal incentives such as feed-in-tariffs, which provide a fixed price to renewable energy providers over a period of time, are particulary popular and have been shown to be effective (Reference LewisLewis 2021). Governments also provide support for R&D in renewable energy generation and storage. Additionally, upgrades and modifications of infrastructure to support renewable energy, particularly electricity grids, are critical and often the responsibility of governments (Reference Seetharaman, Nitin Patwa and GuptaSeetharaman et al. 2019; IEA 2020f).

Investments in renewable energy have the potential to improve energy access, reduce energy poverty, and create employment opportunities (Reference DincerDincer 2000; Reference Edenhofer, Pichs-Madruga and SokonaEdenhofer et al. 2011). These outcomes are more likely when they are targeted to marginalized and underserved communities, particularly remote communities (i.e., not connected to the main electricity grid) that are currently dependent on fossil fuels for energy. Several policies identified in our screening of the EPT fall into this category and are highlighted in Section 3.1. Policies promoting or funding renewable energy projects that are community-led or community-owned are also examined. We acknowledge that there has been a tendency “to assume rather than demonstrate that community projects are more democratic or just” (Reference Van VeelenVan Veelen 2018, 645). Therefore, we stress that this is a preliminary review and more in-depth case studies would be required to assess whether, for example, there were certain societal groups that were excluded or marginalized in the initiatives that we highlight (Reference van Bommel and Höffkenvan Bommel and Höffken 2021).

2.3.2 Energy Access

The COVID-19 pandemic has made the goal of providing universal energy access by 2030 significantly more difficult to achieve. The financial impact of the pandemic has reversed progress on energy access in countries like Nigeria, the Democratic Republic of Congo, and Ethiopia (IRENA 2021a). It is estimated that the pandemic could increase levels of extreme poverty for an additional 70 million rural people throughout both South Asia and sub-Saharan Africa (Reference Debucquet, David and VosLaborde Debucquet, Martin, and Vos 2020). Due to the containment measures for the COVID-19 virus, many of those who worked in informal jobs became unemployed and experienced difficulty paying for energy services (Reference Zaman, van Vliet and PoschZaman, van Vliet, and Posch 2021). Approximately 30 million people who previously could afford access to energy are now unable to (IRENA 2021a).

The post-COVID-19 global economic environment will include a long-term recession, as well as increased levels of unemployment as countries work toward restarting their economies (SEforALL 2020), which will contribute further to a decline in energy access. If the impacts of the COVID-19 pandemic on achieving energy access go ignored, the Sustainable Development Goal (SDG) of universal access to affordable, sustainable energy by 2030 (SDG 7) will not be achieved.

Investment into renewable energy generation will have to be around $550–850 billion per year, alongside other investments into electricity networks, to reach universal energy access by 2030, which is significantly higher than the current annual $300 billion investment (IRENA 2021a). In Africa alone, to achieve universal electricity access by 2030, an annual investment of around $29–30 billion in electricity infrastructure is required (SEforALL 2020; Reference Cozzi, Wetzel, Tonolo and HyppoliteCozzi et al. 2022). Least developed countries face the greatest challenges in accessing finance for energy projects (Reference BhattacharyyaBhattacharyya 2013).

Energy infrastructure plans must be socially and culturally inappropriate, taking into consideration community values, especially in rural areas (Reference TarekegneTarekegne 2020). Renewable energy can create more added value when generated locally, especially for rural locations that are not connected to the national grid (Reference KhennasKhennas 2012). Off-grid solutions (see Table 3) should actively be considered for deployment in areas that have lower consumption levels, as they have the potential to provide greater improvements to energy access per dollar spent (Reference Bhattacharyya and PalitBhattacharyya and Palit 2016). However, the pandemic hit the off-grid sector hard; about two-thirds of mini-grid operators and 75 percent of solar home system suppliers were facing critical liquidity challenges during the first phase of the COVID-19 crisis (IEA 2020 g).

Table 3 Types of electricity systems and their advantages and disadvantages

Type of systemDescriptionAdvantagesDisadvantagesEnergy source
Main gridA main grid consists of complicated interconnections, including three main sections: generation, transmission, and distribution. Electricity is transmitted through power lines. With a distribution grid, substations are connected for customers that require electricity
  • Reduced energy losses

  • Efficient electrical generation

  • Reduced operations and management costs for utilities

  • Lower power costs for consumers

  • Costly to expand grid

  • Expansion through various political jurisdictions

  • Requires political power that disadvantaged populations lack

  • Requires supporting networks to move forward generation

  • Not viable for most rural areas

  • Coal

  • Natural gas

  • Wind

  • Solar power

  • Hydro

Off-grid: mini-gridMini-grids consist of small-scale electricity generation (10 kW to 10 MW) that serves limited consumers through a grid that is separate from the national transmission network. The systems can offer energy that ranges from covering a small number of households and commercial consumers or entire villages
  • Offers a collective solution

  • Lower in cost

  • Productive source of electricity

  • Assists in economic development

  • Can be connected to main power grid eventually

  • More energy security

  • Less environmentally degrading

  • Can overcome energy isolation barriers

  • Can be run by the public utility, private sector, community-based, or a combination of models

  • High initial cost

  • Higher system failure rates due to poor maintenance

  • Wind

  • Small hydro

  • Solar power

  • Diesel

Off-grid: solar household system (SHS)PV systems are an option for rural areas that are isolated from the grid. It can extend a fixed amount of electricity per day. It is often placed on top of a rooftop to capture sunlight, a battery for storing energy, and end-use appliances with a capacity between 10 W and 200 W
  • Indirect benefits related to social, economic, and environmental factors

  • After initial cost the investment cost is reduced overtime

  • Increase in quality of life due to access to light

  • High connection cost

  • Fixed amount of energy

  • Higher system failure rates due to poor maintenance

  • PV solar power

To enhance the deployment of off-grid energy systems, countries will need to engage in land-use reforms and streamlining of regulatory processes that act as barriers to the deployment of electricity systems (Reference Mugisha, Ratemo, Keza and KahveciMugisha et al. 2021). Research indicates that a community-ownership model increases the likelihood of off-grid projects succeeding (Reference Duran and SahinyazanDuran and Sahinyazan 2021).

Only two countries tracked in the EPT – Kenya and Nigeria – lack universal access to electricity and rolled out programs to address this during 2020–1. We describe these programs in Section 3.2.

2.3.3 Low-Carbon Mobility

The pandemic and associated lockdowns necessitated that human mobility be reduced to curb the spread of COVID-19. While this reduced the use of personal vehicles and associated GHG emissions, it also dramatically impacted the use of public transportation such as buses and trains. Public transportation systems remained underutilized even as lockdowns eased, as they were considered a vector of virus transmission (Reference Gutiérrez, Miravet and DomènechGutiérrez, Miravet, and Domènech 2021). As revenue from fare collection plummeted, government support was needed simply to maintain basic transportation services and to keep workers employed (Reference VickermanVickerman 2021). The loss of revenue may, in some cases, result in reduced service into the future and delays in investments in areas such as fleet electrification.

The C40 network of cities has argued that “public transport can play a major role in supporting a green and just economic recovery,” highlighting that public transport networks “enable affordable access to the economic, social and cultural opportunities offered by cities especially for those who cannot afford to own a vehicle” (C40, International Transport Workers’ Federation 2021). Public support for active transportation can also contribute to equity if programs recognize and work to remove barriers that prevent certain groups from participating in cycling and walking (Reference McCullough, Lugo and van StokkumMcCullough, Lugo, and Stokkum 2019; Reference AgyemanAgyeman 2020). Electrically assisted micromobility modes (e.g., e-scooters, e-bikes) can also increase access to active transport, increase the distance that people are willing to commute using active transportation, and help with difficult topographies (Reference KoehlKoehl 2021).

Municipalities have significant involvement in enabling and encouraging public and active modes of transport. The notion of the “eco-city” gained popularity in the wake of the pandemic as a means for municipalities to take a holistic approach to transitioning mobility systems. Broadly, the goal of an eco-city is to:

[provide] healthy abundance to its inhabitants without consuming more (renewable) resources than it produces, without producing more waste than it can assimilate, and without being toxic to itself or neighboring ecosystems. Its inhabitants’ ecological impact reflect planetary supportive lifestyles; its social order reflects fundamental principles of fairness, justice and reasonable equity.

Generally, eco-cities center around low-carbon discourses, “green-smart” technological innovation, and accessibility to transport for all peoples (Reference Joss, Cowley and TomozeiuJoss, Cowley, and Tomozeiu 2013; Reference Meine Pieter vanvan Dijk 2015). However, it should be noted that the concept of the eco-city has also been subject to thorough critique, with some scholars questioning whether the concept provides more than a “technological fix” (Reference Joss, Cowley and TomozeiuJoss, Cowley, and Tomozeiu 2013; Reference CaprottiCaprotti 2014). One eco-city program is captured in the EPT and is discussed in Section 3.3.

In addition to public and active modes of transportation, a switch from internal combustion engine vehicles to EVs is widely considered to be an essential part of the transition to low-carbon mobility. While there is now a technology and cost breakthrough for EV and battery production, these technologies are still largely confined to wealthier markets (Reference HendersonHenderson 2020; Reference Dolšak and PrakashDolšak and Prakash 2022).

Consumer subsidies have been a popular method to increase the uptake of EVs (Reference O’Callaghan and MurdockO’Callaghan and Murdock 2021). During 2020, EV registrations increased by 41 percent, despite the overall 16 percent drop in global car sales, with approximately 3 million electric cars sold globally in 2020 (IEA 2021b). In 2021, sales of EVs doubled from the previous year to a new record of 6.6 million (IEA 2022b), which was again surpassed in 2022 with 10 million units sold (IEA 2023). The IEA attributes this resilience to an increased number of consumer subsidies that governments used to continue to incentivize EV sales during the pandemic, citing a global increase of $14 billion in government spending for electric car sales in 2020 and more than double that in 2021 (IEA 2021b, 2022b).

It is important to recognize that EV subsidies primarily benefit high-income earners (Reference Ku and GrahamKu and Graham 2022) although there have been efforts in some jurisdictions to target subsidies to low-income earners (California’s program is discussed in Section 3.3) (Reference LinnLinn 2022). Targeted subsidies make economic sense because a rebate or grant is more likely to influence a low-income earner’s decision to purchase an EV (wealthier households are more likely to be “free riders” who would have purchased an EV in the absence of a subsidy) (Reference DeShazo and Di FilippoDeShazo and Di Filippo 2021). Low-income earners also tend to drive older, less-efficient cars; getting these cars off the road will have a greater impact on emissions while also promoting upward mobility for low-income households that will save on fuel costs and vehicle repairs (Reference Bauer, Hsu and LutseyBauer, Hsu, and Lutsey 2021; Reference AounAoun 2022). In addition to targeted subsidies, making purchases of used EVs eligible for rebates can also significantly increase the number of potential beneficiaries of a program (Reference DeShazo and Di FilippoDeShazo and Di Filippo 2021).

Increased investment is also needed for improving and expanding charging infrastructure to ensure not only that are there available electric chargers for an increased number of EVs, but also that the electric grid itself is decarbonized (IEA 2021 g). However, equity issues can arise if infrastructure is unevenly distributed, leading to “urban charging deserts” in some neighborhoods (often those where racial minorities are dominant) or if gentrification occurs in areas where charging stations are concentrated (Reference HendersonHenderson 2020; Reference Jing, Qiu, Liu, Pan and MauzerallLiang et al. 2023). The private sector also lacks incentives to invest in charging infrastructure in remote areas, and active public sector involvement is needed to ensure that these areas are not neglected (Reference MoerenhoutMoerenhout 2021).

While there is no doubt that electric mobility will play a key role in the energy transition, there are several environmental and justice concerns associated with mass uptake of personal EVs. Scholars have noted that promotion of mass uptake of EVs locks in car-focused urban design and limits space available for public and active modes of transportation (Reference HendersonHenderson 2020). There are also concerns associated with the resource extraction that is required for EV batteries, which could be limited through efforts to increase use of public transportation and limit car dependency (Reference Hund, La Porta, Fabregas, Laing and DrexhageHund et al. 2020; Reference Riofrancos, Kendall and DayemoRiofrancos et al. 2023).

