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18 - The Regulation of Hydrogen in the Transport Sector

Focus on Refuelling Stations

from Part V - End Use of Hydrogen

Published online by Cambridge University Press:  28 November 2024

Ruven Fleming
Affiliation:
Rijksuniversiteit Groningen, The Netherlands

Summary

This chapter examines the regulation of the hydrogen refuelling infrastructure in the European Union (EU). Since the EU is committed to reducing its carbon footprint and transitioning to sustainable energy sources, it sees hydrogen as an alternative to fossil fuels in the transport sector. This view reflects the tenor of the EU Green Deal, the Hydrogen Strategy, and the Sustainable and Smart Mobility Strategy. The success of these strategies depends on the successful resolution of several issues that would otherwise disrupt the just transition in the transport sector. The deployment of hydrogen refuelling stations requires a careful analysis of the various legal barriers that affect the value chain of the hydrogen industry.

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Chapter
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Publisher: Cambridge University Press
Print publication year: 2024
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18.1 Introduction

The European Union (EU) has undertaken measures to reduce greenhouse gas (GHG) emissions and to become carbon neutral by 2050. It adopted several interconnected strategic frameworks to that end. These frameworks include the Energy System Integration Strategy (ESI),Footnote 1 the Hydrogen Strategy (HS),Footnote 2 and the Sustainable and Smart Mobility Strategy (SSM),Footnote 3 all of which are aligned with the European Green Deal (EGD).Footnote 4 These strategies designate transport as an end-use sector in which the use of hydrogen, particularly renewable hydrogen, should be promoted. This strategic orientation is intended to contribute to the broader effort to decarbonise the economy.

Global emissions from transport increased at an effective annual rate of 1.7 per cent between 1990 and 2022, surpassing emissions in every other end-use sector except industry, as highlighted by the International Energy Agency (IEA).Footnote 5 If net zero emissions are to be achieved by 2050, carbon dioxide emissions from the transport sector must begin decreasing by more than 3 per cent per annum by 2030.Footnote 6 Globally, road transport appears to be the primary source of emissions within that sector (Figure 18.1).Footnote 7

Figure 18.1 Global emissions from transport.

Source: International Energy Agency, ‘Global CO2 emissions from transport by sub-sector in the Net Zero Scenario, 2000–2030’ (2023) <https://iea.org/data-and-statistics/charts/global-co2-emissions-from-transport-by-sub-sector-in-the-net-zero-scenario-2000-2030-2>

GHG emissions in most sectors of the EU economy have been decreasing since 1990; transportation is an exception.Footnote 8 Road transport has emerged as the main cause of this exceptionalism. Carbon dioxide emissions from road transport increased by 21 per cent between 1990 and 2021.Footnote 9 Passenger cars and motorcycles account for 64 per cent of road-transport emissions. Heavy-duty trucks and buses contribute a substantial 27 per cent, while light-duty trucks account for 10 per cent of the total.Footnote 10 Analyses have revealed that the emissions patterns of the Member States of the EU are structurally convergent. If the emissions reduction goal is to be attained, EU policies should account for the structural factors that are specific to each country, and coordinated measures should be formulated accordingly.Footnote 11

In the light of the foregoing, it should come as no surprise that the transportation sector has been identified as a potential ‘new lead market’ for hydrogen, particularly in instances in which electrification is infeasible.Footnote 12 For that potential to be harnessed, however, several technologies must first mature, and cost efficiency must improve. Other renewable and low-carbon fuels should also be utilised. The difficulties that attend on the formation of such a market were acknowledged in the 2020 SSM.Footnote 13 That strategy advocates for a gradual integration of fuel-cell vehicles into the mobility sector, and its focus is on the creation of an alternative fuel infrastructure. The SSM contends that the augmented deployment and utilisation of renewable and low-carbon fuels should be accompanied by the establishment of a comprehensive recharging and refuelling infrastructure to facilitate the widespread adoption of low- and zero-emissions vehicles across all modes of transportation. According to the SSM, constructing 500 of the envisaged 1,000 hydrogen stations by 2025 is a realistic target. The ultimate objective is to establish a dense yet widely dispersed infrastructure that will guarantee convenient access to all users and operators of heavy-duty vehicles.Footnote 14 However, in Europe, the number of hydrogen refuelling stations (HRSs) has not even approached half of the target. Currently, only 164 HRSs are available, with another 41 under construction at the time of writing. Most of those stations are in Germany, where 87 have been completed and 19 are under construction.Footnote 15 Germany aside, the rollout of HRSs at the Member State level is proceeding at an uneven and contradictory pace. Some national or sub-national governments are establishing support frameworks for hydrogen-based transport, while others are withdrawing from this technology; for instance, in September 2023, the Netherlands introduced a subsidy scheme for hydrogen used in transport.Footnote 16 Conversely, Denmark is set to shutter all of its hydrogen filling stations by the end of 2024, and it has suspended plans for new ones.Footnote 17 In France, a city that pioneered green hydrogen buses now intends to replace them with electric buses.Footnote 18

The objectives of these European strategies, the attendant legal uncertainties, and the commitment of the EU to develop hydrogen-based transport markets and services, when taken in their totality, mean that there is a compelling case for regulatory intervention. Such an intervention would be crucial for the dismantlement of the barriers that presently obstruct the deployment of hydrogen technology. Given the adoption of the Fit for 55 Package,Footnote 19 several components of the legal framework for hydrogen are now in force. Those components include the revised Renewable Energy Directive (RED III),Footnote 20 the new Energy Efficiency Directive (EED),Footnote 21 the Taxonomy Delegated Act,Footnote 22 and the Delegated Acts on Renewable Hydrogen.Footnote 23 Given the purpose of this chapter, special mention should be made of the recent Regulation 2023/1804 (Alternative Fuels Infrastructure Regulation – AFIR), which addresses the deployment of the alternative fuels infrastructure.Footnote 24

The primary focus of this chapter is on the identification of barriers in the hydrogen value chain. Those barriers may impede the use of hydrogen in the decarbonisation of transport. In particular, the analysis that is presented here zooms into the HRS infrastructure that must be developed for a just and sustainable transition to occur. The chapter is structured as follows: Section 18.2 contextualises the European legislation on hydrogen for transport within the theoretical framework of ‘infrastructure as the fabric of society’, and presents the extant regulatory framework. Section 18.3 identifies the regulatory bottlenecks in the hydrogen value chain that pertain to hydrogen-based transport. Those bottlenecks have to do with production, transport, and storage. Section 18.4 concerns HRSs and the legal issues that affect their rollout. Finally, Section 18.5 provides a summary and charts several avenues for future research.

