The roadmap, developed with the input of more than a hundred materials experts from the UK research community and industry, highlights five major areas of work required to enable the materials for future fusion power plants.
Fusion – the same principle by which the sun creates heat and light – has the potential to be an abundant, low-carbon and safe part of the world’s future sustainable energy supply.
Recent advances in the technology mean that prototype fusion power stations are now being designed, with the UK’s STEP (Spherical Tokamak for Energy Production) plant due to go online in the early 2040s.
The leading contender for fusion power plants is the ‘tokamak’ – a ring-shaped machine in which fuel is confined with powerful magnets and heated until particles fuse together. The fusion process produces high-energy neutrons that can be turned into electricity, but which could also significantly damage and irradiate materials within the device.
Identifying, developing and qualifying the right materials is key to delivering commercial fusion for two reasons. First, plant efficiencies, safety and availability often hinge on the quality of the component materials. Second, a sustainable fuel cycle requires highly productive fuel breeding materials. Both plant components and fuel breeder materials will need to withstand a highly challenging combination of neutron bombardment and thermal, magnetic, electric and mechanical loads in a tokamak power plant.
The five priority areas identified by the UK Fusion Materials Roadmap are:
- Novel materials to minimise the amount of activation in the structure of the fusion power plant;
- Compounds that can be used within the power plant to optimise breeding of tritium fuel to sustain the fusion process;
- Magnets and insulators that are resistant to irradiation from fusion reactions – especially under cryogenic (the production and behaviour of materials at very low temperatures) conditions;
- Structural materials able to retain their strength under neutron bombardment at high operating temperatures (over 550 degrees C);
- Engineering assurance for fusion materials – providing irradiated sample data and modelled predictions such that plant designers, operators and regulators have confidence that materials are suitable for use in future commercial power stations.
Dr Amanda Quadling, Director of Materials at UKAEA said: “This roadmap is a national tool that aims to give UK materials researchers common themes to collaborate around. We hope to generate momentum in the testing, mechanistic understanding, and surmounting of, irradiation damage from fusion.
“The roadmap is also a teaching document for those who wish to learn more about fusion materials from a supply chain and regulatory point of view.
“It will help to form new partnerships across a wide range of materials stakeholders so we can bring fusion electricity to the world as quickly as possible.”
Professor David Knowles, CEO, Henry Royce Institute, said: “The technological challenges of delivering fusion energy into practical application demand the development of materials which can withstand the extremely severe operational conditions of fusion power plants. We now need to pursue, as a matter of urgency, the development of novel materials which engineers can use to reliably withstand fusion plants demanding environments such high temperatures, severe irradiation and rapid thermal cycling gradients.
“This important materials roadmap published by Royce and UKAEA sets out what we need to do to ensure we can deliver on one of the most challenging technological missions we have ever faced; the controlled exploitation of fusion using a tokamak technology has the potential to deliver low-carbon fuel abundance to the benefit for millennia to come.”
The UK Fusion Materials Roadmap is available from The Henry Royce Institute website at: https://www.royce.ac.uk/collaborate/roadmapping-landscaping/fusion/