2.3.4 Energy-Efficient Buildings

In late 2020, the Global Alliance of Buildings and Construction (2020) called the global COVID-19 pandemic an opportunity for a “paradigm shift” in the buildings sector through recovery package measures to promote building decarbonization. This is not the first crisis to have been viewed as an opportunity to improve the energy efficiency of buildings. When proposals for green stimulus measures were circulated in 2008 and 2009 in the wake of the GFC, there appeared to be one point of agreement between proposal authors: increasing the energy efficiency of buildings was a “low-hanging fruit” that was ripe and ready to be picked (Green New Deal Group 2008; UNEP 2009). The fact that this fruit remained available for picking in 2020 indicates that the opportunity presented by the GFC was not seized; although there certainly were some investments in building efficiency made by governments, they were small compared to what was needed (Reference TienhaaraTienhaara 2018).

Renovating existing buildings can be a relatively cheap way to create significant energy savings and emission reductions. Examples of energy efficiency measures in buildings include sealing gaps, installing insulation, and upgrading windows with double- or triple-glazed panes. Investments in these areas can “offer an ongoing stream of cost savings that [are] generally far greater than the value of the initial investment” (Reference BrownleeBrownlee 2013; Reference Hoicka, Parker and AndreyHoicka, Parker, and Andrey 2014). Minor or one-off retrofits are cost-effective and practical options in many contexts (see Table 4). However, the most substantial GHG reductions occur through deep energy retrofits. Deep energy retrofits are high cost, high impact changes of the entire building structure (Sustainable Buildings Canada 2021). This class of building retrofits reduces the structure’s energy use by 30–50 percent (IEA 2020b). Additionally, retrofits can prepare buildings to support increased renewable energy, resilient microgrids, and EVs. Retrofits are also beneficial because keeping older buildings for longer means avoiding the substantial emissions associated with construction.

Table 4 Types of building energy efficiency retrofits

MinorMajorDeep energy
Financial costLowLow to mediumHigh
Upgrade examplesLightingHeating/coolingEntire structure
Energy use reduction≤10%10–30%≥50%
ImpactLowMediumHigh

There are several barriers to the voluntary adoption of energy efficiency measures in buildings. Private actors have tended to view investments in energy-efficient buildings as risky and inconvenient (Reference Baldoni, Coderoni, D’Orazio, Di Giuseppe and EspostiBaldoni et al. 2019). The retrofitting of existing buildings requires a high upfront cost for investors, which pays off in the long run rather than short term, through benefits like reduced overall energy expenditure (Reference Baldoni, Coderoni, D’Orazio, Di Giuseppe and EspostiBaldoni et al. 2019). There are also information barriers; many building owners are simply unaware of potential cost savings associated with energy efficiency measures (Reference CalderCalder 2020). Additionally, for many owners there is uncertainty about whether they will own or live in a building long enough to collect a return on the investment (Reference BrownleeBrownlee 2013). In the rental market, there is a conflict of interest between the owner who would have to make the investment and the occupier who would often reap the rewards through lower energy costs (Reference EconomidouEconomidou 2018). Finally, fluctuations in the cost of electricity and fossil fuels can affect the cost–benefit analysis of building upgrades (Reference PersramPersram 2011). These barriers can be reduced with public investments, for example through grants and loans.

If designed well, building energy efficiency policies can reduce both GHG emissions and energy poverty, which is closely connected to health and social inequality (Reference Boemi and PapadopoulosBoemi and Papadopoulos 2019). Energy poverty can lead to respiratory and cardiovascular problems, and preventable deaths in winter or during periods of extreme heat. High heating and cooling expenditures disproportionately impact populations at the lower end of the socioeconomic spectrum. Reference Braubach and FerrandBraubach and Ferrand (2013, 331) make the case that lower-income households are “three times more vulnerable to indoor cold than the other households.” Low-income residences are also the least likely to be upgraded in the absence of government support (Reference Kantamneni and HaleyKantamneni and Haley 2022). This is because low-income households lack the necessary upfront capital to invest in retrofits. Additionally, a focus on low-income households in government programs is likely to reduce free rider effects (public funds going to households that would have made investments anyway) and rebound effects (recipients of energy efficiency improvements increase energy use and offset the savings) (Reference Lee, Kung and OwenLee, Kung, and Owen 2011).

In addition to reducing energy poverty and emissions, investing in energy-efficient buildings has significant potential for skilled job creation, particularly given the low barriers to entry into the retrofit industry (UNFCCC Secretariat 2020). According to Reference Max, Patadia and KammenWei, Patadia, and Kammen (2010), energy efficiency investment “offers a high payoff in induced jobs.” Reference Garrett-PeltierGarrett-Peltier (2017) estimates that for every $1 million invested, 7.72 full-time equivalent (FTE) jobs in energy efficiency are created, versus 2.65 FTE jobs in the fossil fuel industry. Importantly, building energy efficiency jobs are not limited geographically and can therefore provide much needed employment opportunities in rural areas and small towns (Reference HaleyHaley 2020). A just transition also requires that attention be paid to ensuring that these jobs have good work conditions and pay well.

2.3.5 Support for Fossil Fuel–Dependent Communities

Although the COVID-19 economic crisis differs from previous crises in important ways (Reference CohanCohan 2020; International Labour Organization 2020), it has, nevertheless, led to increased unemployment, which has in turn exacerbated economic and social inequality (International Labour Organization 2021). A total of 255-million FTE jobs (assuming a 48-hour working week) or 8.8 percent of global working hours were lost in 2020 relative to the fourth quarter of 2019 (International Labour Organization 2021). Working hours rebounded in 2021, but deteriorated again in early 2022, even though most workplace closures had, by that time, ended (International Labour Organization 2022).

As noted in Section 1, many carbon-intensive sectors were hit hard by the pandemic. The price of oil collapsed in 2020 and so too did employment in the sector. In the United States, about 107,000 oil and gas workers were laid off between March and August 2020 (Reference Dickson, Tilghman, Bonny, Hardin and MittalDickson et al. 2020). However, even prior to 2019, workers in the sector were vulnerable to fluctuations in the oil price and to increased automation (Reference SahaSaha 2020). In the long term, the increasing cost competitiveness of renewable energy coupled with government-imposed limits on extraction should lead to a contraction of the fossil fuel industry and associated loss of jobs in the sector.

Providing (re)training support to workers, in the form of subsidized or free education and relevant work experience, is key to a green and just recovery, even if it alone will not address all issues related to employment disruptions. Although much of the emphasis is put on retraining/upskilling fossil fuel workers to work in emerging green sectors, a just transition should also consider other workers who are indirectly impacted by a loss of economic activity in an area when an industry shuts down (Reference GassGass 2021).

Experts argue that worker retraining cannot be left in the hands of corporations. As Ana Guerra, National Chapter Director of Iron & Earth (a not-for-profit worker-led organization in Canada) notes, “There has to be some sort of regulatory system in place … because otherwise … How far can a corporation go? It will go towards what their shareholders say” (interview with Ana Guerra, 2021). There are government and nonprofit organizations that were operating prior to the COVID-19 pandemic that focus on helping workers transition into jobs in the renewable energy sector. For example, Skills Development Scotland (Scotland’s national job agency since 2008) was able to retrain and upskill more than 3,000 fossil fuel employees from 2016 to 2019 in partnership with Scotland’s energy task force. Iron & Earth has been involved in oil and gas worker retraining in Canada since 2015. However, greater investment on the part of many governments is needed. David Coyne from Skills Development Scotland argues the government simply “hasn’t fully understood the scale of investment that’s going to be required to help people reskill and upskill and nor have they fully understood the pace at which we may need to move” (interview with David Coyne, 2021). Iron & Earth estimates that retraining a single worker can cost about CAD10,000 ($7957) (interview with Ana Guerra, 2021).

In addition to greater investment in retraining, it is also critical that programs and policies reflect the gendered dimensions of the transition (International Labour Organization 2015; UNFCCC Secretariat 2020; Just Transition Initiative 2021), particularly considering the severe impacts that the pandemic has had on women. Attention should also be given to issues such as worker safety, fair wages, and respect for workers’ rights (International Labour Organization 2015; UNFCCC Secretariat 2020; Just Transition Initiative 2021). In developing worker (re)training policies, governments should provide opportunities for meaningful participation from impacted workers communities (Reference StanfordStanford 2021) and representation from Indigenous peoples (interview with Ana Guerra, 2021). Ultimately, policies and programs will vary by country as they will have to be designed to address the specific needs of workers in very different contexts (International Labour Organization 2015; UNFCCC Secretariat 2020).

Reclamation of mines and oil and gas wells is also a critical justice issue for fossil fuel–dependent communities. In addition to the environmental and health benefits associated with cleaning up oil and gas wells and coal mines, such activities can also create employment opportunities (Reference Raimi, Nerurkar and BordoffRaimi, Nerurkar, and Bordoff 2020; Reference BoettnerBoettner 2021). If locals, including former oil and gas workers and miners, are given priority access to these jobs, it contributes further to the achievement of a just transition (Reference FrenchFrench 2020). Moreover, site restoration can make land available for new community amenities and developments, including renewable energy projects.

Idle and abandoned/orphaned oil and gas wells can leak gas, oil, saline water, and other fluids (Reference Kang, Brandt and ZhengKang et al. 2021), which in turn can “contribute to local adverse environmental and human health effects from soil and groundwater contamination” (Reference Vanessa and WalkerAlboiu and Walker 2019, 1). Abandoned wells also leak large amounts of methane – a potent GHG – into the atmosphere (Reference BoettnerBoettner 2021). Methane leaks also risk explosions occurring (Reference BoettnerBoettner 2021; Reference Kang, Brandt and ZhengKang et al. 2021). Plugging wells can eliminate some of these risks, but full restoration would also involve site decontamination and revegetation (Reference BoettnerBoettner 2021). Oil and gas wells are located in both residential (often low-income and racially marginalized communities, see Reference MernitMernit 2021) and rural areas. Inactive, aging wells have been a large burden for farmers, who often do not have the option to refuse wells on their property (CBC Radio 2020).

Abandoned coal mines also present serious harm to human health and the environment. Many abandoned coal mines emit acid mine drainage that can have “long-term devastating impacts on groundwater, community water supplies, rivers, streams, and aquatic life” (GroundWater Protection Council n.d.).

The pandemic and downturn in the oil, gas, and coal industries has potentially made it harder to ensure that reclamation is paid for by companies. For example, across Canada and the United States there were at least 116,245 oil and gas wells that were operated by companies that were filing for bankruptcy in the first half of 2020 (Reference Kang, Brandt and ZhengKang et al. 2021). This suggests a role for governments in the form of targeted recovery policies.

2.4 Summary

Substantial government investment in renewable energy generation and distribution (including increased access to energy in some countries), technologies and infrastructure for low-carbon mobility, and energy efficiency of buildings is necessary to decarbonize economies and avert climate breakdown. Governments have an opportunity to further the goals of climate justice and a just transition at the same time as they reduce GHGs if they consider the distributional impacts of energy policies and target them to low-income, marginalized and underserved communities. Furthermore, ensuring specific support for communities that are dependent on the fossil fuel industry for employment will help to ensure that the transition does not create new inequities and injustices. Targeted policies will be somewhat context dependent (e.g., there are more underserved remote communities in large, sparsely populated countries like Australia and Canada) but across policy areas, it is evident that providing low-income earners with greater support is likely to contribute to program efficacy as well as contributing to equity objectives.