18.2 Theoretical and Regulatory Framework

The SSM strategy asserts unequivocally that sustainable mobility and transport serve as ‘enabler[s] for our economic and social life’.Footnote 25 They facilitate commutes as well as family and personal trips, they enable the movement of goods and services, they render manufacturing more efficient, and they strengthen territorial cohesion. Beyond its technical utility, infrastructure is valuable because of the services that it provides – ‘infrastructure could be regarded as the fabric of society, on the one hand, because infrastructure provision literally connect[s] everybody, on the other hand, because infrastructure equip[s] every member of society with more or less equal development opportunities’.Footnote 26

For infrastructure to discharge all of those functions in an age of energy transformation,Footnote 27 it must become more complex, including through the construction of new refuelling stations. At the same time, that sophisticated infrastructure ought to be designed with the tenets of the just energy transition in mind;Footnote 28 otherwise, the hydrogen economy might exacerbate inequality in society. The spatial and temporal distribution of the benefits and costs of new technologies must be allocated equitably, and social needs, other than the legitimate demands of economic operators, must be acknowledged. It is also important that bottom-up participation be promoted within the decision-making frameworks that are devised in the course of the transition.Footnote 29

The hydrogen refuelling infrastructure furnishes several paradigmatic examples of energy integration and of the interdependent infrastructural systems that typify energy-transition processes.Footnote 30 In the case of HRSs, physical, energy, and digital infrastructures are linked. As will become evident from the discussion that follows, the elements of the corresponding regulatory framework are tightly intertwined.

18.2.1 The Alternative Fuels Infrastructure Regulation (AFIR)

The significance of the AFIR lies in its comprehensiveness. It is a legal instrument that covers all transportation modes and a wide variety of alternative fuels.Footnote 31 The regulatory strategy is intended to contribute to climate neutrality. In addressing the deficiencies of the hydrogen refuelling infrastructure, the AFIR sets minimum mandatory national targets for the number of publicly accessible HRSs; those targets must be met by December 2030.Footnote 32

According to Article 6 AFIR, the Member States are legally obliged to form HRS networks. For reasons of interoperability, the Member States must ensure that the stations in question have a minimum cumulative daily capacity of 1 tonne and that they are equipped with at least one 700-bar dispenser, which would allow light- and heavy-duty vehicles to be refuelled. The targets in the AFIR reflect the desire to create a dense network of HRSs along the Trans-European Transport Core Network (TEN-T; see Section 18.2.3 below). No two stations should be separated by more than 200 km. It should also be possible for hydrogen-powered vehicles to access refuelling stations in or near cities. Consequently, the AFIR requires the Member States to provide at least one publicly accessible HRS in all urban nodes, as defined by the TEN-T. The need for multimodal hubs for heavy-duty vehicles and other modes of transport should also be considered in determining the optimal locations of the HRSs. A single HRS in an urban node may fulfil the TEN-T requirements if the capacity targets are met. In addition, given the emergence of technologies such as liquid hydrogen, that infrastructure should be developed flexibly. The measures that will be adopted to advance the alternative fuels market and to complete the refuelling network must be delineated in national policy frameworks (Article 14 AFIR). The Member States are required to facilitate genuine and early public participation in the development of those national frameworks – the comprehensive involvement of members of the public other than industry stakeholders is crucial for preventing injustices. It should also be noted that the AFIR contains several provisions on the collection of data and the provision of digital services.

18.2.2 The Trans-European Network for Energy (TEN-E)

The TEN-E policy focuses on the interconnections between the energy infrastructures of the EU Member States. In this policy, eleven priority corridors and three thematic areas are identified as integral components of the network. In the updated TEN-E framework, these corridors span diverse geographic regions and various sectors, such as electricity, the offshore grid, and the hydrogen infrastructure. The 2022 revision of the TEN-E RegulationFootnote 33 aligned it with the climate-neutrality objectives that are outlined in the European Green Deal and the Climate Law. This revision establishes a framework for selecting infrastructure projects of common interest (PCIs)Footnote 34 in fields such as electricity, gas, hydrogen, and CO2. Financial support is available from the Connecting Europe Facility (CEF).Footnote 35 The TEN-E Regulation also contains rules for determining the scope and governance of Ten-Year Network Development Plans (TYNDP). This framework facilitates cross-sectoral planning in gas and electricity, providing investors with a comprehensive overview of the optimal locations of electrolysers, hydrogen transmission and storage infrastructure, and refuelling stations. In addition, it supports the cost-effective integration of energy systems, in accordance with the energy-efficiency-first principle, which will be discussed further later in this chapter (Section 18.2.4). This integration extends to digital and transmission systems, as well as to synergies with the TEN-T, so that it ‘aims to generate additional opportunities for the decarbonisation of transport from the new vision of energy infrastructure planning’.Footnote 36

18.2.3 The Trans-European Transport Network (TEN-T)

As a policy, the TEN-T targets the development of a cohesive, efficient, multimodal, and high-quality transport infrastructure across the EU. The policy covers railways, inland waterways, short shipping routes, and the roads between urban nodes, ports, airports, and cargo terminals. It is governed by the TEN-T Regulation.Footnote 37 The TEN-T Regulation has recently been revised by replacing its previous versionFootnote 38 to ensure that it accords with the EGD, the SSM Strategy, and the Zero Pollution Action Plan.Footnote 39 The 2024 TEN-T Regulation is based on a three-phase approach to the transport network. The TEN-T network will be developed or upgraded gradually in accordance with the new regulation, which sets clear deadlines for completion: the core network by 2030, the extended core network by 2040, and the comprehensive network by 2050. The problems of the 2013 TEN-T included inefficient and unattractive modes of sustainable transport, the inadequate integration of the alternative fuels infrastructure, the use of outdated digital tools for traffic management, insufficient network interoperability, the poor integration of urban nodes into the regulatory framework, and a misalignment between national investment plans and the TEN-T priorities.Footnote 40 The new Regulation is geared towards enhancing synergies between the TEN-T and TEN-E Regulation,Footnote 41 as well as ensuring access, particularly for heavy-duty road vehicles, to the hydrogen that is transported via the TEN-E corridors.Footnote 42 The refuelling stations that are required to that end should be positioned along the TEN-T corridors.Footnote 43 The HS already provides for synergies between the CEF Energy and CEF Transport. Those synergies should enable a dedicated infrastructure for hydrogen to be funded, and should make it easier to finance HRSs.Footnote 44

