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Stellarator–mirror fusion–fission hybrid – a fast route to clean and safe nuclear energy
The multiple-recycle fuel cycle for uranium-238 considered here, if practically realized, can bring revolutionary changes in nuclear energy. A full use of uranium-238 implies a practically infinite resource for power generation. Besides the energy, the fuel cycle net output is only fission products,...
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| Published in: | Journal of plasma physics 2023-09, Vol.89 (4), Article 955890401 |
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| container_title | Journal of plasma physics |
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| creator | Moiseenko, V.E. Chernitskiy, S.V. Ågren, O. Garkusha, I.E. |
| description | The multiple-recycle fuel cycle for uranium-238 considered here, if practically realized, can bring revolutionary changes in nuclear energy. A full use of uranium-238 implies a practically infinite resource for power generation. Besides the energy, the fuel cycle net output is only fission products, which are co-products rather than waste. For the same amount of energy produced, the amount of fission products is two orders of magnitude less compared with the amount of spent nuclear fuel generated in currently exploited nuclear energy production scenarios. Using the simplest isotope balance model, key features of the multiple-recycle fuel cycle for uranium-238 are investigated. The repetition of this cycle results in smooth transformation of the initial fuel to ‘stationary’ fuel without strong variations in the fractional isotope content. Deficit of delayed neutrons is a threat of the fuel cycle considered as well as other fuel cycles that use plutonium. It has a dramatic impact on reactor controllability and safety. A solution to this threat could be a subcritical nuclear reactor with an external neutron source. In this paper, use of a stellarator–mirror (SM) fusion–fission hybrid for the multiple-recycle fuel cycle for uranium-238 is analysed. A summary of the experimental and theoretical studies on the SM hybrid is given. Preliminary results for principal design of a SM hybrid nuclear reactor for the multiple-recycle fuel cycle for uranium-238 are presented. |
| doi_str_mv | 10.1017/S0022377823000442 |
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A full use of uranium-238 implies a practically infinite resource for power generation. Besides the energy, the fuel cycle net output is only fission products, which are co-products rather than waste. For the same amount of energy produced, the amount of fission products is two orders of magnitude less compared with the amount of spent nuclear fuel generated in currently exploited nuclear energy production scenarios. Using the simplest isotope balance model, key features of the multiple-recycle fuel cycle for uranium-238 are investigated. The repetition of this cycle results in smooth transformation of the initial fuel to ‘stationary’ fuel without strong variations in the fractional isotope content. Deficit of delayed neutrons is a threat of the fuel cycle considered as well as other fuel cycles that use plutonium. It has a dramatic impact on reactor controllability and safety. A solution to this threat could be a subcritical nuclear reactor with an external neutron source. In this paper, use of a stellarator–mirror (SM) fusion–fission hybrid for the multiple-recycle fuel cycle for uranium-238 is analysed. A summary of the experimental and theoretical studies on the SM hybrid is given. Preliminary results for principal design of a SM hybrid nuclear reactor for the multiple-recycle fuel cycle for uranium-238 are presented.</description><identifier>ISSN: 0022-3778</identifier><identifier>ISSN: 1469-7807</identifier><identifier>EISSN: 1469-7807</identifier><identifier>DOI: 10.1017/S0022377823000442</identifier><language>eng</language><publisher>Cambridge, UK: Cambridge University Press</publisher><subject>Burns ; Clean energy ; Fission products ; fusion plasma ; Isotopes ; Mirror fusion ; Neutrons ; Nuclear electric power generation ; Nuclear energy ; Nuclear fuels ; Nuclear reactor components ; Nuclear reactors ; Nuclear safety ; Plasma physics ; Plutonium ; Reactors ; Spent nuclear fuels ; Stellarators ; The 23rd International Stellarator-Heliotron Workshop (ISHW) ; Uranium ; Uranium 238</subject><ispartof>Journal of plasma physics, 2023-09, Vol.89 (4), Article 955890401</ispartof><rights>Copyright © The Author(s), 2023. Published by Cambridge University Press</rights><rights>Copyright © The Author(s), 2023. Published by Cambridge University Press. This work is licensed under the Creative Commons Attribution License http://creativecommons.org/licenses/by/4.0/ (the “License”). 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Plasma Phys</addtitle><description>The multiple-recycle fuel cycle for uranium-238 considered here, if practically realized, can bring revolutionary changes in nuclear energy. A full use of uranium-238 implies a practically infinite resource for power generation. Besides the energy, the fuel cycle net output is only fission products, which are co-products rather than waste. For the same amount of energy produced, the amount of fission products is two orders of magnitude less compared with the amount of spent nuclear fuel generated in currently exploited nuclear energy production scenarios. Using the simplest isotope balance model, key features of the multiple-recycle fuel cycle for uranium-238 are investigated. The repetition of this cycle results in smooth transformation of the initial fuel to ‘stationary’ fuel without strong variations in the fractional isotope content. 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Plasma Phys</addtitle><date>2023-09-04</date><risdate>2023</risdate><volume>89</volume><issue>4</issue><artnum>955890401</artnum><issn>0022-3778</issn><issn>1469-7807</issn><eissn>1469-7807</eissn><abstract>The multiple-recycle fuel cycle for uranium-238 considered here, if practically realized, can bring revolutionary changes in nuclear energy. A full use of uranium-238 implies a practically infinite resource for power generation. Besides the energy, the fuel cycle net output is only fission products, which are co-products rather than waste. For the same amount of energy produced, the amount of fission products is two orders of magnitude less compared with the amount of spent nuclear fuel generated in currently exploited nuclear energy production scenarios. Using the simplest isotope balance model, key features of the multiple-recycle fuel cycle for uranium-238 are investigated. The repetition of this cycle results in smooth transformation of the initial fuel to ‘stationary’ fuel without strong variations in the fractional isotope content. Deficit of delayed neutrons is a threat of the fuel cycle considered as well as other fuel cycles that use plutonium. It has a dramatic impact on reactor controllability and safety. A solution to this threat could be a subcritical nuclear reactor with an external neutron source. In this paper, use of a stellarator–mirror (SM) fusion–fission hybrid for the multiple-recycle fuel cycle for uranium-238 is analysed. A summary of the experimental and theoretical studies on the SM hybrid is given. 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| identifier | ISSN: 0022-3778 |
| ispartof | Journal of plasma physics, 2023-09, Vol.89 (4), Article 955890401 |
| issn | 0022-3778 1469-7807 1469-7807 |
| language | eng |
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| source | Cambridge Journals Online |
| subjects | Burns Clean energy Fission products fusion plasma Isotopes Mirror fusion Neutrons Nuclear electric power generation Nuclear energy Nuclear fuels Nuclear reactor components Nuclear reactors Nuclear safety Plasma physics Plutonium Reactors Spent nuclear fuels Stellarators The 23rd International Stellarator-Heliotron Workshop (ISHW) Uranium Uranium 238 |
| title | Stellarator–mirror fusion–fission hybrid – a fast route to clean and safe nuclear energy |
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