3 Energy Policies during the Pandemic

For the period 2020–1, governments and MDBs tracked in the EPT developed new or amended energy policy measures providing $1.3 trillion in support, at least 40 percent ($519.38 billion) of which was for fossil fuels ($389.23 billion unconditional, $130.15 billion conditional), 39 percent ($503.4 billion) for clean energy ($132.67 billion unconditional, $370.77 billion conditional), and 21 percent ($276.48 billion) for other energy (see Figure 1). Over 94 percent of this spending was from governments, with the remainder coming from the MDBs. The distribution of funds by the top ten spending leaders (representing over 70 percent of all spending captured in the EPT) is provided in Figure 2. We do not attempt to quantify the number of policies that have equity/justice elements. However, another study based on the EPT (using a different methodology) has estimated that 11 percent of energy policies approved between January 2020 and November 2021 are likely to decrease inequality (Reference Dufour, Roth and PicciarielloDufour, Roth, and Picciariello 2022).

Figure 1 Public spending by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

Figure 2 Public spending in top ten countries, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

3.1 Renewable Energy

The EPT contained information on power generation policies by governments amounting to $255 billion. Of this, $34.7 billion was allocated to clean conditional policies and $34.1 billion was for clean unconditional policies. A further $20.6 billion went to fossil conditional policies and $13.8 billion to fossil unconditional policies (see Figure 3). Most funds ($151.7 billion) were in the “other energy” category, which includes policies that cover multiple sources of energy ($120 billion) (e.g., infrastructure for electrical transmission and storage, $33.5 billion) and nuclear energy ($11.8 billion).

Figure 3 Public spending on power generation policies by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

Projects involving multiple energy types or multiple renewables received most of the clean funding, followed by hydroelectric projects and hydrogen projects (see Figure 4). The largest investments were from the United States, with a $10 billion increase to the borrowing authority of the Bonneville Power Authority to aid in the reconstruction and replacement of the Federal Columbia River Power System, and $3 billion allocated to the Smart Grid Investment Matching Grant Program, a program initially funded under the Obama administration’s GFC stimulus (Reference EvansEvans 2022). Germany made a $9.1 billion investment in hydrogen. Twelve EU member states made a collective investment of €2.9 billion ($3.3 billion) in the European Battery Innovation project (European Commission 2021). This project will support research and innovation along the entire battery value chain, starting from extraction of materials to recycling and disposal. Public funding is expected to encourage an additional €9 billion ($10.5 billion) from private investments. The project is expected to be completed by 2028 (European Commission 2021).

Figure 4 Public spending on clean conditional and clean unconditional power generation policies by type of energy, Jan. 2020–Dec. 2021

Source: Authors, based on EPT 2022

Other policies with a large monetary commitment have been implemented by Italy. The national government has committed nearly €5.2 billion ($5.5 billion) for three separate policies related to power generation (Government of Italy 2021). The first €2.4 billion ($2.5 billion) policy focuses on electricity generation and supporting economies in small municipalities at risk of depopulation. The investment will install 2,000 MW of new electricity generation and produce 2,500 GWh per year to reduce GHG emissions by about 1.5 million tons of CO2 per year. The second €1.6 billion ($1.7 billion) policy focuses on incentivizing the installation of solar energy panels on buildings to improve the agricultural sector while simultaneously redeveloping structures in need of asbestos removal and improvements to insulation and ventilation. Finally, the third €1.2 billion ($1.3 billion) policy aims to install production capacity from agrovoltaic plants and produce 1,000 GWh per year to reduce about 0.8 million tons of CO2. The policy focuses on making a more competitive agricultural sector and providing a hybrid agriculture-energy production system without damaging the land.

While the national government in Australia focused on a “gas-led recovery” (Reference MortonMorton 2020) and made only small investments in renewables (see Section 3.1.1), both Queensland and Victoria had large funding programs. The Queensland state government committed AUD2 billion ($1.03 billion) toward the establishment of a Queensland renewable energy and hydrogen jobs fund. This investment will allow “energy government-owned corporations to increase ownership of commercial renewable energy and hydrogen projects, as well as supporting infrastructure, including in partnership with the private sector” (Queensland Treasury 2021). The fund will consider investment proposals from government-owned corporations that support renewable energy generation and storage to aid in meeting Queensland’s 50 percent renewable energy target by 2030. Such proposals can include “solar, wind, pumped hydroelectric storage, hydrogen and supporting network infrastructure” (Queensland Treasury 2021). Victoria’s program is particularly notable for the efforts being made by the government to increase community consultation – we briefly summarize it in Box 1 given the relevance to procedural justice, which as noted in Section 2 is a key aspect of climate justice but not one that we focus on in this Element.

Governments in India also introduced several policies to increase renewable energy power generation. The government of Maharashtra, for example, announced a clean unconditional policy that aims to implement 17,360 MW of transmission system-connected renewable power projects by 2025. This is divided into 12,930 MW of solar power projects, 2,500 MW of wind energy projects, and 1,350 MW of cogeneration projects. It will also include 100,000 agricultural solar pumps, 52,000 kV of rooftop solar systems, 2,000 solar water supply stations, the electrification of 10,000 rural homes, microgrid projects for twenty homes, 55,000 square feet of solar water and cooking systems, and 800 solar cold storage projects (Maharashtra Energy Development Agency 2021). The state government of Andhra Pradesh also launched a project to generate 10,000 MW of solar power. The government has promised nine hours of free power each day to the agricultural sector for the next thirty years. This sector currently consumes approximately 24 percent of total energy demand in the state (TNN Agency 2020). Finally, Korea also invested in renewables as part of its ₩73.4 trillion ($57 billion) Green New Deal (Reference ChowdhuryChowdhury 2021; IEA 2021h). Another ₩2.8 trillion ($221 million) was allocated to the improvement of energy infrastructure, which includes the digital, green, and job security sectors. A sum of ₩1.8 trillion ($144 million) went to renewable energy deployment and the hydrogen economy with the inclusion for construction costs for solar PV for homes, buildings, and public institutions.

Box 1 Victoria, Australia

On February 18, 2021, the Victorian Government announced a AUD1.2 billion ($850 million) clean energy package as part of the state budget to invest in renewables, grid infrastructure, energy efficiency, and decarbonization projects. Within this budget is a proposed AUD540 million ($380 million) to be used over the four years toward the establishment of six renewable energy zones (REZs) to bring 600 megawatts of renewable energy generation online. This investment would allow Victoria to transition from a system of a few large electricity generators to a system that connects many renewable projects across the REZs. An REZ is a renewable-rich area with infrastructure and a transmission network that can supply clean energy to other areas that need it, ensuring a secure, affordable, clean, and reliable energy system and storage. Renewable energy zones will be located in Central North, Gippsland, Murray River, Ovens Murray, South Victoria, and Western Victoria and will help direct investments to enhance transmissions grids. The Department of Environment, Land, Water and Planning in the Victorian Government has specifically stated that these REZs will “ensure that communities, including traditional owners, are engaged in the process.” Along with the implementation of REZs, a portion of funding will be put toward the establishment of a new body, VicGrid, to oversee investments in the grid. This body will work closely with local communities and traditional owners to ensure that all stakeholders receive benefits from REZs. By ensuring community consultation at the beginning of the planning process, the government hopes to reduce planning times and increase public acceptability of renewable energy developments.

When we searched the EPT data on clean conditional and unconditional power generation policies, we found that the policies with descriptions that included our keywords fell into two broad categories: policies aimed at bringing renewable energy to remote communities that are not connected to the main electrical grid and instead rely on nonrenewable energy sources such as diesel, and community-led and community-owed renewable energy projects. As noted in Section 2, policies in these categories are likely to have positive redistributive impacts (i.e., reduce inequality). For this reason, we highlight the policies that fall into these categories.

3.1.1 Remote Communities

Several investments in Canada were directed to bringing renewable energy to remote Indigenous communities that are not connected to the main North American electrical grid and are largely reliant on diesel power generation, which is both expensive (as diesel must be shipped in at high cost) and has negative impacts on local health and the environment (Pembina Institute 2020). In 2021, the federal budget included CAD76.4 million ($57 million) earmarked over three years to build capacity for local renewable energy projects in First Nations, Inuit, and Métis communities and to support feasibility assessment and planning for hydroelectric projects and grid extensions. The government also invested CAD40.5 million ($30.2 million) in the Clarke Lake Geothermal Development Project, which is a wholly owned and Indigenous-led project to build a commercially viable geothermal electricity production facility that can produce between 7 and 15 megawatts and power up to 14,000 households (Natural Resources Canada 2021a). Finally, several community-led projects in the Northwest Territories and Yukon were funded through the Clean Energy for Rural and Remote Communities program, a program that predates the pandemic (Natural Resources Canada 2022). Yukon’s government also funded a number of community-based renewable energy projects in its 2020–1 budget (Government of Yukon 2021). In total, the investments for remote communities amounted to $121 million out of a total of $3.3 billion (3.7 percent) for clean conditional and unconditional power generation policies in Canada in the period 2020–1. However, it should also be noted that an unspecified amount of the $1.8 billion allocated to clean power in the Canada Infrastructure Bank Growth Plan (to be delivered through public-private partnerships) is also expected to benefit remote Indigenous communities.

Australia also made two investments in renewable energy in remote communities in 2021. The government allocated AUD19.3 million ($13.4 million) over three years to develop a renewable energy microgrid in the Daintree Rainforest in Far North Queensland. An additional AUD30 million ($21 million) was invested in the Northern Territory’s Katherine-Darwin Interconnected System big battery project and microgrid rollout. The project is expected to displace more than 4 million liters of diesel fuel that are consumed in the region each year (Reference BridgeBridge 2022). A sum of AUD15 million ($10.5 million) was allocated to the deployment of renewable energy microgrids in remote Indigenous communities in the Northern Territory. The other AUD15 million ($10.5 million) was invested in a 35 MW battery energy storage system to support the Darwin-to-Katherine grid as more households install rooftop solar (Reference CarrollCarroll 2021). These investments amounted to only 1.4 percent of the total spending on clean power generation policies in Australia over 2020–1.

3.1.2 Community-Led and Community-Owned

Spain stands out in the EPT as having an emphasis on citizen participation in renewable energy production. The concept of “energy communities” was introduced in the EU in the Clean Energy for all Europeans legislation in 2019. The EU now has rules to “enable active consumer participation, individually or through citizen energy communities,” in renewable energy generation, consumption, sharing and selling, as well as energy storage (European Commission n.d.). In line with this, in 2020, a Royal Decree-Law in Spain was issued that recognizes renewable energy communities as “autonomous legal entities that provide open and voluntary participation” and regulates energy self-consumption in these communities. This framework has allowed renewable energy communities to flourish in the country (Reference Castillo SánchezCastillo Sánchez 2021).

In the Basque Energy Transition and Climate Change Plan (2021–4, €10.1/$11.5 million) there is discussion of both “citizen energy generation cooperatives,” which are designed to “satisfy their own consumption in municipalities in the Basque Country,” and promoting other “individual and collective self-consumption projects.” The Valencian Community has also allocated aid in 2020 (€550,00/$627,854) and 2021 (€2/$2.3 million) to promote self-consumption in renewable energy communities. For the government of the Valencian Community, local energy communities are considered a “key” element in the transition, since they pursue not only economic ends but also “promote citizen participation, the use of local supply chains and provide employment opportunities, maintaining the value of energy generation within the local population”(“Energy Policy Tracker” 2022). In Navarra, a pilot solar project aimed at collective self-consumption will supply a neighborhood located within a radius of 500 meters of the project (€180,000/$205,480). A “citizen community of renewable energy” will be formed, which will be a group of legally constituted users, with voluntary and open participation, which can develop actions for the generation, distribution, supply and consumption of energy, and the provision of different energy services to members (Government of Navarra 2020; “Energy Policy Tracker” 2022).

Outside of Spain, in 2020, New York State allocated $10.6 million to help underserved and disadvantaged communities to access solar energy as part of New York’s Social Energy Equity Framework (Reference StateNew York State 2020). In 2021, an additional $52.5 million was allocated for community solar projects to serve up to 50,000 low-to-moderate-income households, affordable housing providers, and facilities serving disadvantaged communities (Reference StateNew York State 2021). These investments comprised 19 percent of the total $332 million that New York State invested in clean power generation in 2020–1.