The new TEN-T Regulation introduces, inter alia, a new provision on PCI, standards for infrastructural development, additional requirements for multimodal freight terminals and urban nodes, and new operational requirements that strengthen the connection between infrastructure planning and transport-service operations.Footnote 45 The charging and refuelling infrastructure for alternative transport fuels must conform to the provisions of the AFIR.Footnote 46 Therefore, the 431 cities that are identified as urban nodes in the TEN-T will be required to formulate Sustainable Urban Mobility Plans (SUMPs) by 2025.Footnote 47 They will also need to comply with the provisions of the AFIR. Accordingly, their plans should provide for the deployment of at least one HRS, which may be integrated into a multimodal hub to serve buses and coaches.Footnote 48

18.2.4 The Energy-Efficiency-First Principle

The European HS casts hydrogen as a promising alternative fuel in transportation, especially when electrification is difficult or infeasible as a matter of practice. This framing of the choice between hydrogen and electricity reflects a preference for the latter – hydrogen is reserved for cases in which electrification would engender extraordinary difficulties. The preference for electrification accords with the notion that cars and vans with directly rechargeable electric batteries are considerably more energy efficient than cars and vans that have fuel cells. That proposition also holds true for the trucks that operate in cities, but not for long-haul heavy-duty trucks. In the latter case, using fuel-cell technology would be more sensible.Footnote 49 In consequence, the preference for transport solutions based on electric vehicles or fuel cells must be justified by reference to the energy-efficiency-first principle.Footnote 50

The SSM strategy posits that ‘energy efficiency shall be a criterion for prioritising future choice of suitable technologies looking at the whole life-cycle’.Footnote 51 Since the adoption of the new EED, the energy-efficiency-first principle has become an overarching principle in energy policy.Footnote 52 The HS refers to two focal areas for the utilisation of hydrogen in mobility. First, hydrogen should be adopted early in ‘captive applications’, such as municipal buses and commercial fleets (for example, taxis). In most cases, those applications have to do with public transportation and highly regulated private services. In such instances, regional or local electrolysers can easily supply HRSs. The introduction of such arrangements ought to be made contingent on a comprehensive analysis of demand for fleets and of the distinct requirements of light- and heavy-duty vehicles. Secondly, the SSM strategy promotes the use of hydrogen fuel cells in heavy-duty vehicles, in conjunction with electrification. The term ‘heavy-duty vehicle’ is defined to include coaches, specialised vehicles, and long-haul freight trucks, all of which produce substantial CO2 emissions. Notably, the 2025 and 2030 targets from the CO2 Emission Standards RegulationFootnote 53 are expected to create an advanced market for hydrogen solutions once fuel-cell technology becomes sufficiently cost effective.

Inspired by efficiency reasons, by way of derogation from the targets for HRSs’ deployment, according to Article 6.4 AFIR, HRS implementation is not required in areas with little heavy-duty vehicle traffic on the TEN-T core network. In such cases, Member States have the flexibility to reduce the capacity of publicly accessible HRSs by up to 50 per cent, as long as specified requirements related to the maximum distance between stations and dispenser pressure are met. The Member States must report all Article 6.4 derogations to the Commission and continuously review the circumstances in which they were imposed to ensure that the conditions that are set out in that article are still being met.

18.3 Regulatory Barriers to the Deployment of Hydrogen Refuelling Stations along the Hydrogen Value Chain

The conditions under which hydrogen can be deployed in the transport sector depend on the entire content of the regulatory framework that governs its production, transport, storage, and supply for end uses, as well as on the legislation that defines the objectives of the transition to renewable energy.Footnote 54 Certainly, the ultimate utilisation of hydrogen for transport and mobility services depends on a series of favourable legal preconditions. These include legislation outlining rules for its production, regulations governing its transport from production sites to points of end use, and storage. This proposition cuts both ways: the regulatory challenges are also shaped by the design of infrastructure.Footnote 55 For example, much depends on whether an HRS supplies hydrogen that is produced in a single facility (in situ production) or in external production plants. In the latter case, hydrogen can be carried through dedicated networks of pipelines; through repurposed natural gas pipelines; or in gaseous or liquefied form, in which case it can be transported by road, rail, or sea. In addition, the regulatory burden on HRSs may come to be as heavy as the one that is imposed on infrastructures that are employed for other purposes.

It is also important to note that, at present, the regulations that affect the hydrogen value chain are largely formulated at the national level. Therefore, it is in the Member States that the main barriers to the rollout of end-use hydrogen in the mobility sector are detected and anticipated. European regulation does not prevent particular Member States, such as Germany,Footnote 56 from developing the necessary infrastructure at a more rapid rate. Harmonisation is of fundamental importance, as is the subsequent monitoring of the transposition and application of the relevant EU law. Furthermore, other types of legislation, such as environmental law, also directly affect the rollout of HRSs.Footnote 57 The regulations that govern environmental impact assessments and integrated environmental authorisation supply salient examples. The subsections that follow outline the regulatory barriers that could influence the uptake of hydrogen in transportation.

18.3.1 The Transport Sector and Hydrogen Production

The production of hydrogen, in contrast to the production of gas or electricity, faced a deficiency in a comprehensive regulatory framework until 2023. This lacuna constituted the initial regulatory impediment to the overall advancement of hydrogen and its application within the transportation sector. The revision of the regulatory framework is poised to accelerate the adoption of production technologies. For instance, the revised Industrial Emissions Directive (IED)Footnote 58 will exempt electrolyser-based production facilities with a capacity below 50 megawatts (MW) from protracted permitting procedures.Footnote 59 This modification will advantage HRSs equipped with on-site hydrogen production. Furthermore, the regulations in force until the first half of 2024 did not differentiate between alternative sources or different purposes;Footnote 60 in addition, a regulatory framework concerning safety indirectly shapes hydrogen production by establishing a set of requirements. For this reason, the legislation did not fully account for the possibility of using hydrogen as an energy vector.Footnote 61

Urban planning restrictions can also obstruct the rollout of HRSs. Hydrogen production typically entails the production of an inorganic gas – that is, it is a chemical-industrial process. This legal classification has important consequences for urban planning because the plants in question, whatever their size, need to be confined to industrial areas. For instance, in Spain, as well as in several other Member States, hydrogen production plants may not be located in urban areas. The EU has limited competences in the domain of urban planning. Therefore, this barrier must be overcome at the national level. Under the current regime, it is difficult for private fuel-cell vehicles to access HRSs outside of cities. Consequently, fuel-cell technology will largely be restricted to heavy-duty vehicles, which are more likely to transit in industrial areas.

