Analysis

Identifying areas for EU-UK energy and climate cooperation

Energy and climate cooperation has mutual benefits for the UK and EU, the obstacles are political

Publishing date
26 September 2024
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Energy cooperation

Despite Brexit, the European Union and United Kingdom remain linked through energy. In 2023, trade in energy accounted for 10 percent of EU-UK trade, and energy accounted for 20 percent of the UK’s exports to the EU 1 Calculated from Eurostat database, ds-045409. Energy includes electricity (2716), crude oil (2709), oil products (2710) and natural gas (2711). . The UK is a major supplier of crude oil to the EU with around €1 billion in exports monthly. Increased exports of natural gas and electricity from the UK into north-west Europe were essential for surviving the winter 2022-23 energy crisis 2 The UK acted as a ‘land bridge’ for natural gas to reach north-western Europe. Large UK import capacities for liquefied natural gas were utilised, with gas re-exported via pipelines into Belgium and the Netherlands, where capacities for directly importing LNG are limited.  (Figure 1).

This post-Brexit bilateral relationship is based on the Trade and Cooperation Agreement (TCA), signed by the EU and the UK in May 2021 3 See Ofgem, ‘Interconnectors’, undated, https://www.ofgem.gov.uk/energy-policy-and-regulation/policy-and-regula…. . It includes specific provisions on electricity and natural gas trade that have so far sustained cross-border energy flows in those commodities. However, the temporary nature of these trading arrangements weakens the business case for British and European companies to make clean energy investments. Establishing a more solid relationship on energy has also been hampered by political red lines, with UK policymakers keen to avoid any notion of ‘rejoining’ elements of Brussels bureaucracy and European policymakers keen to dispel the notion that the UK, having left the single market, can pick-and-choose areas for policy alignment.

The change in UK government in July 2024 may enable an improvement in energy trading relations with the EU. On energy and climate policy, the UK and EU have more in common than differences, and deeper cooperation can be mutually beneficial. The shared renewable resource in the North Sea means cooperation can lower the cost of the energy transition for both.

Deeper cooperation can be realised through a series of bespoke arrangements. First, the current temporary electricity trading arrangements should be agreed and finalised. Second, trade disruptions arising from carbon border tariffs should be mitigated, especially when the results might be counterproductive. Third, the UK and EU should approach climate policy – on which they share similar ambitions – as an area for cooperation on the international stage to leverage shared goals.

Deeper cooperation will enable a smoother energy transition

The main opportunity for deeper cooperation on energy is with electricity. Cooperation should be framed by three related aims: 

  1. Constructing new electricity infrastructure;

  2. Ensuring the physical security of that infrastructure;

  3. Facilitating efficient electricity trade via that infrastructure.

A shared priority is the development of electricity infrastructure to exploit the huge offshore wind potential of the North Sea, which could meet 45 percent of the electricity demand of North Sea countries by 2050 (Danish Energy Agency, 2022). Making full use of these renewable resources will require generation and interconnection capacity to be built and hybrid energy projects to be carried out 4 Hybrid projects would combine offshore wind electricity generation with interconnection and potentially green hydrogen production, typically involving an ‘energy island’, which would be the hub for a set of projects. In a ‘meshed offshore grid’, such infrastructure nodes would be interconnected across the North Sea, as well as to coastal countries, allowing for efficient secure usage of offshore resources. . Cost savings and less reliance on fossil fuels can be realised by distributing and interconnecting generation capacity across the North Sea, smoothing the output from variable renewables to more efficiently balance supply and demand (Zachmann et al, 2024). 

The UK currently has 9.8 gigawatts (GW) of interconnection capacity with European countries, approximately one fifth of its peak demand. This is a relatively high degree of physical integration, given that EU countries have a target of 15 percent interconnection capacity relative to peak demand by 2030. Approval has been granted for another 4.4 GW of interconnection capacity between the UK and the EU 5 See Ofgem, ‘Interconnectors’, undated, https://www.ofgem.gov.uk/energy-policy-and-regulation/policy-and-regula…. . Figure 2 shows existing and planned interconnectors, existing offshore wind capacities and targets for 2030.