In Nova Scotia, Canada, a Shared Solar Program was launched in 2021 aimed at reducing barriers to solar adoption for communities and businesses. Under the program, municipalities, First Nation bands, co-ops, and not-for-profits can create community solar gardens. Those renting an apartment can adopt solar energy through a shared ownership or subscription model (Government of Nova Scotia 2021).

Finally, in 2020, Scotland injected £4.5 million ($5.6 million) into the existing Community and Renewable Energy Scheme for local renewable projects (Government of Scotland 2020a). The government has set a target for 2 GW of energy to be produced by community and locally owned energy by 2030.

3.2 Energy Access

Within the countries represented in the EPT, Kenya and Nigeria have the lowest energy access rates (71.4 percent and 55.4 percent respectively, in 2020). Both funded energy access programs during the study period.

3.2.1 Kenya

Approximately, 72 percent of Kenya’s population lives in rural areas (World Bank n.d.). As of 2020, 71.4 percent of the population in Kenya had access to electricity, which is a dramatic increase from 2010, when it was only 19.2 percent of the population (World Bank n.d.). However, only 62.7 percent of the rural population has access compared to 94 percent of the urban population. Approximately 13 million people in Kenya continue to lack access to electricity (SEforALL 2020). Kenya has ambitious energy access plans and has set a target to achieve universal electrification by 2022. To achieve this, 5.7 million households will need to be connected to grids, at an estimated cost of $2.3 billion of public investment and $458 million of private investment (Ministry of Energy 2018). Kenya has made immense progress throughout the past decade, expanding electricity access, while at the same time substantially increasing renewable energy production, which now constitutes 78 percent of electricity in Kenya (Ministry of Energy 2021).

Extending the main grid into remote areas is very expensive, so there is an emphasis in Kenya on mini-grid technologies, which are more cost-effective (Reference Nkiriki and Selim UstunNkiriki and Ustun 2017; Reference Blimpo and Cosgrove-DaviesBlimpo and Cosgrove-Davies 2019). It has been found that most rural populations without access to electricity will be better serviced with mini-grids or stand-alone systems (Reference Kagimu and Selim UstunKagimu and Ustun 2016).

During the first two years of the pandemic, Kenya had two programs related to energy access. The first, in 2020, involved $4.6 million in credit from the World Bank to provide short-term loans and other forms of financing to off-grid solar companies to enable them to buy stocks of home solar systems and clean cooking stoves (Reference MwirigiMwirigi 2020).

In 2021, Kenya launched a project to electrify twenty-two villages through mini-grids in rural Busia County in Northwest Kenya (Reference TakouleuTakouleu 2021). The mini-grids will incorporate battery backup and range in size from 100 to 60 kWp, with the goal to “expand access to clean, reliable solar power in rural areas [and] pilot delivery of street lighting, water pumping, purification, and appliance financing to ensure that [all] communities and businesses can … maximize the health, security, and economic benefits of clean renewable power” (Reference TakouleuTakouleu 2021). To continue the expansion, a total of $8 million will be required to create 7,000 electricity connections with prepaid solar electricity (InfraCo Africa 2021). A sum of $4.2 million is being provided by InfraCo Africa, and $3.8 million is being provided by the Green Mini-Grid Facility (Reference TakouleuTakouleu 2021). The project has also received a $235,000 grant from the Private Infrastructure Development Group, which funds InfraCo Africa, to support the various building initiatives and technical studies required for the project. The project is being implemented by Rural Village Energy Solutions (RVE.SOL), a for-profit social entrepreneurship. Although the company’s system works on a pay-as-you-go model, they are committed to connecting all households in the communities that they work in, regardless of income (interviews with Lameck Odidah and Stephen Nakholi, 2021).

3.2.2 Nigeria

Nigeria is one of the most populated countries in the world and has the largest economy in Africa, with high levels of poverty and low levels of electricity access (Reference Ogbonnaya, Abeykoon, Damo and TuranOgbonnaya et al. 2019). About 85 million Nigerians lack access to electricity (World Bank 2021). As of 2020, 83.9 percent of the urban population and only 24.6 percent of the rural population in Nigeria had access to electricity (World Bank n.d.). It is estimated that Nigeria would have to connect between 500,000 and 800,000 households to the main grid on an annual basis between 2018 and 2030 to achieve SDG 7 (Reference OdinOdin 2018).

Nigeria as a country has access to an abundance of both renewable and nonrenewable energy resources (Reference Nwozor, Oshewolo, Owoeye and OkiduNwozor et al. 2021). However, oil remains dominant: around 70 percent of centralized electricity generation is fossil fuel based, with the remaining 30 percent coming from hydro (Reference Akinyele, Belikov and LevronAkinyele, Belikov, and Levron 2018). The government has been working for decades to expand access with renewable energy, utilizing various policy initiatives. In 2015, the National Renewable Energy and Energy Efficiency Policy created a framework for both on-grid and off-grid solutions (Reference Emodi and Ekene EbeleEmodi and Ebele 2016). The National Renewable Action Plan was developed to further the goals laid out in the framework. It included objectives to increase the share of on-grid renewable energy, improve cookstoves, and expand biodiesel (Reference Nwozor, Oshewolo, Owoeye and OkiduNwozor et al. 2021). Unfortunately, the implementation of these policies has been slow.

Around 60 percent of Nigeria’s citizens cannot access the national power grid, making off-grid systems an attractive option to facilitate economic growth and development (Reference Akinyele and RayuduAkinyele and Rayudu 2016). Many of the current mini-grids in use throughout Nigeria are powered from renewable sources, most commonly solar PV (Reference Ekpe and Bassey UmohEkpe and Umoh 2019). As of 2018, there were thirty operating hybrid-solar mini-grids in Nigeria, utilized for the purposes of street lighting, community water pumping, and energy supply to community halls, households, schools, and health centers (Reference Akinyele, Belikov and LevronAkinyele et al. 2018).

In response to the COVID-19 pandemic, the Government of Nigeria developed a ₦2.3 trillion ($5.6 billion) Economic Sustainability Plan in March 2020 (Government of Nigeria 2020). A sum of N$500 billion ($1.2 million) of this went to the Solar Power Naija Plan (Government of Nigeria 2020). The World Bank and African Finance Development Bank Group have provided a further $765 million in funding. The Solar Power Naija Plan aims to create 5 million solar connections, 250,000 jobs, and impact up to 25 million beneficiaries. As in Kenya, the program is not focused on public provision of electricity, but instead on creating a favorable environment for the private sector to do so (interview with Suleiman Babamanu, 2021). Businesses involved in the project must have at least 70 percent local ownership (SEforALL 2021). Businesses must also demonstrate that they have a plan to source materials from local suppliers (interview with representative of SEforALL, 2021). The focus on localization of the solar power supply chain to develop local manufacturing industries is considered to be one of the most innovative aspects of the Solar Power Naija Plan (ibid) and could, if it is ambitious in scale and ultimately successful, “inspire confidence in the government which would hopefully lead to more investments in those areas” (interview with Chukwumerije Okereke, 2021). However, there is a concern that the emphasis on local production could slow the rollout of the plan and, if the quality of the products is not high, this could damage public confidence in the green transition (interviews with SEforALL and Chukwumerije Okereke, 2021).

The Solar Power Naija Plan may help to overcome one of the major barriers to the deployment of solar PV in Nigeria: the cost. Although these systems can be very cost-effective over time, the upfront cost (up to $400 for an 80 W system) of a solar home system in rural sub-Saharan Africa is too high for many households (Reference Hassan, Morse and LeachHassan, Morse, and Leach 2020). It remains to be seen whether other barriers will be overcome. For example, there are technological issues to deal with; the capacity of a typical solar home system used in sub-Saharan Africa is also only in the 10–100 W range. Unsurprisingly, many households surveyed both in Federal Capital Territory and Lagos State in Nigeria are unsatisfied with this power capacity, especially in terms of the amount of light provided and the limitations on using a solar system to power appliances (Reference Hassan, Morse and LeachHassan et al. 2020). Another barrier to the adoption of solar home systems in Nigeria is higher than average system failure rates: a solar electricity system’s life span should range from twenty to twenty-five years (Reference Akinyele, Belikov and LevronAkinyele et al. 2018), but in Nigeria, they commonly fail within two to three years of installation due to poor maintenance (Reference AdelekeAdeleke 2016).

3.3 Low-Carbon Mobility

The EPT contains information on mobility policies representing commitments of $599 billion. Spending on clean mobility ($292 billion clean conditional, $5.7 billion clean unconditional), and fossil-fueled mobility ($48.2 billion fossil conditional, $240 billion fossil unconditional) was close to equivalent. Figure 5 shows the breakdown of policies by category.

Figure 5 Public spending on mobility policies by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

Road construction is a staple of stimulus packages, but this crisis is notable for its impact on the aviation sector and many of the policies reflect this. The International Civil Aviation Organization (2022) reported that the approximate loss of gross passenger operating revenues (compared to 2019 levels) for airlines was approximately $372 billion in 2020 and would be another $324 billion by the end of 2021. Generally, the breadth of the aviation-centered policies – which spanned across all countries listed in the EPT – speaks to the economic dominance of the airline industry. While most airline bailouts were unconditional (see further Reference EuropeGreenpeace Europe 2021), France is notable for attaching some “green strings” to its bailout for Air France, including the requirement that it cut domestic flights by 40 percent (Reference DunnDunn 2020). The country later moved to ban some short haul flights (BBC News 2021).

Some of the other recovery packages for airlines highlight the intricacies of a just recovery in the sector that accommodates equity concerns of marginalized groups. For instance, Canada had the highest number of aviation-related policies, the majority of which were bailout funds. However, the Canadian aviation context is complicated by its expansive geography and the remoteness of many of its communities. For example, the government of Canada committed up to $12 million to support the province of Manitoba to continue essential air travel for remote communities that are otherwise impossible to access. These communities – often located in northern climates – tend to be populated primarily by Indigenous groups, and lack access to medical supplies, food, and equipment for electricity and water systems (Reference SeymourSeymour 2020; Transport Canada 2021). Already underserved, these Indigenous communities are reliant on small airlines to ensure individual and community well-being, thus emphasizing the importance of bailing out those fossil-reliant industries during a pandemic. This highlights how equity concerns can complicate the energy transition discourse.

Clean unconditional or conditional energy policies were wide-ranging in focus. While a considerable number of policies addressed public transportation, many of these were funding measures to address shortfalls in revenue due to COVID-19. Policies aimed at decarbonizing public transport generally focused on electrification, such as Poland’s commitment to purchase zero-emission busses under its Green Public Transport program, and Canada’s efforts to purchase electric school busses in several provinces. The largest single investment in mobility in any category was the $65 billion allocated to public transportation under the US Bipartisan Infrastructure Law (enacted as the Infrastructure Investment and Jobs Act), representing 22 percent of total clean conditional mobility funding captured in the EPT. This is the largest investment in public transit in US history, yet was still only about one-fifth of the investment made in highways (Reference LovaasLovaas 2022). The investment has equity aspects that are discussed in Section 3.3.1.

Many policies aimed to promote EVs for individual consumption and to build out the infrastructure to support them. Electric vehicle policies centered around removing financial barriers to personal EV purchases by subsidizing their cost, offering incentives, or specifically supporting battery manufacturing. Policies in two Canadian provinces – Nova Scotia and Prince Edward Island – specifically mention that purchases of used EVs are eligible for rebates. This is viewed as an effort to make these programs more equitable (Reference Sharpe and BauerSharpe and Bauer 2021). California’s EV rebate program was targeted to low-income households and is discussed in Section 3.3.2.

Policies relating to infrastructure often complemented these initiatives, with the majority focused on increasing the accessibility of EV charging stations, primarily in cities, but also in some rural areas. The US Bipartisan Infrastructure Law included a set-aside for grants for EV infrastructure in rural communities, as well as low- and moderate-income neighborhoods (US Department of Transportation 2022). New Jersey’s program, which specifically targets electric charging infrastructure and other mobility programs to “environmental justice communities across the state,” is discussed in Section 3.3.3.