The stricter environmental law requirements for small-scale hydrogen production matter, too. Under the Directive on Environmental Assessment,Footnote 62 public and private projects with potentially significant effects on the environment can only be authorised upon completion of an environmental impact assessment. Annex I circumscribes the set of projects for which such assessments are mandatory across the Union. Annex II lists the types of projects that the Member States may subject to environmental impact assessments if they so choose. Even though neither Annex refers to the production, transport, or storage of hydrogen, those activities are highly likely to be caught by the ‘integrated chemical installations’Footnote 63 category in Annex I. Therefore, an environmental impact assessment must be completed for all production installations, including HRSs with in situ production. This arrangement increases the regulatory burden for the operators of small-scale projects, which compromises the financial viability of those projects.

The in situ production of hydrogen for HRSs is expected to occur primarily at small power-to-gas installations that rely on water electrolysis. At those installations, hydrogen is derived from substantial amounts of water. Consequently, in most Member States, it will be necessary for those who run such projects to obtain administrative authorisation or, in cases in which the annual volume of water consumption at the installation is expected to be relatively high, water concessions. Authorisation requirements vary widely across the EU. For instance, in Spain, water is designated as a public good. Therefore, green hydrogen production will likely require the grant of concessions. Such grants are conditional on the order of preference that is contained in the hydrological plans of each river basin district, in which industrial uses other than electricity production tend to come fourth.Footnote 64 Hydrogen production through electrolysis falls into that category, and it is not treated as equivalent to the production of electricity.

18.3.2 Mobility, Transport, and Storage of Hydrogen

The EU can only fulfil its commitment to develop an internal market for hydrogen that smooths the decarbonisation of the economy by building an appropriate infrastructure.Footnote 65 Dedicated hydrogen networks and cross-border networks should enable trade between the Member States while also promoting competition. The success of HRSs with no onsite production depends on the availability of such an infrastructure because pipelines are likely to be the most cost-efficient transportation solution. This is the first legal hurdle encountered in efforts to transport and store pure or blended hydrogen through the gas grid until the adoption of the hydrogen and decarbonised gas market package (the Hydrogen Package).Footnote 66 The main objective of the Hydrogen Package is to adapt the rules that currently apply to the natural gas market to the specificities of the infrastructure for the transport, storage, and supply of hydrogen. The new Package includes specific provisions on dedicated hydrogen networks and storage infrastructure. The European experience in energy shows that three key conditions must be met if market competition is to be guaranteed: open and non-discriminatory access to the network for third parties; regulated tariffs; and rules on unbundling.Footnote 67 For an in-depth analysis of the contents of the Hydrogen Package, see Chapter 2, authored by Leigh Hancher and Simina Cuciu.

The absence of a dedicated regulatory framework for the terrestrial transport of hydrogen is also a cause for concern. Only transport through networks falls within the scope of the Hydrogen Package. Hydrogen can also be transported in liquified or condensed form. In that case, trucks, boats, and trains may be used as means of transportation. Whether these operations are energy efficient depends on the context. The transport of hydrogen by road is regulated by the agreements on the transport of dangerous goods, particularly the European Agreement concerning the International Carriage of Dangerous Goods by Road (ADR) and Directive 2008/68/EC on the inland transport of dangerous goods.Footnote 68 Furthermore, depending on the transport vector, the regulations concerning the International Carriage of Dangerous Goods by Rail (RID) and the European Agreement concerning the International Carriage of Dangerous Goods by Inland Waterways (ADN) also apply. These legal instruments give rise to various regulatory barriers for emerging synthetic compounds classified as Liquids Carriers Organic Hydrogen (LCOH). Notable among them are specific conditions governing the transport of hazardous materials via rail, ship, or road, including designated dates and times. Against this backdrop, as explained previously, the new guidelines of the TEN-T Regulation stress the need to align with the TEN-E and the AFIR to deploy alternative fuels refuelling infrastructure.Footnote 69

The final regulatory problem that ought to be considered here has to do with the hefty environmental law burdens that the providers of small-scale hydrogen storage bear. The Directive on Environmental Assessment is applicable to hydrogen storage. Annex I, which contains a list of projects for which an extensive ex ante assessment is required, refers to facilities for the storage of petroleum, petrochemicals, and chemical products, a category that includes hydrogen. The corresponding obligation to complete an extensive assessment applies to facilities with a capacity of at least 200,000 tonnes. A simplified environmental assessment is mandatory for lower-capacity projects.

18.4 Hydrogen Refuelling Stations

The wide availability of HRSsFootnote 70 is a prerequisite for the adoption of hydrogen as an energy carrier.Footnote 71 This issue poses several economic and regulatory challenges that tend to resemble the classic chicken-and-egg dilemma. If the sustainable energy transition is taken seriously, then the law should incentivise behavioural transformations among the public. Fuel-cell vehicle advocates argue that these vehicles provide a range and refuelling experience comparable to traditional internal combustion engine vehicles.Footnote 72 This situation is posited to confer a competitive edge to hydrogen-powered vehicles over their electric counterparts. Indeed, according to a survey that the Clean Hydrogen Partnership conducted,

only a quarter of customers consider charging times longer than 30 minutes acceptable. This means that even if fast-charging time could be halved, 75% of customers would not be satisfied. Consumer preferences are vital to take into consideration. For the decarbonisation of transport to succeed, consumers must be willing to purchase and drive the offered vehicles. Only if the range of models meet the requirements of consumers will their adoption increase, triggering a further scale-up and acceleration of investment into new models.Footnote 73

These conclusions rest on the presumption that drivers will maintain current usage patterns, disregarding intrinsic energy efficiency considerations. This assumption fails to consider the ongoing evolution of electric battery technology and the potential emergence of new modes of private transportation. Moreover, it neglects the imperative to formulate a sustainable energy policy in the transportation sector that addresses broader societal needs, beyond the preferences of affluent individuals who can afford alternative-fuel vehicles. Consequently, it is crucial to advocate for public policies integrating sustainability, justice, and energy efficiency principles, transcending individual preferences and specific industrial interests. Sustainable mobility plans at various territorial levels, as delineated in the SSM, play a significant role in fostering such integration.

