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Spherical Tokamak for Energy Production

Coordinates: 53°22′N 0°49′W / 53.36°N 0.81°W / 53.36; -0.81
From Wikipedia, the free encyclopedia

Spherical Tokamak for Energy Production (STEP) is a spherical tokamak fusion plant concept proposed by the United Kingdom Atomic Energy Authority (UKAEA) and funded by the UK government.[1][2][3] The project is a proposed DEMO-class successor device to the ITER tokamak proof-of-concept of a fusion plant, the most advanced tokamak fusion reactor to date, which is scheduled to achieve a 'burning plasma' in 2035. STEP aims to produce net electricity from fusion on a timescale of 2040. Jacob Rees-Mogg, the UK Secretary of State for Business, Energy and Industrial Strategy, announced West Burton A power station in Nottinghamshire as its site on 3 October 2022 during the Conservative Party Conference.[4] A coal-fired power station at the site ceased production a few days earlier.[5] The reactor is planned to have a 100 MW electrical output and be tritium self-sufficient via fuel breeding.[6]

Plans

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In September 2019, the United Kingdom announced a planned £200-million (US$248-million) investment to produce a design for STEP. The funding covers the initial five year concept design phase, while the total capital costs are estimated to be several billion pounds. STEP should be operational by the early 2040s.[7] In February 2023 the UK government established a new delivery body for STEP, UK Industrial Fusion Solutions Ltd., under the UKAEA.[8]

The planned UK facility is based on a ‘tokamak’ design that uses magnetic fields to confine a plasma of heavy isotopes of hydrogen, tritium and deuterium, which fuse under extreme heat and pressure. STEP would be a variant on the basic tokamak, a spherical tokamak that holds the plasma in a cored-apple shape. UKAEA's MAST Upgrade spherical tokamak device started operation in October 2020, and will heavily inform the STEP design.[9] With a total diameter of only around 10 m, STEP will be relatively small in comparison to ITER. This greatly reduces the cost, but also puts higher stress on the applied materials.[10]

The construction of STEP is designed to occur over three phases. The first phase, from 2019 to 2024, should create an integrated concept design for the reactor together with a strategy to amass an intellectual property portfolio and manage technical risks. Additionally, it will locate a UK site and establish the operational framework for the venture. The second phase, from 2025 to 2032, will develop the engineering design, including testing and optimizing subsystems, at which stage the STEP site will begin to see a range of engineering activities. In the third phase, from 2032 to 2040, the SPR will be constructed and commissioned.[10]

The reactor's current goal is an electrical output of 100 MWe and will breed its own tritium via Tritium Breeding Modules.[6]

Goals and objectives

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According to the UKAEA, STEP is designed to complement, not replace, private-sector development of fusion through synergies such as providing an enhanced research suite of facilities, an integrated design framework which can both inform private-sector activities and serve to solicit a private-sector supply chain of components and subsystems, a UK regulatory framework for fusion, and the training of a national fusion workforce.[10]

The STEP programme is designed to achieve the following objectives:[10]

  • Deliver outputs to help inform a fusion regulatory framework
  • Stimulate commercial investment
  • Innovate, creating solutions that find near term applications in adjacent sectors
  • Stimulate growth of the fusion energy supply chain through partnering
  • Nurture skills in a diverse and inclusive way, training those who will deliver fusion power and supporting skills growth in adjacent sectors
  • Support industry to develop designs for a first commercial fleet of fusion reactors to follow the SPR [STEP Prototype Reactor]
  • Develop the new STEP site and associated infrastructure

See also

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References

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  1. ^ Gibney, Elizabeth (11 October 2019). "UK hatches plan to build world's first fusion power plant". Nature. doi:10.1038/d41586-019-03039-9. PMID 33037417. S2CID 208833905.
  2. ^ Allison, Peter Ray (15 December 2020). "The UK's quest for affordable fusion by 2040". BBC. Retrieved 8 February 2021.
  3. ^ Chapman, I. T.; Cowley, S. C.; Wilson, H. R. (2024-10-09). "The Spherical Tokamak for Energy Production: theme issue introduction". Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 382 (2280). doi:10.1098/rsta.2023.0416. ISSN 1364-503X. PMC 11515121.
  4. ^ Roe, Tony; Smith, Alex (3 October 2022). "Nuclear fusion plant to be built at West Burton A power station". BBC News. Retrieved 4 October 2022.
  5. ^ Edwardes-Evans, Henry (21 March 2021). "EDF Energy confirms end-September 2022 closure for West Burton A coal plant". SPGlobal. Retrieved 22 March 2021.
  6. ^ a b "Whole Plant Partners' engagement" (PDF). STEP UKAEA Web Portal. 22 February 2023. Retrieved 4 April 2023.
  7. ^ Daniel Clerry (2 December 2020). "U.K. seeks site for world's first fusion power station". Science Magazine. doi:10.1126/science.abf9768. S2CID 230611562.
  8. ^ Hamilton, Kirsty (7 February 2023). "Science Minister announces new delivering body for West Burton fusion project". Worksop Guardian.
  9. ^ Rincon, Paul (29 October 2020). "EUROATOM fusion experiment in UK used in hunt for clean energy". BBC News Online. Retrieved 30 October 2020.
  10. ^ a b c d Wilson, Howard; Chapman, Ian; Denton, Tris; Morris, William; Patel, Bhavin; Voss, Garry; Waldon, Chris; the STEP Team (2020), "STEP—on the pathway to fusion commercialization", Commercialising Fusion Energy, IOP Publishing, doi:10.1088/978-0-7503-2719-0ch8, ISBN 978-0-7503-2719-0, S2CID 234565909, retrieved 13 December 2021
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53°22′N 0°49′W / 53.36°N 0.81°W / 53.36; -0.81