Active transport policies captured in the EPT included expansion of bike and walking pathways, as well as policies that actively reduced the speed and volume of car traffic. New Zealand’s commitment, through various funds, to significantly expand a series of walking/cycling trails across the country is an interesting example of an effort not only to encourage active transport (particularly as a form of tourism) but also to better connect rural areas (Government of New Zealand 2020b). Although major cities in the Global North, particularly London, Paris and New York, are frequently cited as cities that utilized the pandemic to rapidly shift to active modes of transportation (see further Reference DurantonDuranton 2021), cities in the Global South also invested in cycling and pedestrian infrastructure. One such project in Medellín, Colombia, is an example of an attempted “holistic” low-carbon mobility transition that incorporates justice and equity objectives and is discussed in Section 3.3.4.

3.3.1 United States

Descriptions from the US government of the public transit investments in the Bipartisan Infrastructure Law include numerous references to underserved and marginalized communities. However, in many cases, it is simply assumed that improving transit will benefit these communities because they are more likely to use transit. One program that was specifically targeted to improving equity is the All Stations Accessibility Program, established with $1.75 billion to help finance upgrades to rail transportation that would make them more accessible to people with disabilities, including those who use wheelchairs (Federal Transit Administration 2021). Funding for the preexisting Tribal Transit Program, which supports public transit projects that will meet the growing needs of rural and tribal communities, was also increased (US Department of Transportation 2022).

3.3.2 California

In September 2021, the Governor of California Guy Newson announced a package of over $15 billion in climate measures, including $3.9 billion directed to Zero-Emission Vehicle programs. Funding for 1,000 zero-emission drayage trucks, 1,000 zero-emission school buses and 1,000 transit buses, along with associated charging infrastructure, with projects that “benefit disadvantaged communities” getting priority (State of California 2021). Additionally, funding was directed to the Clean Vehicle Rebate Program (CVRP), which provides up to $4,500 toward the purchase of eligible plug-in hybrid, battery electric, or fuel cell EVs for residents that “meet income requirements” (California Air Resources Board n.d.). An additional $2,500 is available to individuals with household incomes of less than or equal to 400 percent of the federal poverty level. The rebate could also be stacked with the preexisting Clean Vehicle Assistance Program that has a stated objective to prioritize “communities that are disproportionately impacted by pollution,” which “often includes low-income communities and communities of color” (Clean Vehicle Assistance Program n.d.), although this program ran out of funds in 2021. Another program – Clean Cars For All – provides up to $9,500 toward an EV to owners of vehicles older than 2005 if they turn over that vehicle (California Air Resources Board n.d.).

Although these programs have equity criteria, concerns have been raised about how accessible they are to those with the greatest need and the CVRP has not “had significant success reaching residents in priority communities” (Reference DeShazo and Di FilippoDeShazo and Di Filippo 2021). For example, it is only possible to apply for the CVRP after purchasing a car, while most low-income buyers need assistance to afford a down payment (Reference AounAoun 2022). The rebate is also not available for purchases of used vehicles. Experts have recommended changes in these aspects as well as increasing the rebate and lowering the income cap (Reference DeShazo and Di FilippoDeShazo and Di Filippo 2021).

3.3.3 New Jersey, United States

Transportation is the most polluting sector in New Jersey. It emits nearly half of the state’s GHG emissions and is the largest contributor of local air pollution that causes a host of health threats. Low-income and minority populations are disproportionately burdened by air pollution from transportation because they tend to live along transportation corridors (Reference DavisDavis 2021).

In February 2021, Governor Phil Murphy announced an investment of more than $100 million (drawn from proceeds from the New Jersey’s participation in the Regional Greenhouse Gas Initiative and its prosecution of Volkswagen for cheating on vehicle emission testing) in transportation projects. The governor also established the Office of Climate Action and the Green Economy which would prioritize “equity and environmental justice.” Projects funded within the $100 million package included $9 million in grants for local government electrification of garbage and delivery trucks; $13 million in grants for electric school and shuttle buses in low- and moderate-income communities; $5 million in grants for equitable mobility projects that will bring electric vehicle ride hailing and charging stations to four New Jersey towns and cities; $15 million for electric public buses; and $36 million for electrification of medium- and heavy-duty equipment in port and industrial areas to reduce diesel and black carbon emissions in “environmental justice communities” (New Jersey Office of the Governor 2021). In terms of charging infrastructure, it is notable that grants were made available to encourage installation in multiunit dwellings, with “overburdened communities” eligible for larger grants (New Jersey Board of Public Utilities 2021). A law was also passed requiring multifamily developments with more than five units to reserve 15 percent of parking spaces to be made ready for a charging station and for these to be installed within six years (New Jersey Department of Community Affairs 2021).

In addition to the $36 million investment, in December 2021, the New Jersey Department of Environmental Protection adopted the Advanced Clean Trucks rule, first developed in California, which requires manufacturers to sell an increasing number of zero-emission trucks in New Jersey beginning in 2025, with 40–75 percent of new truck sales required to be zero-emission by 2035 (Environmental Defense Fund 2021). The rule is considered particularly important for reducing health risks from pollution from diesel trucks for lower-income families and marginalized communities living near freight corridors, ports, bus depots, and Newark airport (Environmental Defense Fund n.d.). However, environmental justice advocates are pushing for the state to also adopt stricter emissions standards to reduce pollution levels faster (Reference TigueTigue 2022).

3.3.4 Medellín, Colombia

Medellín’s eco-city project, led by Mayor Daniel Quintero, seemingly takes a holistic, structural approach to transitioning the city’s mobility systems to low-carbon transport, by emphasizing electrified public transit and increased bicycle and walking pathways. The project aims to “cut carbon emissions by 20 percent, electrify all public transport by 2030, expand bike lanes by 50 percent, and double the number of public transport lines” (Reference GlatskyGlatsky 2021). The initiative is based on existing green infrastructure: in January 2021, Medellín opened new electric charging stations for its sixty-nine electric busses (Reference GlatskyGlatsky 2021); it also already boasts a city-led, award-winning “green corridor” project which planted trees along streets to cool the city down (Reference MoloneyMoloney 2021). Another part of the eco-city project is to source its electric buses domestically, rather than continuing to purchase them from China (Reference GlatskyGlatsky 2021).

The eco-city project appears to aim to fundamentally restructure how individuals move, rather than emphasizing private forms of green transit. The city website states that it hopes to “Establish the foundations of the ecological transition to direct Medellín to a future of sustainability, where the full enjoyment of the right to the city, the dignified habitability of its inhabitants and the functional and harmonious integration of rural areas is guaranteed through the recognition and access to the rights of rural people” (City of Medellín 2020).

However, there has been significant opposition to the project from current and former city council members, including one from the “left-leaning Green Alliance party” (Reference GlatskyGlatsky 2021). This opposition stems primarily from the fact that Medellín’s city council cut its environmental budget earlier in 2021, making its claims for an “eco-city” seem suspect and unrealistic (Reference GlatskyGlatsky 2021). Environmental activists in Medellín are also wary of the project, given that Medellín’s city council has undergone significant membership changes recently, wherein politicians with the requisite environmental knowledge to implement an “eco-city” project have been replaced with Quintero’s political allies (Reference GlatskyGlatsky 2021). One interviewee pointed out that there has been significant political overhaul that will likely impact the viability of this type of initiative, stating that there were originally “a lot of people in the mayor’s administration who … were really knowledgeable and had experience … [but have been] replaced by people that … didn’t have any expertise” (interview with Genevieve Reference GlatskyGlatsky, 2021).

Ultimately, Medellín’s eco-city initiative is still in its initial phases, and it is unclear whether it will bring about the type of structural changes to mobility systems that are needed for a green and just recovery.

3.4 Energy-Efficient Buildings

The EPT contains information on 197 policies related to buildings worth $61.2 billion. Only nine policies in five countries (Finland, France, Poland, Turkey, and Ukraine) were fossil conditional or unconditional and a further seven policies were classified as “other energy.” Most of these policies were aimed at either switching heating systems from oil to gas or reducing energy costs, although Turkey’s $9.4 billion to provide low-interest home and home renovation loans was designated “fossil unconditional” based on the fact that it had no energy efficiency conditions attached and China’s $7.8 billion renovation program was classified as “other energy” because the amount that would be directed to clean energy is unquantified. Several of these policies were designated as negative in value, because they represented loss of tax income rather than provisioning of new funds (these values are not included in the total funding cited earlier in this section).

A sum of $43.5 billion (71 percent) was committed to clean conditional and unconditional policies related to buildings (see Figure 6). However, a small number of countries dominate: the United Kingdom (including policies in Scotland and Wales) accounts for 27.4 percent of this total, Canada for 19.5 percent, and France for 17.6 percent. While $43.5 billion may seem like a significant sum, to put this into context, the Pembina Institute has estimated that in Canada alone public investments in building retrofits of 10–$15 billion per year, every year between now and 2040, are required to meet the country’s climate targets (Reference Frappé-SénéclauzeFrappé-Sénéclauze 2021).

Figure 6 Public spending on building energy policies by category Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

Policy descriptions in the EPT for programs in Canada, New Zealand, the United Kingdom, and the United States explicitly mention poverty, social housing, or low-income households and are therefore discussed in further detail. The Korean Green New Deal also mentioned that “insulation system will be replaced with high performance ones in 225,000 public rental housings that are over 15 years old” but no additional information on this program was available (in English) at the time of writing.

3.4.1 Canada

In 2017, space heating accounted for 63 percent of Canada’s GHG emissions from buildings (NRCAN 2019). Heating and cooling of buildings accounts for 17 percent of Canada’s total GHG emissions (Energy and Mines Ministers’ Conference and Natural Resources Canada 2017).

To address building efficiency, the federal government launched the Canada Greener Homes Grant in May 2021. This retrofit program targeted toward homeowners has a budget of CAD2.6 billion ($1.8 billion) over seven years. Homeowners can access a maximum of CAD600 ($477) as a reimbursement for home energy audits and up to CAD5000 ($3,976) in reimbursement for eligible retrofits (Natural Resources Canada 2021b). This program has been critiqued as being likely to only incentivize one-off retrofits rather than deep retrofits and to be primarily taken up by middle and upper-income households.

The 2021 budget also allocated CAD778.7 million ($619 million) annually for a total of five years in interest-free loans for deep retrofits worth up to CAD40,000 ($31,812). Brendan Haley, Policy Director at Efficiency Canada, estimates that deep energy retrofits in Canada range from CAD40,000 to 100,000 ($31,812–$79,530) (interview, 2021) and that this program is therefore not likely to strongly incentivize such efforts. The loan program includes a dedicated stream for low-income homeowners and rentals, including not-for-profit and low-income housing. However, according to Tom-Pierre Frappé-Sénéclauze, the Director for Buildings and Urban Solutions at the Pembina Institute, the loan program still essentially targets upper-middle-class households who had previously considered retrofitting their home, and so is not accessible to households with less spending capacity (interview, 2021). Upper-middle-class property owners are more than likely to already have access to low interest rate financing from their bank or credit union (Reference Frappé-SénéclauzeFrappé-Sénéclauze 2021). Reference HaleyHaley (2020) concurs, noting that “Lower income Canadians will either not qualify or will be reluctant to participate due to already high levels of personal debt.”

There are also geographic inequalities that have been taken into consideration in the design of the Greener Home Grant program, but possibly not sufficiently. The program includes specific funding for northern and off-grid communities. Normally, homeowners must prove that they own and primarily reside in the building receiving the grant; however, in the territories, Nunavik, Nunatsiavut, and off-grid communities, the criteria differ (NRCAN 2021). Indigenous people represent most of the population in Northern Canada, and constantly see challenges in the realm of adequate housing (Reference Nicol, Segel-Brown and Mohamed AhmedNicol, Segel-Brown, and Mohamed Ahmed 2021). The Canada Greener Homes Grant makes an exception to the primary residence criteria in order to allow Indigenous governments to access the grant. However, challenges remain, particularly with booking the home energy evaluations that must be completed prior to any retrofits. The Northwest Territories, for example, only has one company that conducts home energy evaluations (Reference WhitehouseWhitehouse 2021). In 2021, the wait time to receive an evaluation there was between six months to a year (Reference WhitehouseWhitehouse 2021).