The AFIR imposes binding targets on Member States. The aim of those targets is to ensure that a robust and publicly accessible infrastructure for hydrogen-based road vehicles will be established. The targets call for alignment between the TEN-E and TEN-T at the European level. Such a development would accelerate the flow of investment to hydrogen infrastructure. The alignment in question can only be achieved through sound infrastructural planning, which should be informed by the TYNDPs. Furthermore, it remains unclear whether the Member States will meet the targets for hydrogen refuelling infrastructure that are set forth in AFIR by the 31 December 2030 deadline.

Turning to the specific issue of HRSs, it should be noted that the AFIR does not distinguish between refuelling stations that produce hydrogen onsite and stations that only store it. According to Article 2.59 AFIR, a ‘refuelling station’ is a single physical installation that has one or more refuelling outlets. The emergence of differences in national permit procedures that depend on whether hydrogen is generated onsite or offsite would be highly problematic.

Importantly, the binding targets for a minimum number of stations that are included in the AFIR apply only to publicly accessible HRSs. A ‘publicly accessible’ station is defined as ‘an alternative fuels infrastructure which is located at a site or premises that are open to the general public, irrespective of whether the alternative fuels infrastructure is located on public or private property, whether limitations or conditions apply in terms of access to the site or premise and irrespective of the applicable use conditions of the alternative fuels infrastructure’ (Article 2.45 AFIR). It follows that the enabling legal framework of the AFIR does not apply to refuelling outlets that are located on private property if access to them is restricted to a limited and determinate set of individuals. The parking places of an office building, if they are available only to employees or other authorised individuals, provide a salient example. If the construction of HRSs at such non-publicly accessible premises is cost effective, it may be desirable to consider energy communitiesFootnote 74 or other self-consumption formulas, especially ones that involve industrial participation. Those arrangements could benefit from coverage in the enabling legal frameworks of the RED, the EED, and the Internal Market for Electricity Directive.Footnote 75

The AFIR provides that the national policy frameworks for the deployment of alternative fuels in the transport sector, that the Member States adopt, ought to include measures that eliminate potential impediments to the planning, authorisation, procurement, and operation of alternative fuel infrastructures, be they publicly accessible or not. The responsibility for the effective implementation of measures for the establishment of an adequate hydrogen refuelling infrastructure lies with national legislatures and authorities. Finally, it is important to note that the AFIR establishes an indifference rule for publicly accessible HRSs – the operator or owner of a publicly accessible refuelling station must ensure that the station can serve both light- and heavy-duty vehicles.Footnote 76

18.5 Conclusion

Transport, especially road transport, has witnessed an increase in GHG emissions since 1990. This trend is in stark contrast to those that have been observed in other domains of economic and social activity. For this reason, the decarbonisation of transport would be a stepping stone in the pursuit of the energy and climate targets of the EU. Accordingly, the various European strategies that form part of the regulation of the sustainability transition ascribe a central role to hydrogen, as well as to other alternative fuels.

A complex and coordinated legal framework must be created if the potential of this energy vector is to be exploited fully. That framework remains a work in progress, both as a general matter and in the specific contexts of mobility and transport. This chapter focused on a recent piece of legislation on HRSs, namely the AFIR. It transpires that, as far as infrastructure is concerned, there is a growing regulatory synergy between energy and transport. It is important to underscore that the deployment of end-use hydrogen in the transportation sector will primarily focus on long-haul heavy trucks. In addition, concerning other modes of transportation, such deployment should occur in strict accordance with the notion of a socially just transition and the principle of ‘energy efficiency first’.

HRSs are one element of a large infrastructure. The infrastructure in question must be designed, planned, and implemented to further a broad vision. That vision ought to reflect considerations of, among others, social acceptability, energy efficiency, territorial cohesion, sustainability, and fair access.

The analysis of the regulatory barriers along the hydrogen value chain – that is, the legal problems that may affect the generation, transport, storage, and end use of hydrogen through HRSs – revealed several causes for concern. The AFIR, important though it may be, is not sufficient. Several avenues of research are open at present. First, the understanding of the challenges derived from the new Hydrogen Package. Second, scholars and policymakers must ensure that the content of the Package is coordinated with the content of other relevant instruments, such as the revised TEN-T. Third, a concerted effort should be made to ensure that the transposition, implementation, and planning measures that the Member States will adopt will be consistent with EU law and policy. Finally, the actual rollout of the hydrogen infrastructure should reflect the goals of the just transition, namely social benefits and environmental sustainability.

Footnotes

This chapter is part of the project TED2021-131840B-I00, which is funded by the MCIN/AEI/10.13039/501100011033 and by the European Union ‘NextGenerationEU’/PRTR. Furthermore, this publication contributes to the project 101073195 – THERESA – HORIZON-MSCA-2021 – DN-01.

1 Regulation (EU) 2021/1119 of the European Parliament and of the Council of 30 June 2021 establishing the framework for achieving climate neutrality and amending Regulations (EC) No 401/2009 and (EU) 2018/1999 (European Climate Law) OJ L243/1.

2 Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, ‘Powering a climate-neutral economy: An EU strategy for energy system integration’ (COM) 2020/299 final. Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, ‘A hydrogen strategy for a climate-neutral Europe’ (COM) 2020/301 final (Hydrogen Strategy).

3 Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, ‘Sustainable and Smart Mobility Strategy – putting European transport on track for the future’ (COM) 2020/789 (hereinafter: Sustainable and Smart Mobility Strategy).

4 Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, ‘The European Green Deal’ (COM) 2019/640 final.

5 International Energy Agency, ‘Global CO2 emissions from transport by sub-sector in the Net Zero Scenario, 2000–2030’ (2023) <https://iea.org/data-and-statistics/charts/global-co2-emissions-from-transport-by-sub-sector-in-the-net-zero-scenario-2000-2030-2> accessed 23 January 2024.

8 Ian Tiseo, ‘Greenhouse gas emissions in the European Union 1990–2021, by sector’ (Statista, 23 July 2023) <https://statista.com/statistics/1171183/ghg-emissions-sector-european-union-eu/#statisticContain>accessed 23 January 2024.