Figure 2: Offshore wind and electricity cables across the North Sea

2

As the North Sea becomes a major energy resource for Europe, the physical security of infrastructure will become increasingly important for energy security. Explosions on the Nord Stream pipeline and damage to energy infrastructure in the Baltics demonstrate the material risks.

Political dialogue on the North Sea

The North Seas Energy Cooperation (NSEC) is a collaboration between EU countries in the region 6 Belgium, Denmark, France, Germany, Ireland, Luxembourg, the Netherlands, Norway, Sweden and the European Commission are current NSEC members.  to develop the offshore grid and renewable potential in the North Sea. The UK left NSEC after Brexit, but a memorandum of understanding between NSEC participants and the UK was signed in December 2022 to establish core areas of cooperation, including hybrid projects, planning, finance and knowledge sharing. The Ostend Declaration 7 Government of the Netherlands, ‘Ostend Declaration on the North Sea as Europe , a non-binding agreement between North Sea countries, followed in 2023, laying out plans to expand offshore wind capacity and transmission infrastructure. A target was set to quadruple current offshore wind capacity in the North Sea to 120 GW by 2030, and to increase it by a factor of ten, to 300 GW, by 2050. Such agreements signal a common level of ambition, yet substantially more concrete commitments and policy detail are needed on the regulatory regime for North Sea offshore wind projects 8 Simone Tagliapietra, ‘North Sea Summit: blowing in the wind?’ First Glance, 25 April 2023, Bruegel https://www.bruegel.org/first-glance/north-sea-summit-blowing-wind.  (Tagliapietra, 2023). 

Policy design risks impeding efficient investments and trade

After the UK’s exit from the EU’s integrated wholesale electricity markets at the end of the Brexit transition period in January 2021, electricity trading across interconnectors in the Channel and the North Sea reverted to a less-efficient arrangement 9 In the EU’s integrated wholesale market (often called Single Day Ahead Coupling), price zones are coupled implicitly, meaning that cross-border transmission capacity and electricity flows are determined in a single market-clearing process. Post-Brexit trading arrangements between the EU and UK involve explicit coupling, with transmission capacity and actual electricity exchanges auctioned separately, leading to potential underutilisation of interconnectors. . Current rules are sufficient to ensure security of supply but may inhibit the development of shared assets in the North Sea.

The TCA committed to establishing a more integrated trading model, yet finalised arrangements have yet to materialise 10 Efforts have been made to implement so-called ‘Multi-Region Loose Volume Coupling’, an arrangement that would bring the UK and EU wholesale electricity markets closer while preserving some regulatory independence. . For offshore wind developers and their financiers, it is presently unclear what future trading regime they will be subject to. If divergent arrangements persist, hybrid offshore wind projects will face the administrative burden of simultaneously operating in separate regulatory zones, potentially increasing costs or slowing down project development.

National Grid, the UK’s transmission system operator, has stated its desire to rejoin fully the EU’s integrated wholesale markets 11 Alex Blackburne, ‘National Grid urges relinking UK, EU power markets to boost trading after Brexit’, SPGlobal, 5 April 2024, https://www.spglobal.com/marketintelligence/en/news-insights/latest-new…. . Full participation would be economically optimal for both parties and would minimise regulatory uncertainty for offshore wind projects. The full integration of non-EU member Norway into the EU’s electricity markets demonstrates that extra-EU arrangements for integrated electricity trading are feasible.

The EU concluded an electricity market reform in 2024, while the UK at time of writing is assessing consultation responses to its own reform proposals. Both jurisdictions should consider regulatory compatibility in any future market design changes. 

Climate cooperation: aligned ambitions

On climate policy, the EU and the UK have similar ambitions. Progress has also been broadly similar judged by reductions in greenhouse gas emissions per capita, reduced carbon intensity of electricity generation and increased electric vehicle registrations (the UK is marginally ahead on all three; Figure 3). The TCA includes a commitment to ‘non-regression’, committing both parties to not reduce current levels of climate ambition and to support the goals of the Paris Agreement.