3.4.2 New Zealand

In May 2020, the Government of New Zealand announced a NZD56 million ($37 million) boost to an existing insulation and heating program called Warmer Kiwi Homes. The Energy and Resources Minister Megan Woods made an explicit connection to the pandemic, noting that “insulation and heating helps to prevent respiratory illness” and also highlighted that the program was targeted to help “the most vulnerable people in our communities” (Government of New Zealand 2020a). The program was initially launched in 2018, with NZD142.5 million ($93.4 million) allocated over four years. To be eligible for a grant, homeowners either needed to have a Community Services Card or lived in an area identified as low-income. Low-income areas are determined using the New Zealand Deprivation Index. The original aim was to insulate or install a heater in 52,000 houses but the bump in funding allows for 9,000 additional houses; the grants now cover 90 percent of the cost of getting insulation or a heater installed (up from the previous 67 percent), with the grant for heaters capped at NZD3000 ($1,966).

In a study of 127 households that received an energy-efficient heat pump in the program, 82 percent said their house was much more comfortable or more comfortable after having received it and the proportion of households that reported ever having restricted heating due to cost fell from 80 percent to 21 percent (Reference Fyfe, Grimes, Minehan and TaptiklisFyfe et al. 2022).

3.4.3 United Kingdom

Several policies in the United Kingdom are relevant to this discussion. One that is directly focused on low-income households is the Social Housing Decarbonisation Fund, which began in 2020–1 as a £50 million ($63 million) demonstration project. There are approximately 4.0 million social homes in England (17 percent of all homes). Social housing is generally more efficient than other types of homes in England, but it still accounts for around 23 percent of households experiencing energy poverty (Department for Business, Energy & Industrial Strategy 2021). The Social Housing Decarbonisation Fund was established to help social housing landlords improve the least energy-efficient rented social homes. In the demonstration phase, over 2,300 homes were improved and at least 1,300 local jobs were supported. A further £179 million ($225 million) in funding was provided for Wave 1 of the program in 2020–1 and £800 million ($1 billion) has been confirmed for Wave 2, which will run for three years from 2022 (Department for Business, Energy & Industrial Strategy 2022). The funds will be directed to upgrades of 50,000 households in social housing with insulation, heat pumps, and solar panels. The government expects to help households in England and Scotland save up to £450 ($566) a year on their energy bills and to support around 8,000 green jobs annually.

The largest programs launched in the United Kingdom during the pandemic to address building energy efficiency were the £1 billion ($1.3 billion) for local authority retrofitting schemes and the £2 billion ($2.5 billion) Green Homes Grant to retrofit private homes, introduced in the July 2020 Plan for Jobs. A sum of £1.5 billion ($1.9 billion) of the Green Homes program was to be dispersed through a voucher system that households could apply for directly, while the remaining £500 million ($629 million) went to a Local Authority Delivery program focused on low-income households (social housing tenants and low-income families) (Committee of Public Accounts 2021; Department for Business, Energy & Industrial Strategy 2021). The vouchers could cover up to two-thirds of the cost of a variety of low-carbon heating options or energy efficiency improvements. The government aimed to make 650,000 homes more energy efficient, save households up to £300 ($377) a year on their bills, cut carbon by more than half a megatonne per year, and support around 140,000 green jobs. The Green Homes Grant started in September but by February 2021, only around 22,000 vouchers had been issued, and fewer than 3,000 installations had been completed. The scheme was scrapped in March 2021. Of the total spending (£264 million/$332 million) by March 2021, £211 million ($265 million) flowed to low-income households (Reference Hinson and AdcockHinson and Adcock 2021).

The main flaw in the program was that it provided a very short window (six months) for vouchers to be used and the retrofit industry simply did not have capacity to complete such a large volume of installations, so applicants were unable to find an approved contractor (Hodgkin and Sasse 2021). The prioritization of the stimulus effect of a short program that could provide a significant economic boost was at the expense of workers, many of whom suffered from the scheme because they invested time and money in accreditation only then to see the program canceled (Climate Change Committee 2021). Following the end of the program, a government committee advised that short-term programs are not suitable either to create jobs and support the industry or to achieve net-zero targets and that what is needed is a “stable, long-term plan” (Committee of Public Accounts 2021).

In the wake of the collapse of the program, a protest group specifically focused on energy efficiency in homes formed in the United Kingdom. Insulate Britain has two main demands of the government: that it should fund the insulation of all social housing by 2025 and that it should develop a “legally-binding national plan” for a low energy and low-carbon retrofit of all homes in Britain by 2030 (Insulate Britain n.d.). With the outbreak of war in the Ukraine and an ensuing energy crisis in Europe, the United Kingdom was the hardest hit and public pressure forced the government to responded with a new £6 billion fund for insulation and replacing gas boilers with heat pumps in November 2022 (Reference LawsonLawson 2022).

3.4.4 United States

On November 15, 2021, as part of the Bipartisan Infrastructure Law, $3.5 billion was allocated to budget for the Weatherization Assistance Program (WAP) for a five-year period. This is a long-standing Department of Energy program rather than a new initiative. Congress created WAP in 1976 under Title IV of the Energy Conservation and Production Act. It is funded through federal appropriations that have averaged between $100 million and $450 million annually. In 2009, it received a massive influx of $4.7 billion under Obama’s stimulus package (in response to the GFC). The program is specifically targeted to provide energy efficiency upgrades in low-income households. The program has been extensively evaluated, particularly following the large injection of funds during the Obama administration. Researchers found that 340,158 units were retrofitted under the program in 2010 at a cost of $2.3 billion ($2 billion of which came from WAP) and the cost to weatherize a unit was $6,812 on average (Reference Tonn, Carroll and RoseTonn et al. 2015).

During the GFC stimulus-funded period, the WAP supported approximately 28,000 jobs (directly and indirectly) and increased national economic output by $4 billion. However, many of these jobs were temporary, with 25 percent of auditors, 27 percent of crew chiefs, and 40 percent of crew members leaving the field of low-income weatherization only two years after their initial involvement in the WAP (Reference Tonn, Carroll and RoseTonn et al. 2015). In terms of environmental impacts, carbon emissions declined by an estimated 7.3 MMT CO2-e (Reference Tonn, Carroll and RoseTonn et al. 2015). There were also health and social benefits of the program. The Oak Ridge National Laboratory study valued these at $3.8 billion in 2010 or $14,148 per household (Reference Tonn, Carroll and RoseTonn et al. 2015). While some have critiqued the program for not being cost-effective (Reference Fowlie, Greenstone and WolframFowlie, Greenstone, and Wolfram 2015), others stress that the program has numerous nonenergy retrofits, like the removal of asbestos and mold (Reference DetrowDetrow 2015; Reference PlumerPlumer 2015). These retrofits are also done to improve the comfort of low-income households, for example by allowing people to heat their homes more in the winter without increasing their energy bills. Programs like WAP are done “for equity reasons and social service reasons as much as savings” (Nadel quoted in Reference DetrowDetrow 2015). Similarly, Reference KushlerKushler (2015) argues that the GHG emissions reduction benefits “are just a bit of frosting on the benefits cake. No one would suggest WAP should be considered as entirely, or even primarily, a mechanism to fight climate change.”

3.5 Support for Fossil Fuel–Dependent Communities

The EPT only contains a handful of policies that included an element of worker training. The state government of Queensland in Australia invested $12 million in the Pinkenba Renewable Energy Training Facility. The facility will provide pre-trade apprenticeships and post-trade courses for up to 300 electrician students at a time and support forty teaching positions (Reference PeacockPeacock 2021). In Canada, several of the federal government’s investments in remote communities (discussed in Section 3.1.1) included training opportunities for members of Indigenous communities. The Optimized Retrofit Programme in Wales also included some job training elements. In the United States, the Bipartisan Infrastructure Law provided $55 million in grant funding in 2022 to train transit workers to use zero-emission vehicles “to ensure that diesel mechanics and other transit workers are not left behind in the transition to new technology” (US Department of Transportation 2022).

In terms of policies more specifically concerned with communities that have traditionally been dependent on the fossil fuel industry for employment, there are interesting examples of worker-focused policies in Europe. In Germany, the Coal Phase Out Act was passed on July 3, 2020. Alongside the law, €40 billion ($43 billion) has been allocated to support the economic transformation of coal regions, including up to €5 billion ($5.4 billion) by 2048 for adaptation payments for older workers in lignite mines and hard coal and lignite power plants who lose their jobs in the coal phaseout. However, the final plan did not include any targeted education and training for coal workers who were not ready to retire, despite the fact that this was recommended by a multi-stakeholder “Coal Commission” that was tasked with providing guidance for the legislation (Reference RaitbaurRaitbaur 2021). On the other hand, the EU- and Scotland-funded programs that were directly aimed at retraining workers impacted by the transition away from fossil fuels are discussed further in Sections 3.5.1 and 3.5.2. Funding programs in Canada and the United States that address oil and gas well and coal mine reclamation (categorized as “fossil conditional” in the EPT) are summarized in Sections 3.5.3 and 3.5.4.

3.5.1 European Union

The EU released a proposal for a Just Transition Mechanism in January 2020 as part of the European Green Deal (European Commission 2020a). The Just Transition Mechanism provides financial and accountability tools that help address the transition and help unlock the mobilization of funds, particularly of regions and communities most exposed to high employment in fossil fuel production or with GHG-intensive industries. EU member states are expected to develop national just transition plans, commit 30 percent of their recovery spending to net-zero transition, and co-finance/match funding requirements by the European Commission.

The Just Transition Fund is one pillar of the mechanism that will be directed to efforts to “alleviate the socio-economic costs triggered by climate transition,” including “up- and reskilling of workers, job-search assistance and active inclusion of jobseekers programmes” (European Commission 2020a). The European Commission’s initial January 2020 proposal had a budget of €40 billion ($40.6 billion), but only €17.5 billion ($17.8 billion) was approved by the European Council in December 2020. Those countries that have the largest anticipated job losses (Poland, Germany, Romania, and Czech Republic) will be allocated the largest amount of funds. Countries will have to provide matching funding of €1.5–3 for every euro from the Fund (European Commission 2020a). It has been argued that because the fund is small, it should be targeted exclusively to social support and worker retraining efforts (Reference Cameron, Claeys, Midoes and TagliapietraCameron et al. 2020; World Resources Institute 2021b).

3.5.2 Scotland

Between 2014 and 2017, the United Kingdom’s oil and gas sector lost 150,000 jobs due to a sharp downturn in oil prices (World Resources Institute 2021a). The impacts of this were the worst in Scotland. As of 2019, the sector employed 86,000 people (Reference PalmerPalmer 2022). Although the renewable energy sector is growing in Scotland, it employed only 22,600 people in the same year (Reference BlackBlack 2021).

In the fall of 2020, the Scottish Government launched the National Training Transition Fund (NTTF) and awarded £25 million ($31 million) to Skills Development Scotland, several colleges and universities, Scottish Enterprise, Lantra, and Creative Scotland (Government of Scotland 2020b). Unlike its predecessor, the Transition Training Fund (TTF), which ran from 2017 to 2019, the NTTF was not exclusively focused on oil and gas workers (European Commission 2020b). However, the government emphasized that it would be “targeted towards the most exposed sectors including oil and gas, aviation and tourism” (Government of Scotland 2020b). The success of the TTF, which helped 4,272 oil and gas workers, also informed the development of the NTTF (World Resources Institute 2021). The goal of the NTTF is to “boost the supply of skills in areas such as sustainable green jobs and raise the profile of training opportunities linked to Scotland’s transition to a net zero economy” (Government of Scotland 2020b). In the first year of the program, 6,000 individuals were supported. A second phase launched in 2021 aims to provide more than 20,000 additional training opportunities (Government of Scotland 2021).