9 Destatis, ‘Road transport: EU-wide carbon dioxide emissions have increased by 21% since 1990’ (2023) <https://destatis.de/Europa/EN/Topic/Environment-energy/CarbonDioxideRoadTransport.html> accessed 23 January 2024.

11 Ángel Marrero and others, ‘Convergence in road transport CO2 emissions in Europe (2021) 99 Energy Economics, 1, 16 <https://doi.org/10.1016/j.eneco.2021.105322> accessed 23 January 2024.

12 Gokce Mete and Leonie Reins, ‘Governing new technologies in the energy transition: The hydrogen strategy to the rescue?’ (2020) 14 Carbon and Climate Law Review 210, 224 (hereinafter: Mete and Reins).

13 Sustainable and Smart Mobility Strategy.

14 Footnote Ibid 5, 6.

15 According to data from H2 Live <https://h2.live/en/tankstellen/> accessed 23 January 2024.

16 Leigh Collins, ‘Netherlands unveils €150m plan to subsidise hydrogen trucks, vans, buses and filling stations’ (Hydrogen Insight, 29 September 2023) <https://hydrogeninsight.com/transport/netherlands-unveils-150m-plan-to-subsidise-hydrogen-trucks-vans-buses-and-filling-stations/2-1-1526684> accessed 23 January 2024.

17 Maz Plechinger, Alle brintstationer i Danmark lukke (Energy Watch, 14 September 2023) <https://energiwatch.dk/Energinyt/Renewables/article16427393.ece> accessed 23 January 2024.

18 Anne-Claire Poirier, ‘Les bus à hydrogène ont fait leurs preuves mais ne correspondent pas à tous les besoins’ (La Gazette, 9 November 2023) <https://lagazettedescommunes.com/894648/les-bus-a-hydrogene-ont-fait-leurs-preuves-mais-ne-correspondent-pas-a-tous-les-besoins/> accessed 23 January 2024.

19 Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, ‘“Fit for 55”: delivering the EU’s 2030 Climate Target on the way to climate neutrality’ (COM) 2021/550 final.

20 Directive (EU) 2023/2413 of the European Parliament and of the Council of 18 October 2023 amending Directive (EU) 2018/2001, Regulation (EU) 2018/1999 and Directive 98/70/EC as regards the promotion of energy from renewable sources, and repealing Council Directive (EU) 2015/652 OJL 2413. The RED III sets a binding target of 29 per cent for renewable energy consumption by 2030 in the transport sector, of which 5.5 per cent must be covered by advanced biofuels (generally derived from raw materials that are not produced from food crops) and renewable fuels of non-biological origin (mainly renewable hydrogen and synthetic fuels that are based on hydrogen). In addition, 1 per cent of the renewable energy that the transport sector consumes must come from renewable fuels of non-biological origin (Article 25 RED III).

21 Directive (EU) 2023/1791 of the European Parliament and of the Council of 13 September 2023 on energy efficiency, amending Regulation (EU) 2023/955 OJL 231/1.

22 Commission Delegated Regulation (EU) 2021/2139 of 4 June 2021, supplementing Regulation (EU) 2020/852 of the European Parliament and of the Council by establishing the technical screening criteria for determining the conditions under which an economic activity qualifies as contributing substantially to climate change mitigation or climate change adaptation and for determining whether that economic activity causes no significant harm to any of the other environmental objectives OJL 442/1.

23 Commission Delegated Regulation (EU) 2023/1184 of 10 February 2023 supplementing Directive (EU) 2018/2001 of the European Parliament and of the Council by establishing a Union methodology setting out detailed rules for the production of renewable liquid and gaseous transport fuels of non-biological origin; Commission Delegated Regulation (EU) 2023/1185 of 10 February 2023 supplementing Directive (EU) 2018/2001 of the European Parliament and of the Council by establishing a minimum threshold for greenhouse gas emissions savings of recycled carbon fuels and by specifying a methodology for assessing greenhouse gas emissions savings from renewable liquid and gaseous transport fuels of non-biological origin and from recycled carbon fuels OJL 157/11.

24 Regulation (EU) 2023/1804 of the European Parliament and of the Council of 13 September 2023 on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU OJL 234/1.

25 Sustainable and Smart Mobility Strategy, 1.

26 Margot Weijnen and Aad Correljé, ‘Rethinking Infrastructure as the Fabric of a Changing Society with a Focus on the Energy System’ in Margot Weijnen, Zofia Lukszo, and Samira Farahani (eds), Shaping an Inclusive Energy Transition (Springer 2021) 17, 48 <https://doi.org/10.1007/978-3-030-74586-8_2> accessed 23 January 2024 (hereinafter: Weijnen and Correljé).

27 According to Paterson, the ‘energy transition needs to be reimagined as an energy transformation in order to emphasise the scale and pace of change required to meet climate, security, and equity objectives in a timely manner’. See John Paterson, ‘Energy Law and Energy Transformation’ in Ruven Fleming, Kars de Graaf, Leigh Hancer, and Edwin Woerdman (eds), A Force of Energy: Essays in Energy Law in Honour of Professor Martha Roggenkamp (University of Groningen Press 2022) 20 <https://doi.org/10.21827/61eff4099c992> accessed 23 January 2024.

28 Raphael J Heffron, ‘Energy justice – the triumvirate of tenets revisited and revised’ (2023) 42(2) Journal of Energy and Natural Resources Law 227 <https://doi.org/10.1080/02646811.2023.2256593> accessed 27 July 2024.

29 On the new concepts that have arisen from the energy transition, see Romain Mauger, ‘Making Sense of Changing Concept for Energy Transition: An Energy Transition Concepts Nexus for the Development of Policy and Law’ in Ruven Fleming, Kaisa Huhta, and Leonie Reins (eds), Sustainable Energy Democracy and the Law (Brill 2021) 28.

30 Weijnen and Correljé 35.

31 AFIR Recital 5 and Article 2(4).

32 Footnote Ibid Article 6.

33 Regulation (EU) 2022/869 of the European Parliament and of the Council of 30 May 2022 on guidelines for trans-European energy infrastructure, amending Regulations (EC) No 715/2009, (EU) 2019/942 and (EU) 2019/943 and Directives 2009/73/EC and (EU) 2019/944, and repealing Regulation (EU) No 347/2013 OJL 152/45.