Avoid regulatory-driven disruptions

But while ambitions are aligned, policies are, and will likely continue to be, different. A case in point is the introduction of separate EU and UK carbon border adjustment mechanisms (CBAMs). These mechanisms impose a carbon price at the border for imports that are not subject to domestic carbon prices. The tariff is waived or reduced if imports come from a region that imposes a commensurate carbon price. The EU CBAM has already entered its implementation phase, while the UK CBAM is set to be introduced in 2027. 

The EU and UK have very similar carbon cap-and-trade pricing schemes, with the UK largely replicating the EU system since Brexit. However, prices are determined by domestic markets and the differential between EU and UK prices has fluctuated substantially (Figure 4). These fluctuations might require UK exporters that sell to the EU and EU exporters that sell to the UK to pay additional tariffs. A non-tariff barrier to trade is also created owing to the administrative burden of calculating and complying with the regulation. 

For industrial goods including steel and chemicals, this creates a trade barrier but does have some rational climate justification. For the trade in electricity, the situation is different. The EU’s CBAM methodology for assessing the carbon content of imported electricity is based on historical average grid emissions 12 The CBAM regulation envisages that, under certain circumstances (including a power purchase agreement being signed and no cross-border grid capacity congestion), facilities may be exempted from the default calculations. See part 5 of Annex IV of Regulation (EU) 2023/956. The extent to which these will apply to UK trade is not clear. . However, UK exports into the EU (or vice versa) occur during periods of excess electricity generation, which typically means high renewable output and significantly lower than average historical emissions. Without careful design and implementation, a well-intended CBAM might penalise the export of renewable electricity and increase emissions. AFRY (2024) found that the EU CBAM introduction in 2026 would lead to greater curtailment of renewable electricity and a net increase in annual carbon emissions.

An obvious solution to this would be for the UK to rejoin the EU’s emissions trading system – which originates from the system designed by the UK in 2002. Logistically, this is feasible, because the EU and UK systems have remained essentially identical and non-EU members Iceland, Liechtenstein, Norway and Switzerland already participate in the EU ETS. Politically, it might be more difficult, as with electricity market integration, because of the UK reticence about being seen to rejoin EU mechanisms. A solution is needed to at minimum resolve adverse electricity trading outcomes.

Two future areas for possible expanded cooperation are carbon dioxide storage and critical mineral supplies. The North Sea has significant potential for sequestering carbon, while ensuring the supply of critical raw materials – relevant especially for clean-tech supply chains – is a priority for both the EU and the UK.

Leverage aligned climate ambitions on the international stage

Climate cooperation at international level is particularly relevant, as all countries are required to submit their updated nationally determined contributions (NDCs) ahead of the United Nations climate summit (COP30) in 2025. The NDCs will outline national emissions-reduction plans up to 2035 and will largely determine whether the world can get onto an emissions trajectory in line with the goals of the Paris Agreement. These updates have been called by the UNFCCC “the most important documents to be produced in a multilateral context so far this century”.

The EU and the UK could jointly play an important role in fostering global momentum for this new round of NDCs and might also make a joint diplomatic push to turn these new NDCs into comprehensive national green transition plans, integrating concrete projects and initiatives. By linking these plans to climate finance disbursement, particularly in emerging markets and developing economies, incentives can be created for robust development and implementation. This linkage will ensure that financial support is aligned with the priorities outlined in NDCs, facilitating effective climate action.

The EU and UK are also important players in Just Transition Partnerships (JETPs), launched at COP26 in 2021 to provide tailored financial assistance to specific countries, combining public and private funding from G7 countries to support power-sector decarbonisation strategies. The EU and the UK are among the main funders of JETPs, alongside the United States and development banks, and can thus help in fostering their development and increasing their effectiveness. JETPs are currently hampered by inadequate funding and a lack of explicit policy-action links. They also need improved governance and monitoring frameworks (Bolton et al, 2024).

Conclusions 

In energy and climate policy, cooperation offers mutual benefit to the UK and EU, making it a strong contender for helping rebuild the post-Brexit relationship. The focus should be on three areas: efficient electricity trading, resolving CBAM trade barriers and leveraging shared climate ambition and similar policies in an international context.