In addition to the NTTF, the government launched the North East Economic Recovery and Skills Fund in 2021 to help address the impacts of both the pandemic and the downturn in the oil and gas industry in the Northeast region of Scotland (Government of Scotland 2022). The fund includes projects managed by the Energy Transition Zone in Aberdeen, which provides on-the-job transition training in the renewable energy sector and upskilling of oil and gas sector employees (Skills Development Scotland 2021).

3.5.3 Canada

Across Canada there are hundreds of thousands of inactive and abandoned oil and gas wells. Canada’s COVID Economic Response plan included CAD1.72 billion ($1.37 billion) in funding for well cleanup (Department of Finance Canada 2020). Much of the funding has flowed to cleaning up “inactive wells,” which are those that are still owned by viable companies that could fund the well cleanup themselves. Wells are considered “orphaned” if “there is no known, financially viable operator capable of addressing the environmental liabilities” associated with closure (Parliamentary Budget Office 2022). Wells are designated as “abandoned” if they “do not have a solvent owner and require cleanup in the form of either plugging and/or reclamation but have yet to transition to orphan status” (Parliamentary Budget Office 2022).

The largest portion of funds went to Alberta (CAD1 billion/$800 million) (which had lobbied heavily for the program – see Reference CorkalCorkal 2021), with the remainder divided between Saskatchewan (CAD400 million/$318 million), British Columbia ($120 million/$95 million), and as a loan to the Orphan Well Association in Alberta and in British Columbia ($200 million/$159 million) (Ramsay 2020). No funding was provided to Ontario, even though the wells in the province are some of the oldest in North America, dating as far back as the 1800s, meaning the businesses that created them are near impossible to trace (Reference JeffordsJeffords 2021). Minister Chrystia Freeland defended the decision to leave Ontario out of the program, asserting that the program should be concentrated in the energy-producing provinces (Reference EnsingEnsing 2021).

Indigenous leaders in Canada have been lobbying since the orphan wells program was announced to receive an allotment of funding. There is funding needed to clean up oil and gas wells on First Nations and Métis land in Alberta (Reference BakxBakx 2020). The Indian Resource Council requested to receive 10 percent of Alberta’s funds and although it took half a year, the provincial government eventually agreed. A sum of CAD85 million ($68 million) will be allocated toward First Nations land and CAD15 million ($12 million) toward Métis land in Alberta. This will allow Indigenous communities to have control over the gas sites that will be cleaned up. In addition, Indigenous-owned companies have received CAD1.5 million ($1.2 million) in Saskatchewan (Reference BakxBakx 2020).

While the cleanup of any oil and gas wells would be welcomed in the communities in which they are situated, experts have expressed concern that the program will set a dangerous precedent of leaving taxpayers on the hook for costs that should be borne by oil and gas producers (De Reference Souza and WongSouza and Wong 2020). The key issue, as pointed out by the Parliamentary Budget Office (2022), is that “nearly half the funding in Alberta has been disbursed to firms that are viable.” The Center for International Environmental Law (2021) notes that “Because the grants are distributed not according to an operator’s inability to pay, but based on their overall liability, the producers with the biggest environmental footprints get the largest checks.”

The Government of Alberta has taken some steps to address the concern that public money should not be spent on cleaning up the industry’s mess. Oil and gas companies will be required to spend CAD422 million ($336 million) on cleanup and remediation in 2022 and CAD443 million ($352 million) in 2023, with the amount continuing to increase each year. While this is a positive development, the Parliamentary Budget Office (2022) estimates that the amount Alberta is requiring the industry to provide is insufficient and that the funding gap will grow to CAD642 million ($511 million) by 2025 if additional finance is not secured.

3.5.4 United States

The 2021 Bipartisan Infrastructure Law included $11.3 billion for the Abandoned Mine Land (AML) program (Department of the Interior 2022d) and $4.7 billion for orphaned well site plugging, remediation, and restoration activities (Department of the Interior 2022c).

Over a period of eleven years, the AML program will provide grants to eligible states and Tribes for projects that “close dangerous mine shafts, reclaim unstable slopes, prevent releases of harmful gases, including methane, improve water quality by treating acid mine drainage and restore water supplies damaged by mining” (Department of the Interior 2022d). Pennsylvania, which is home to a third of the abandoned mine lands in the United States, was eligible for the most funding in 2022 (nearly $245 million), followed by West Virginia, Illinois, Kentucky, and Ohio (Reference GroomGroom 2022). The United States has, since 1977, required companies to reclaim abandoned mining sites. It also has a system where active coal companies pay a per-ton fee into a fund to clean up sites that were abandoned prior to 1977 (Just Transition Fund n.d.). However, the funding is insufficient and as the amount of coal mined in the United States falls, so too does the funding available for reclamation (Reference GroomGroom 2022; Just Transition Fund n.d).

In May 2022, the Department of Interior (Department of the Interior 2022b) released draft guidance on the implementation of the AML program. The guidance contains many elements that indicate a strong potential for the program to contribute to a just transition. The draft guidance instructs states and Tribes to prioritize projects that provide employment opportunities to current and former employees of the coal industry; prioritize projects that are beneficial to disadvantaged communities and support the revitalization of such communities to meet the overall objectives of Justice40 (a Biden administration initiative that aims to “deliver at least 40 percent of the overall benefits from Federal investments in climate and clean energy to disadvantaged communities” – see Reference Young, Mallory and McCarthyYoung, Mallory, and McCarthy 2021); require contractors to support safe, equitable, and fair labor practices by adopting collective bargaining agreements, local hiring provisions (as applicable), project labor agreements, and community benefits agreements; and incorporate input from disadvantaged communities of color, low-income communities, and Tribal and Indigenous communities into the selection of projects to be funded. Moreover, applicants will be required to provide detail in their proposals on how environmental justice issues within coalfield communities will be addressed; how any disproportionate burden of adverse human health or environmental effects of coal AML problems on disadvantaged communities, communities of color, low-income communities, and Tribal and Indigenous communities will be identified and addressed; and whether and to what extent the proposed projects will reduce GHG emissions, particularly methane emissions. Finally, in contrast to the previous AML program, the draft guidance requires that workers be paid prevailing wages (as determined by the Secretary of Labor in accordance with the Davis–Bacon Act), which will ensure that contractors do not reduce wages in order to win contracts (Appalachian Voices 2022).

The program and draft guidance for its implementation have been widely praised. Chelsea Barnes, the Legislative Director for Appalachian Voices (a nonprofit focused on advocating for a healthy environment and just economy in the Appalachian region) applauded the prioritization of Justice40 and encouraged the DOI “to collaborate with stakeholders to ensure that this abandoned mine land funding is reaching the most disadvantaged communities” (Appalachian Voices 2022). Eric Dixon, Senior Researcher with Ohio River Valley Institute, argues that the draft guidance “signals a shift toward prioritizing the reclamation workers – from backhoe operators to field scientists – who make mine cleanup possible” although he also wished to see even stronger wording in the final version (Appalachian Voices 2022).

The final guidance for the $4.7 billion orphaned well cleanup program was released in April 2022 and like the AML program, it reflects some of the principles of the Justice40 Initiative. In the “recommended” (not required) section of the guidance, states are asked to provide details of how they will “identify and address any disproportionate burden of adverse human health or environmental effects of orphaned wells on communities of color, low-income communities, and Tribal and Indigenous communities”; any “Training programs, registered apprenticeships, and local and economic hire agreements for workers”; plans to “support opportunities for all workers, including workers underrepresented in well plugging or site remediation, to be trained and placed in good-paying jobs directly related to the project”; and plans “to incorporate equity for underserved communities into their planning, including supporting the expansion of high-quality, good paying jobs through workforce development programs and incorporating workforce strategy into project development” (Department of the Interior 2022a). The payment of prevailing wages is a requirement.

While environmental groups and policy experts have generally welcomed the development of the fund, many have expressed similar concerns to those raised in Canada, that is, that not enough is being done to ensure that the oil and gas industry is held accountable for cleaning up their own mess (Reference BivenBiven 2022; Reference Kretzmann, Koney and HufflingKretzmann and others 2022). The amount of funding is also likely to be insufficient to tackle the problem. It has been estimated that it could cost $280 billion to close over 2.6 million documented unplugged onshore wells in the United States that are at risk of being orphaned (Reference TrackerCarbon Tracker 2020). Since the announcement of the funding, the number of documented orphaned wells (always known to be a substantial underestimate of the true number) has exploded, and some are concerned that states will be incentivized to bail out negligent operators (Reference SadasivamSadasivam 2022).

3.6 Summary

In terms of the “greenness” of the COVID-19 stimulus, our findings – that an insufficient proportion of investment (arguably, 100 percent of stimulus should be green) was directed to projects that would facilitate decarbonization – are consistent with other studies. However, clearly the greenness of stimulus does vary across areas of energy policy. Policies directed to buildings are predominantly in the clean categories, whereas there is close to an even split between fossil fuel and clean policies in the case of power generation and mobility investments. However, even in the buildings category, the total amount of green investment is far below what is considered necessary for a rapid energy transition.

With respect to the justice dimension of the recovery, it is evident that this has not been prioritized in the vast majority of policies tracked in the EPT. There is substantial scope for governments to improve both the efficacy of their green policies and to address inequality through more targeting to low-income and other marginalized groups. A small number of policies highlighted in this section could serve as models for future government programs, although more detailed studies are merited.

4 Conclusions

This Element has explored energy policies, in five key areas, adopted by governments during the COVID-19 pandemic that have the potential to reduce both GHGs and inequality. Previous assessments of the greenness of the COVID-19 recovery have concluded that governments have failed to seize the opportunity to accelerate the energy transition through stimulus measures targeted at decarbonization. We concur with these assessments. Our research adds to the overall picture that most of the green stimulus measures adopted in the period January 2020–December 2021 did not prioritize ensuring that the energy transition would be a just one. Nevertheless, we have also highlighted that in some sectors, and in some jurisdictions, issues of justice are being taken seriously and are being actively integrated into energy policies. The implementation of these policies and their impacts, in terms of reducing emissions and benefiting marginalized groups, are worthy of follow-up studies.

Investments in renewable energy have great potential to contribute to a just transition, but the mode of deployment will determine the extent to which they deliver benefits beyond GHG emissions reductions. There appears to be growing interest in community-led and community-owned models of renewable energy generation, particularly in Europe. While it cannot be assumed that such approaches will work in every context, or will deliver just outcomes for all community members, this does appear to be an overall positive development. Similarly, investments for remote communities in Australia and Canada, while small compared to overall spending on renewable energy, have potential to deliver significant benefits to communities currently reliant on dirty forms of energy such as diesel.

Renewable energy also has great potential to deliver equity outcomes in countries that currently lack universal energy access. Off-grid technologies like mini-grids and solar home systems can reduce poverty and improve public health while reducing GHG emissions. The pandemic-era programs in Kenya and Nigeria could help to demonstrate the viability of the off-grid sector and provide a model for other countries within the sub-Saharan Africa region (interview with representative of SEforALL, 2021). However, given the problems that many countries have faced with the provision of basic services by the private sector, more research on these cases is warranted.

In terms of the mobility sector, there has been a missed opportunity with public investments in 2020–1 to advance distributive justice. Although there are examples of cities that have seized the opportunity presented by the pandemic to try to upend the car-focused model of urban life, a substantial amount of green stimulus in transportation still flowed to supporting EV purchases by middle- and upper-income earners. As Reference Brand, Dons and Anaya-BoigBrand et al. (2021, 2) argue, “there is growing consensus that technological substitution via electrification will not be sufficient or fast enough to transform the transport system.” Thus, the overwhelming focus on EV expansion, to the extent that it diverts attention and investments from the public transportation and active transportation sectors, is not justified. Furthermore, very few jurisdictions have made any attempt to target EV subsidies to low-income households even though such an approach would provide greater policy efficacy in addition to delivering on equity. Governments should provide targeted subsidies, as California has, but ensure that they are accessible (i.e., provided at the point of purchase) and are available for the purchase of used vehicles (as in some Canadian provinces).