34 Katja Yafimava, ‘The TEN-E Regulation: Allowing a role for decarbonised gas’ (Oxford Institute for Energy Studies 2022) <www.oxfordenergy.org/publications/the-ten-e-regulation-allowing-a-role-for-decarbonised-gas/> accessed 27 July 2024.

35 Regulation (EU) 2021/1153 of the European Parliament and of the Council of 7 July 2021 establishing the Connecting Europe Facility and repealing Regulations (EU) No 1316/2013 and (EU) No 283/2014 OJL 249/38.

36 Mete and Reins 227.

37 Regulation (EU) No 2024/1679 of the European Parliament and of the Council of 13 June 2024 on Union guidelines for the development of the trans-European transport network, amending Regulations (EU) 2021/1153 and (EU) No 913/2010 and repealing Regulation (EU) No 1315/2013 Text with EEA relevance OJ L 2024/1679.

38 Regulation (EU) No 1315/2013 of the European Parliament and of the Council of 11 December 2013 on Union guidelines for the development of the trans-European transport network and repealing Decision No 661/2010/EU Text with EEA relevance OJL 348/1 (hereinafter: TEN-T Regulation).

39 Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions, Pathway to a Healthy Planet for All – EU Action Plan: ‘Towards zero pollution for air, water and soil’ (COM) 2021/400 final.

40 Dieter Frizberg, ‘Briefing – Initial appraisal of a European Commission Impact Assessment. Revision of the Trans-European Transport Network Regulation’ (European Parliamentary Research Service, May 2022) <https://europarl.europa.eu/RegData/etudes/BRIE/2022/730316/EPRS_BRI(2022)730316_EN.pdf> accessed 23 January 2024.

41 TEN-T Regulation Article 5.1(f).

42 Footnote Ibid Recitals 75–76.

43 Mete and Reins 228.

44 Hydrogen Strategy 9.

45 Monika Kiss, ‘Briefing – EU legislation in progress. Revision of the Trans-European Transport network guidelines’ (European Parliamentary Research Service, June 2023) <https://europarl.europa.eu/RegData/etudes/BRIE/2022/729314/EPRS_BRI(2022)729314_EN.pdf> accessed 23 January 2024.

46 TEN-T Regulation Recitals 75–76 and Articles 38 and 41.

47 Footnote Ibid Article 41 and Annex II.

48 Footnote Ibid Article 41.1(c).

49 Transport and Environment, ‘Wednesday’s EU hydrogen strategy needs to prioritise hard-to-decarbonise transport modes’ (3 July 2020) <https://transportenvironment.org/discover/wednesdays-eu-hydrogen-strategy-needs-prioritise-hard-decarbonise-transport-modes/> accessed 23 January 2024.

50 The energy-efficiency-first principle was introduced through Article 2.18 of the Regulation on the Governance of the Energy Union. For a theoretical elaboration, see Tim Mandel and others, ‘Conceptualising the energy efficiency first principle: Insights from theory and practice’ (2022) 15 Energy Efficiency 41 <https://doi.org/10.1007/s12053-022-10053-w> accessed 23 January 2024.

51 Sustainable and Smart Mobility Strategy 4(19).

52 EED Recitals 16–21 and Article 3.

53 Regulation (EU) 2023/851 of the European Parliament and of the Council of 19 April 2023 amending Regulation (EU) 2019/631 as regards strengthening the CO2 emission performance standards for new passenger cars and new light commercial vehicles in line with the Union’s increased climate ambition OJL 110/5.

54 On the hydrogen regulatory challenges, see Íñigo del Guayo Castiella, Lorenzo Mellado, and José Antonio Redondo, ‘Una breve introducción a los retos regulatorios del hidrógeno y otros gases renovables en la Unión Europea, España y Andalucía’ in Iñigo del Guayo Castiella and Lorenzo Mellado Ruiz (eds), Retos Regulatorios de los Gases Renovables en la Economía Circular (Marcial Pons 2023); Kim Talus, Jaqueline Pinto, and Francisca Gallegos, ‘Realism at the end of the rainbow? An argument towards diversifying hydrogen in EU regulation’ (2024) Journal of World Energy Law & Business <https://doi.org/10.1093/jwelb/jwae007> accessed 1 July 2024.

55 On hydrogen policy plans in the European Union across various sectors, see Ruven Fleming, ‘The Hydrogen Revolution and Natural Gas: A New Dawn in the European Union?’ in Damilola Olawuyi and Eduardo Pereira (eds), The Palgrave Handbook of Natural Gas and Global Energy Transitions (Palgrave MacMillan 2022) 123.

56 Matteo Genovese and others, ‘Current standards and configurations for the permitting and operation of hydrogen refueling stations’ (2023) 48(51) International Journal of Hydrogen Energy 19357 <https://doi.org/10.3390/en16062890> accessed 23 January 2024.

57 Ruven Fleming, ‘Clean or renewable – Hydrogen and power-to-gas in EU energy law’ (2021) 39(1) Journal of Energy and Natural Resources Law 43 <https://doi.org/10.1080/02646811.2020.1795382> accessed 23 January 2024.

58 Directive (EU) 2024/1785 of the European Parliament and of the Council amending Directive 2010/75/EU of the European Parliament and of the Council on industrial emission (integrated pollution prevention and control) and Council Directive 1999/31/EC on the landfill of waste.

59 Annex I (j) revised Industrial Emissions Directive OJ L 2024/1785.

60 The only exception is found in the definition of ‘energy storage’, in which hydrogen is covered as follows: ‘the conversion of electrical energy into a form of energy [hydrogen from renewable sources] which can be stored, the storing of such energy, and the subsequent reconversion of such energy into electrical energy or use as another energy’ (Article 2 (59) of Directive 2019/944 of the European Parliament and the Council on common rules for the internal market for electricity OJL 158/125).

61 Lorenzo Mellado RuizMarco Jurídico actual y futuro de la industria del hidrógeno en la Unión Europea: transición energética e hidrógeno verde’ (2023) 125 Revista Vasca de Administración Pública 17 <https://doi.org/10.47623/ivap-rvap.125.2023.01> accessed 23 January 2024 (hereinafter: Mellado Ruiz).

62 Directive 2011/92/EU of the European Parliament and of the Council of 13 December 2011 on the assessment of the effects of certain public and private projects on the environment OJL 26/1.