Treated in isolation as techno-economic problems, solutions in these areas seem feasible. The real challenges stem from broader political discourse and negotiations between the EU and the UK. For the UK, any agreements must avoid connotations of rejoining the EU. While for the EU, bespoke arrangements must avoid the notion of the UK ‘cherry picking’ policies. 

References

AFRY (2024) EU CBAM impact study focused on electricity imports from Great Britain, AFRY Management Consulting, available at https://afry.com/sites/default/files/2024-03/afry_eu_cbam_impact_study_summary_report_mar_2024_v300.pdf

Danish Energy Agency (2022) Offshore Wind Potential in the North Sea, 25 March, available at https://ens.dk/sites/ens.dk/files/Vindenergi/offshore_wind_potential_in_the_north_sea.pdf 

Zachmann, G., C. Batlle, F. Beaude, C. Maurer, M. Morawiecka and F. Roques (2024) ‘Unity in power, power in unity: why the EU needs more integrated electricity markets’, Policy Brief 2024/03, Bruegel, available at https://www.bruegel.org/policy-brief/unity-power-power-unity-why-eu-needs-more-integrated-electricity-markets

About the authors

  • Conall Heussaff

    Conall is a Research analyst at Bruegel working on energy and climate policy. He studied his BSc in Theoretical Physics at University College Dublin. He then undertook an MSc in Climate Sciences with a special qualification in Economics at the University of Bern, Switzerland, including one semester spent at the National Economic and Social Council (NESC) in Dublin. At NESC, Conall researched Ireland’s energy and economic modelling capabilities. 


    His MSc thesis applied a stylised industrial organisation model to the Irish electricity sector, investigating the climate, economic and social impacts of incentivising community energy development. Before joining Bruegel, Conall worked on the Wholesale Electricity Markets team at the Commission for Regulation of Utilities, the Irish energy regulator. 


    Conall is an Irish citizen and is a native speaker of English and the Irish language. 
     

  • Ben McWilliams

    Ben is working for Bruegel as an Affiliate fellow in the field of Energy and Climate Policy. His work involves data-driven analysis to critique and inform European public policy, specifically in the area of the energy sector and its decarbonisation. Recent work has focussed on the implications of the ongoing energy crisis and policy options for responding. Other topics of interest include tools for stimulating industrial decarbonisation and the implications for new economic geography from the advent of new energy systems, particularly from hydrogen. 

    He studied his MSc in Economic Policy at Utrecht University, completing a thesis investigating the economic effects of carbon taxation in British Colombia. Previously, he studied his BSc Economics at the University of Warwick, with one year spent studying at the University of Monash, Melbourne.

    Ben is a dual British and Dutch citizen.

  • Simone Tagliapietra

    Simone Tagliapietra is a Senior fellow at Bruegel.

    He is also a Part-time professor at the Florence School of Transnational Governance (STG) of the European University Institute and an Adjunct professor at the School of Advanced International Studies (SAIS) Europe of The Johns Hopkins University.

    His research focuses on the EU climate and energy policy, and on its industrial and social dimensions. With a record of numerous policy and scientific publications, also in leading journals such as Nature and Science, he is the author of Global Energy Fundamentals (Cambridge University Press, 2020) and co-author of The Macroeconomics of Decarbonisation (Cambridge University Press, 2024).

    On the basis of his policy and scientific production, Dr. Tagliapietra regularly supports EU and national institutions in the development of their public policies in the field of climate and energy, also through regular interaction with public decision-makers in EU and national institutions, as well as through regular parliamentary testimonies in the European Parliament and various national parliamentary assemblies inside and outside Europe, such as the French Senate, the UK House of Lords and the US Senate. His columns and policy work are widely published and cited in leading international media.

    Dr. Tagliapietra also is a Member of the Board of Directors of the Clean Air Task Force (CATF) and Senior associate of the Payne Institute at the Colorado School of Mines in Golden. He holds a PhD in International Political Economy from the Catholic University of Milan, where he previously graduated under the supervision of Professor Alberto Quadrio Curzio and where he also served as an Assistant professor (tenure-track) until 2024. Born in the Dolomites in 1988, he speaks Italian, English and French.

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