Utilization of spent nuclear fuel and transuranic actinides in a two-component nuclear power industry

According to the strategy for the development of the nuclear power industry in Russia for the first half of the 21st century, the nuclear power industry complex should undergo the initial stage in the formation of a two-component nuclear power system and a closed nuclear fuel cycle (NFC) infrastruct...

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Bibliographic Details
Published in:Atomic energy (New York, N.Y.) N.Y.), 2023-05, Vol.134 (1-2), p.63-72
Main Authors: Adamov, E. O., Kashirsky, A. A., Rachkov, V. I., Rodina, E. A., Khomyakov, Yu. S.
Format: Article
Language:English
Subjects:
Actinides
Development strategies
Electric industries
Electric power systems
Electric utilities
Fabrication
Fast nuclear reactors
Hadrons
Heavy Ions
Natural resources
Nuclear Chemistry
Nuclear Energy
Nuclear fuel cycle
Nuclear fuels
Nuclear industry
Nuclear Physics
Nuclear reactors
Physics
Physics and Astronomy
Plutonium
Radioactive pollution
Radioactive waste disposal
Radioactive wastes
Reactors
Spent nuclear fuels
Uranium
Waste management
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Summary:According to the strategy for the development of the nuclear power industry in Russia for the first half of the 21st century, the nuclear power industry complex should undergo the initial stage in the formation of a two-component nuclear power system and a closed nuclear fuel cycle (NFC) infrastructure. All elements of such a nuclear power system, including NPPs, facilities for the fabrication of uranium and uranium-plutonium fuel, processing of spent nuclear fuel, and radioactive waste management, must be organically linked for producing competitive electricity in both domestic and foreign markets. The present article demonstrates the systemic benefits from a large-scale introduction of fast reactors for the Russian nuclear power industry in terms of a sustainable resource provision and a solution to the key problems of the final NFC stage, which is associated with the accumulation of spent fuel and transuranic actinides. The study proposes an optimum NFC closure scenario, in which the described problems can be solved without increasing the high parameters of the BR in a fast reactor and using special burners.
ISSN:1063-4258
1573-8205
DOI:10.1007/s10512-023-01028-w