63 Annex I(6)(b) of Directive 2011/92/EC, defines ‘integrated chemical installations’ as installations for the manufacture, on an industrial scale, of substances through the use of chemical conversion processes in which several units are juxtaposed and linked functionally to one another.

64 Mellado Ruiz 27.

65 Ruven Fleming, ‘Hydrogen Networks: Networks of the Future?’ in Ruven Fleming, Kaars de Graaf, Leigh Hancher, and Edwin Woerdman (eds), A Force of Energy: Essays in Energy Law in Honour of Professor Martha Roggenkamp (University of Groningen Press 2022) 121 <https://doi.org/10.21827/61eff4099c992> accessed 23 January 2024.

66 The Package includes a Directive of the European Parliament and of the Council on common rules for the internal markets in renewable and natural gases and in hydrogen (recast) and a Regulation on the internal markets for renewable and natural gases and for hydrogen (recast).

67 Lavinia Tanase and Ignacio Herrera Anchusteguí, ‘EU Hydrogen and Decarbonized Gas Market Package: Unbundling, Third-Party Access, Tariffs and Discounts Rules at the Core of Transport of Hydrogen’ in Iñigo del Guayo Castiella and Lorenzo Mellado Ruiz (eds), Retos Regulatorios de los Gases Renovables en la Economía Circular (Marcial Pons 2023) <https://dx.doi.org/10.2139/ssrn.4431113> accessed 23 January 2024.

68 Directive 2008/68/EC on the inland transport of dangerous goods OJL 260/13.

69 TEN-T Regulation Article 5(c).

70 Matteo Genovese and Petronilla Fragiacomo, ‘Hydrogen refueling station: Overview of the technological status and research enhancement’ (2023) 61 Journal of Energy Storage 106758 <https://doi.org/10.1016/j.est.2023.106758> accessed 23 January 2024.

71 Mihaela Iordache, Dorin Schitea, and Ioan Iordache, ‘Hydrogen refuelling station infrastructure roll-up, an indicative assessment of the commercial viability and profitability in the Member States of Europe Union’ (2017) 42(50) International Journal of Hydrogen Energy 29629 <https://doi.org/10.1016/j.ijhydene.2017.09.146> accessed 23 January 2024.

72 Clean Hydrogen Partnership, Hydrogen Roadmap Europe: A Sustainable Pathway for the European Energy Transition (Fuel Cells and Hydrogen: Joint Undertaking 2019) 28 <https://clean-hydrogen.europa.eu/system/files/2019-02/Hydrogen%2520Roadmap%2520Europe_Report.pdf> accessed 23 January 2024.

74 Benedetto Nastasi and Stefano Mazzoni, ‘Renewable hydrogen energy communities: Layouts towards off-grid operation’ (2023) 291 Energy Conversion and Management 117293 <www.sciencedirect.com/science/article/pii/S0196890423006398> accessed 27 July 2024.

75 Directive (EU) 2019/944 of the European Parliament and of the Council of 5 June 2019 on common rules for the internal market for electricity and amending Directive 2012/27/EU OJL 158/125.

76 AFIR Article 6 and Recital 35.

References

Further Reading

del Guayo Castiella, I and Mellado Ruiz, L (eds), Retos Regulatorios de los Gases Renovables en la Economía Circular (Marcial Pons 2023)CrossRefGoogle Scholar
Fleming, R, ‘The Hydrogen Revolution and Natural Gas: A New Dawn in the European Union?’ in Olawuyi, Damilola and Pereira, Eduardo (eds), The Palgrave Handbook of Natural Gas and Global Energy Transitions (Palgrave MacMillan 2022)Google Scholar
Fleming, R, ‘Clean or renewable – hydrogen and power-to-gas in EU energy law’ (2021) 39(1) Journal of Energy and Natural Resources Law 43 <https://doi.org/10.1080/02646811.2020.1795382>CrossRefGoogle Scholar
Genovese, M, Cigolotti, V, Jannelli, E, and Fragiacomo, P, ‘Current standards and configurations for the permitting and operation of hydrogen refueling stations’ (2023) 48(51) International Journal of Hydrogen Energy 19357 <https://doi.org/10.1016/j.ijhydene.2023.01.324>CrossRefGoogle Scholar
Genovese, M and Fragiacomo, P, ‘Hydrogen refueling station: Overview of the technological status and research enhancement’ (2023) 61 Journal of Energy Storage 106758 <https://doi.org/10.1016/j.est.2023.106758>CrossRefGoogle Scholar
Heffron, RJ, ‘Energy justice – the triumvirate of tenets revisited and revised’ (2023) 42(2) Journal of Energy & Natural Resources Law 227 <https://doi.org/10.1080/02646811.2023.2256593>CrossRefGoogle Scholar
Iordache, M, Schitea, D, and Iordache, I, ‘Hydrogen refuelling station infrastructure roll-up, an indicative assessment of the commercial viability and profitability in the Member States of Europe Union’ (2017) 42(50) International Journal of Hydrogen Energy 29629 <https://doi.org/10.1016/j.ijhydene.2017.09.146>CrossRefGoogle Scholar
Mauger, R, ‘Making Sense of Changing Concept for Energy Transition: An Energy Transition Concepts Nexus for the Development of Policy and Law’ in Fleming, Ruven, Huhta, Kaisa, and Reins, Leonie (eds), Sustainable Energy Democracy and the Law (Brill, 2021)Google Scholar
Mete, G and Reins, L, ‘Governing new technologies in the energy transition: The hydrogen strategy to the rescue?’ (2020) 14 Carbon and Climate Law Review 210CrossRefGoogle Scholar
Weijnen, M and Correljé, A, ‘Rethinking Infrastructure as the Fabric of a Changing Society – With a Focus on the Energy System’ in Weijnen, Margot, Lukszo, Zofia, and Farahani, Samira (eds), Shaping an Inclusive Energy Transition (Springer 2021) <https://doi.org/10.1007/978-3-030-74586-8_2>CrossRefGoogle Scholar
Figure 0

Figure 18.1 Global emissions from transport.

Source: International Energy Agency, ‘Global CO2 emissions from transport by sub-sector in the Net Zero Scenario, 2000–2030’ (2023) https://iea.org/data-and-statistics/charts/global-co2-emissions-from-transport-by-sub-sector-in-the-net-zero-scenario-2000-2030-2>

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