Energy research and innovation strategy

In July 2020, the Commission adopted the Hydrogen Strategy with the aim of decarbonising its production and to expand its use to store, transport and accelerate the use of renewable energy, as well as replacing fossil fuels in specific sectors, aiming to substantially increase electrolyser capacity by 2030. Investments in production capacity are estimated at €180-470 billion in the EU until 2050 at least, ‘renewables' producing up to 10 million tonnes of clean hydrogen.

The strategy identifies as a clear priority the production of renewable hydrogen, i.e. hydrogen produced through electrolysis using renewable electricity, while remaining open to new or breakthrough technologies for producing renewable hydrogen. In this context, a top priority is to demonstrate larger size, more efficient and cost-effective electrolysers, with capacities reaching 100 MW and above.

The necessary coordination, along the value chain with the European Clean Hydrogen Alliance, and on data and knowledge with the observatory and database set up under the Fuel Cells and Hydrogen Joint Undertaking, is foreseen.

Aviation is the second highest transport sector after road vehicles, and the fastest growing. Reducing aviation emissions is challenging, considering the long operational life of aircraft and the fact that zero-emission aircraft configurations and powertrain options for commercial air transport are far from technological and commercial maturity. Sustainable aviation fuels can significantly reduce aviation reliance on fossil fuels, while relying on existing infrastructure and propulsion systems, but the transition will require significant investments.

While several sustainable aviation fuels production pathways are certified, their use in the fuel mix is still negligible (less than 0.1%) due to high production costs. The price of the most innovative and sustainable types of fuels is estimated at up to 3 to 6 times the price of fossil aviation fuels depending on the production pathway, while their lifecycle emissions savings are 85% or more compared to fossil fuels.

As part of the Fit for 55 package, the Commission has therefore proposed the ReFuelEU Aviation initiative to boost the supply and use of sustainable aviation fuels in the EU. The action will support the development of the most innovative sustainable aviation fuels notably advanced biofuels and Renewable Fuels of Non Biological Origin in line with the ReFuelEU Aviation and Renewable Energy Directive sustainability framework.

At any moment in time, electricity consumption and generation have to be perfectly matched. This balance is necessary not only in the short term for power grid stabilisation (for which short duration storage solutions exist), but also over the long term, by compensating for weekly fluctuations, for meteorological dark and still periods that can last a few weeks, and for seasonal variations between summer and winter.

Long duration renewable energy storage needs – weekly to seasonal – will expand as both the electrification of demand and the share of renewable energy sources in the total supply mix will grow. Sustainable long duration energy storage therefore has a key role to play in the transition towards a carbon-neutral economy.

Sustainable storage solutions for renewable energy, involving an energy vector that can be used for other purposes than regenerating electricity are also eligible. The topic is open to all technologies: chemical (including hydrogen and its derivatives), electrochemical, thermal and mechanical technologies (other than pumped hydro which is mature and available commercially).

Commission scenarios reaching net-zero emission by 2050 show extensive use of carbon dioxide removal, including direct air capture of CO₂ (a new technology that removes carbon directly from the atmosphere, which differs from carbon capture and storage in that it does not have to be placed directly at the source of emissions) .

Most IPCC scenarios modelling 1.5°C paths also include a share of carbon dioxide removal. Direct air capture offers promise as a new technology to help meet this ambitious goal, but several challenges remain for a large-scale deployment.

The future operational and financial viability shall also be investigated in function of the fate of the captured CO₂ (i.e. underground storage or use), renewable energy source used for the capture process, and vicinity to CO₂ transport and storage infrastructure (in case of underground storage).

The International Energy Agency estimates current direct air capture costs to be within a wide range of $100-$1000 per captured tonne of CO₂. Stakeholders claim that costs can be reduced to €50-€100 by 2030 with sufficient investments in research and innovation and deployment.

Rapid innovation is needed to bring to market clean technologies for those parts of the energy system where emissions are harder to address, in particular carbon intensive industries (e.g. steel, cement, chemicals, aluminium, ceramics).

Carbon capture, utilisation and storage (CCUS) will play an important role in mitigating those hard-to-abate process emissions. In March 2023 the European Commission introduced the Net Zero Industry Act, which identifies CCUS as a strategic net zero technology for which scaling up of manufacturing capacity is critical to reaching the EU’s climate goals.

Specifically, the Act proposes to set an EU-wide goal to achieve an annual CO2 injection capacity of 50 Mt by 2030, with oil and gas producers asked to contribute, in addition to setting clear timelines for permitting CCUS projects. While CCUS technologies have been demonstrated in various settings and on certain scales, it is still a challenge to scale up these technologies for widespread use, understand their performance and requirements and develop the best models for their deployment.

This is due to factors such as energy efficiency, cost of capture technologies, and the technical feasibility of transporting and storing large volumes of CO2.