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{{Short description|Type of nuclear fuel}}
'''Remix Fuel ''' was developed in Russia to make use of Mixed Recycled Uranium and Plutonium from spent nuclear fuel to manufacture fresh fuel suitable for widespread use in Russian reactor designs.<ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/TVEL-outlines-innovation-in-nuclear-fuel|title=TVEL outlines innovation in nuclear fuel : Uranium & Fuel - World Nuclear News|website=www.world-nuclear-news.org}}</ref>
'''REMIX-Fuel '''(REgenerated MIXture of U, Pu oxides) was developed in Russia to simplify the reprocessing process, reuse spent fuel, reduce the consumption of natural uranium and to enable multi-recycling. <ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/TVEL-outlines-innovation-in-nuclear-fuel|title=TVEL outlines innovation in nuclear fuel : Uranium & Fuel - World Nuclear News|website=www.world-nuclear-news.org}}</ref><ref name=":0" /><ref name=":1" />

== Compared to "conventional" MOX-fuel==
== Compared to "conventional" MOX-fuel==
MOX or [[Mixed Oxide Fuel]]<ref>{{Cite web|url=https://www.world-nuclear.org/information-library/nuclear-fuel-cycle/fuel-recycling/mixed-oxide-fuel-mox.aspx|title=MOX, Mixed Oxide Fuel - World Nuclear Association|website=www.world-nuclear.org}}</ref> as deployed in the western European and East Asian nations generally consists of [[depleted Uranium]] mixed with between 4% and 7% Reactor Grade Plutonium. Only a few Generation II and about half of Generation III reactor designs are MOX fuel compliant allowing them to use a 100% MOX fuel load with no safety concerns.
MOX or [[Mixed Oxide Fuel]]<ref>{{Cite web|url=https://www.world-nuclear.org/information-library/nuclear-fuel-cycle/fuel-recycling/mixed-oxide-fuel-mox.aspx|title=MOX, Mixed Oxide Fuel - World Nuclear Association|website=www.world-nuclear.org}}</ref> as deployed in some western European and East Asian nations generally consists of [[depleted uranium]] mixed with between 4% and 7% [[reactor grade plutonium]]. Only a few Generation II and about half of Generation III reactor designs are MOX fuel compliant allowing them to use a 100% MOX fuel load with no safety concerns.
=== Nuclear physics background===
=== Nuclear physics background===
However all water cooled water moderated reactors using lightly enriched Uranium fuel produce Plutonium in the course of normal operation as [[Uranium-238]] (over 90% of the uranium content in lightly enriched uranium) captures neutrons and undergoes successive beta decays until it is [[nuclear transmutation|transmuted]] to [[plutonium-239]]. This internally produced Plutonium increases in percentage until it is common enough that a growing percentage of Fission reactions within the fuel are actually within the Plutonium generated during the fuel cycle. Approximately half of the [[Plutonium-239]] "bred" during the fuel cycle is fissioned and another 25% is transmuted through additional neutron capture into other Plutonium isotopes, primarily [[Pu-240]]. Virtually all of the [[minor actinides]] present in [[spent nuclear fuel]] are produced by successive neutron capture of the Plutonium produced and as decay products of the more short lived isotopes. As a consequence of these factors the fresh Uranium Oxide fuel initially generates all of its fission reactions from U-235 but at the end of the cycle this has shifted to 50% U-235/50% Pu-239 fission reactions. In total about 33% of the energy generated by Uranium fuel at the end of its life cycle actually comes from the bred and consumed Pu-239. Because the thermal neutron spectrum is not very good for fissioning Pu-239 the fuel shifts from 100% Uranium at start of cycle to 96% Uranium, 1% Plutonium and 3% mixture of transuranic [[minor actinides]] and [[fission product]]s. The longer the fuel remains in the reactor undergoing fission the more the Uranium percentage decreases while the other materials increase. In effect all power reactors have been long known to be capable of operating with a mixed fissionable core containing 1% reactor grade Plutonium without issues arising like those caused by the more highly concentrated MOX fuel used in western reactors. <ref>{{Cite web|url=https://www.world-nuclear.org/information-library/nuclear-fuel-cycle/conversion-enrichment-and-fabrication/fuel-fabrication.aspx#ECSArticleLink5|title=Nuclear Fuel Fabrication - World Nuclear Association|website=www.world-nuclear.org}}</ref> <ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/REMIX-fuel-pilot-testing-starts-at-Balakovo-reacto|title=REMIX fuel pilot testing starts at Balakovo reactor - World Nuclear News|website=www.world-nuclear-news.org}}</ref>