When it comes to buildings, the picture is mixed. There are certainly some countries that have prioritized energy-efficient retrofits for low-income households and social housing, particularly the United States and to some extent the United Kingdom, while others (notably, Canada, where heating buildings makes a significant contribution to overall GHG emissions) continue to primarily target middle- and upper-income earners. As energy prices skyrocketed in 2022 (brought on by the war in Ukraine), concerns about energy poverty, even in the rich countries of the Global North, have substantially increased. Protest groups like Insulate Britain have also helped to draw media attention to the issue. Hopefully, these factors will lead to greater emphasis on justice and equity issues in retrofit programs in more countries moving forward.

Finally, some attention was given in the pandemic period to job losses and other harms that have been inflicted on fossil-dependent communities, which is sensible given the degree to which these communities have suffered in recent years. However, the funds that have been offered by governments that will directly support workers and communities are a tiny fraction of that which has been provided to the industry itself in the form of fossil fuel subsidies. Furthermore, it is concerning that reclamation programs that should have positive outcomes in terms of environmental and health improvements may also serve as bailouts for negligent companies. While the United States’ plans for mine reclamation and orphaned well cleanup are not without concerns in this regard, they do offer advances in terms of the prioritization of disadvantaged communities and assurances about good conditions for workers. These programs, and others that are implemented in line with the Justice40 initiative, will be important ones for researchers to monitor.

Clearly, much further research in this area is merited. This preliminary review of energy policies adopted in the pandemic period has largely relied on an assessment of governments’ proposals for funding. Of course, the actual outcomes of funding programs may diverge substantially from stated objectives. Furthermore, we have not investigated the question of why governments have largely failed to act on the existing evidence that targeting policies to underserved communities and marginalized groups can improve program outcomes by delivering greater GHG emissions reductions as well as additional benefits to society. Is this the result of a lack of awareness among policymakers, or are political factors (e.g., the desire to appease voters in higher-income brackets and those who donate to political campaigns) more important?

Even as restrictions lift and daily life returns to an approximation of “normal,” the impacts of COVID-19 continue to be felt and will likely endure long after the pandemic is officially deemed “over.” Additional crises have also sparked further calls for government spending. While our study points to a deficient recovery thus far, there remain opportunities for innovative and equitable energy transitions. One example, which falls outside the period that we studied but is worthy of mention, is the US Inflation Reduction Act (IRA) of 2022. It combines the objectives of carbon emission mitigation with industrial policy objectives of creating competitive manufacturing sectors with more secure supply chains. The IRA specifically relies on tax credits and targets renewable energy, low-carbon mobility, energy-efficient buildings, and fossil fuel communities all at once (US Department of Energy 2022). The energy and climate commitments together were estimated at $369 billion at the time the IRA was passed (Reference SenateSenate Democrats 2022), but since some tax credits are uncapped, the eventual value might be much higher (Goldman Sachs 2023).

In terms of renewable energy, tax credits will support the deployment of, or investments in, solar, wind, geothermal, and energy storage infrastructure. Many of the low-carbon electricity tax credits have a bonus (i.e., a higher tax credit) when projects are located in brownfield sites, fossil fuel communities, low-income communities, or on Tribal land.

On the side of low-carbon mobility, EVs are incentivized through a clean vehicle credit that can go up to $7,500 per vehicle depending on where its components come from. The IRA also includes a consumer tax credit for previously owned EVs as well as a credit for new commercial clean vehicles. There is a maximum income eligibility that is supposed to reduce the number of wealthy households that are eligible for tax credits, even if the maximum income cap is still very high.

With respect to building efficiency, the IRA extends a tax credit for residential clean energy, including battery storage, and extends the credit for energy efficiency home improvements. It also adds more money to the Home Energy Performance-Based Whole House Rebates, which is intended to increase funding specifically for low- and moderate-income households. Tax credits are available for energy savings retrofits, but also for heat pumps, electric stoves, and insultation, to name a few.

Finally, the IRA also provides funding for specific community investment and energy justice projects, ranging from environmental and climate justice grants over neighborhood access and equity grants to specific tax credits for reducing air pollution, purchasing clean heavy-duty vehicles, and improving low-emissions electricity projects in lower-income and affected communities. The implementation of the IRA and its impacts will be the subject of important research in the years to come.

Acronyms and Abbreviations

CO2

carbon dioxide

CVRP

Clean Vehicle Rebate Program (California)

EPT

Energy Policy Tracker

EU

European Union

EV

electric vehicle

GFC

global financial crisis

GHG

greenhouse gas

GWh

gigawatt hours

GT

Gigaton

IEA

International Energy Agency

IISD

International Institute for Sustainable Development

ILO

International Labour Association

IMF

International Monetary Fund

IPCC

Intergovernmental Panel on Climate Change

IRA

Inflation Reduction Act (US)

IRENA

International Renewable Energy Agency

MDB

Multilateral Development Bank

MMT CO2-e

million metric tons of carbon dioxide equivalents

MW

megawatt

NTTF

National Transition Training Fund (Scotland)

OECD

Organisation for Economic Cooperation and Development

RVE.SOL

Rural Village Energy Solutions

SDG

Sustainable Development Goal

SEforALL

Sustainable Energy for All

TTF

Transition Training Fund (Scotland)

UNEP

United Nations Environment Program

UNFCCC

United Nations Framework Convention on Climate Change

WAP

Weatherization Assistance Program (US)

Appendix

Interviewees

  • Suleiman Babamanu, Rural Electrification Agency, Nigeria

  • Anup Bandivadekar, International Council on Clean Transportation

  • Chris Brodie, Skills Development Scotland

  • David Coyne, Skills Development Scotland

  • Megan Egler, Parkland Institute, Canada

  • Tom-Pierre Frappé-Sénéclauze, Pembina Institute, Canada

  • Genevieve Glatsky, Al Jazeera

  • Ana Guerra Marin, Iron & Earth, Canada

  • Dr. Brendan Haley

  • Gerard Hendriksen, GMG Kenya

  • Oliver Massmann, Duane Morris

  • Stephen Nakholi, RVE.SOL

  • Lameck Odidah, RVE.SOL

  • Prof. Chuks Okereke, Alex Ekwueme Federal University Ndufu-Alike Nigeria

  • Ashwini Swain, The Center for Policy Research, India

  • Bruce Wilson, Iron & Earth, Canada

  • SEforAll

  • Note: only those interviewees that did not wish to remain anonymous are listed.

Dr. Kyla Tienhaara is Canada Research Chair in Economy and Environment in the School of Environmental Studies and the Department of Global Development Studies, Queen’s University. She is the author of Green Keynesianism and the Global Financial Crisis (Routledge 2018) and the co-editor of The Routledge Handbook on the Green New Deal (2022).

Dr. Tom Moerenhout is an adjunct assistant professor at Columbia University’s School of International and Public Affairs (SIPA), and a resident scholar at SIPA’s Center on Global Energy Policy. He also leads the energy subsidy program at Johns Hopkins’ Initiative for Sustainable Energy Policy.

Vanessa Corkal is a policy advisor on Canada Energy Transitions at the International Institute for Sustainable Development. She combines her climate change expertise with over nine years of documentary, journalism, and nonprofit experience.

Joachim Roth is a policy analyst with International Institute for Sustainable Development’s Energy team. Joachim works on the circular economy, green fiscal policies, and coal phase-out with a particular focus on a just transition in developing and emerging economies.

Hannah Ascough is a PhD candidate in the Department of Global Development Studies at Queen’s University. Her research centers on environmental charities in South Africa and internationally.

Jessica Herrera Betancur is a Master of Environmental Studies candidate at Queen’s University. Her research addresses the need for worker retraining in a just transition for oil workers in Alberta.

Samantha Hussman is a Master of Environmental Studies candidate at Queen’s University. Her research examines degrowth discourses during the period of the COVID-19 pandemic.

Jessica Oliver completed a Master of Environmental Studies at Queen’s University in 2022. Her research focused on the role of community wind projects in the energy transition.

Kabir Shahani completed a Master of Arts in Global Development Studies at Queen’s University in 2021. He now works as a research and financial analyst with the Sustainable Housing Initiative of the Rural Development Network in Alberta.

Tianna Tischbein completed a Master of Arts in Global Development Studies at Queen’s University in 2021. She now works as a research analyst at the Institute of Fiscal Studies and Democracy at the University of Ottawa.

Acknowledgments

This work was supported by Mitacs through the Mitacs Accelerate Program. This research was also supported by funding from the Canada Research Chairs Program. We are immensely grateful to all of the participants who agreed to be interviewed for the research. We also appreciate the institutional support that we received from the International Institute for Sustainable Development (IISD). Finally, we would like to recognize the contribution of the anonymous peer reviewers and our editor, Aarti Gupta, who made valuable comments and suggestions for revisions to our initial manuscript.

  • Frank Biermann

  • Utrecht University

  • Frank Biermannis Research Professor of Global Sustainability Governance with the Copernicus Institute of Sustainable Development, Utrecht University, the Netherlands. He is the founding Chair of the Earth System Governance Project, a global transdisciplinary research network launched in 2009; and Editor-in-Chief of the new peer-reviewed journalEarth System Governance(Elsevier). In April 2018, he won a European Research Council Advanced Grant for a research program on the steering effects of the Sustainable Development Goals.

  • Aarti Gupta

  • Wageningen University

  • Aarti Gupta is Professor of Global Environmental Governance at Wageningen University, The Netherlands. She is Lead Faculty and a member of the Scientific Steering Committee of the Earth System Governance (ESG) Project and a Coordinating Lead Author of its 2018 Science and Implementation Plan. She is also principal investigator of the Dutch Research Council-funded TRANSGOV project on the Transformative Potential of Transparency in Climate Governance. She holds a PhD from Yale University in environmental studies.

  • Michael Mason

  • London School of Economics and Political Science

  • Michael Mason is a full professor in the Department of Geography and Environment at the London School of Economics and Political Science. At LSE he is also Director of the Middle East Centre and an Associate of the Grantham Institute on Climate Change and the Environment. Alongside his academic research on environmental politics and governance, he has advised various governments and international organisations on environmental policy issues, including the European Commission, ICRC, NATO, the UK Government (FCDO), and UNDP.

About the Series

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Footnotes

1 In the conduct of interviews, the authors followed an ethics protocol approved by the Queen’s University General Research Ethics Board. Those interviewees who agreed to be named in the research are listed in the Appendix.

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Figure 0

Table 1 Comparison of green stimulus trackers

Figure 1

Table 2 Policy categories

Source:https://www.energypolicytracker.org/methodology/
Figure 2

Table 3 Types of electricity systems and their advantages and disadvantages

Source: Authors (based on Mahapatra and Dasappa 2012; Alstone, Gershenson, and Kammen 2015; Hansen, Pedersen, and Nygaard 2015; Williams et al. 2015; Adeleke 2016; Baurzhan and Jenkins 2016; Bhattacharyya and Palit 2016; Kagimu and Ustun 2016; Nkiriki and Ustun 2017; Akinyele, Belikov, and Levron 2018; IRENA 2021b)
Figure 3

Table 4 Types of building energy efficiency retrofits

Source:Sustainable Buildings Canada 2021
Figure 4

Figure 1 Public spending by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)
Figure 5

Figure 2 Public spending in top ten countries, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)
Figure 6

Figure 3 Public spending on power generation policies by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)
Figure 7

Figure 4 Public spending on clean conditional and clean unconditional power generation policies by type of energy, Jan. 2020–Dec. 2021

Source: Authors, based on EPT 2022
Figure 8

Figure 5 Public spending on mobility policies by category, Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)
Figure 9

Figure 6 Public spending on building energy policies by category Jan. 2020–Dec. 2021

(Source: Authors, based on EPT 2022)

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