However all moderated reactors using lightly enriched uranium fuel produce plutonium in the course of normal operation as [[Uranium-238]] (typically 94% to 97% of the uranium content in lightly enriched uranium<ref>{{cite web | url=https://www.energy.gov/ne/nuclear-fuel-facts-uranium | title=Nuclear Fuel Facts: Uranium }}</ref>) captures neutrons and undergoes successive beta decays until it is [[nuclear transmutation|transmuted]] to [[plutonium-239]]. This internally produced plutonium increases in percentage until it is common enough that a growing percentage of fission reactions within the fuel are actually within the plutonium generated during the fuel cycle. Approximately half of the [[plutonium-239]] "bred" during the fuel cycle is fissioned and another 25% is transmuted through additional neutron capture into other plutonium isotopes, primarily [[Pu-240]]. Virtually all of the [[minor actinides]] present in [[spent nuclear fuel]] are produced by successive neutron capture of the plutonium produced and as decay products of the more short lived isotopes. As a consequence of these factors the fresh uranium oxide fuel initially generates all of its fission reactions from U-235 but at the end of the cycle this has shifted to 50% U-235/50% Pu-239 fission reactions. In total about 33% of the energy generated by uranium fuel at the end of its life cycle actually comes from the bred and consumed Pu-239. Because the thermal neutron spectrum is not very good for fissioning Pu-239 the fuel shifts from 100% uranium at start of cycle to 96% uranium, 1% plutonium and 3% mixture of transuranic [[minor actinides]] and [[fission product]]s. The longer the fuel remains in the reactor undergoing fission the more the uranium percentage decreases while the other materials increase. In effect all power reactors have been long known to be capable of operating with a mixed fissionable core containing 1% reactor grade plutonium without issues arising like those caused by the more highly concentrated MOX fuel used in western reactors. <ref>{{Cite web|url=https://www.world-nuclear.org/information-library/nuclear-fuel-cycle/conversion-enrichment-and-fabrication/fuel-fabrication.aspx#ECSArticleLink5|title=Nuclear Fuel Fabrication - World Nuclear Association|website=www.world-nuclear.org}}</ref> <ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/REMIX-fuel-pilot-testing-starts-at-Balakovo-reacto|title=REMIX fuel pilot testing starts at Balakovo reactor - World Nuclear News|website=www.world-nuclear-news.org}}</ref> Ultimately, the spent fuel is removed from power reactors long before all available "fuel" is actually consumed, as [[neutron poison]]s and minor actinides with undesirable properties build up to unacceptable levels and alter the reaction parameters too much. [[Nuclear reprocessing]] is primarily done to remove undesirable parts of the spent fuel and either re-use the other parts or store them as waste. [[Reprocessed uranium]] for example, which is derived from spent fuel, usually has a higher [[uranium-235]] content than [[natural uranium]].


== Process==
== Process==
Russia spent nearly a decade developing techniques similar to Nuclear [[Pyroprocessing]] that allows them to reprocess spent nuclear fuel without separating the recycled Uranium and Plutonium from the other metals as is done in the [[PUREX]] chemical reprocessing system used to manufacture MOX fuel. The Recovered Mixture of Uranium and Reactor Grade Plutonium is then converted to Oxide and blended with medium enriched fresh Uranium Oxide fuel in a carefully measured proportion to create a mixture with 4% U-235 and 1% Reactor Grade Plutonium. After extensive testing in a reactor starting in 2016 <ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/Russia-loads-REMIX-fuel-into-MIR-research-reactor|title=Russia loads REMIX fuel into MIR research reactor - World Nuclear News|website=www.world-nuclear-news.org}}</ref> Russia is now deploying Remix Fuel as replacement fuel for their [[VVER]] Pressurized Water Reactors as of February 2020.
Russia spent nearly a decade developing techniques similar to nuclear [[pyroprocessing]] that allows them to reprocess spent nuclear fuel without separating the recycled uranium and plutonium as is done in the [[PUREX]] chemical reprocessing system used to manufacture MOX fuel.<ref>{{Cite web |last=Simpson |first=Michael |last2=Law |first2=Jack |date=2024-10-20 |title=Nuclear Fuel Reprocessing |url=https://inldigitallibrary.inl.gov/sites/sti/sti/4460757.pdf |website=INL Research Library Digital Repository}}</ref><ref>{{Cite web |title=Rosatom has launched facility for REMIX-fuel fabrication |url=https://rosatom-asia.com/press-centre/news/rosatom-has-launched-facility-for-remix-fuel-fabrication-/ |url-status=live |archive-url=https://archive.today/20241019183134/https://rosatom-asia.com/press-centre/news/rosatom-has-launched-facility-for-remix-fuel-fabrication-/ |archive-date=2024-10-19 |access-date=2024-10-19 |website=rosatom-asia.com}}</ref> Small volumes of enriched uranium are added to this recovered mixture of non-separated uranium and plutonium so that it performs similarly to the fuel made only from freshly enriched uranium.<ref>{{Cite web |date=2021-11-11 |title=REMIX fuel ready for final test |url=https://www.world-nuclear-news.org/Articles/REMIX-fuel-ready-for-final-test |url-status=live |archive-url=https://archive.today/20211113091327/https://www.world-nuclear-news.org/Articles/REMIX-fuel-ready-for-final-test |archive-date=2021-11-13 |access-date=2024-10-19 |website=World Nuclear News |language=en}}</ref><ref name=":1">{{Cite web |last=Thonney |date=2021-06-08 |title=Russia begins pilot production of Remix fuel assemblies |url=https://www.neimagazine.com/news/russia-begins-pilot-production-of-remix-fuel-assemblies-8803273/ |url-status=live |archive-url=https://archive.today/20241019190628/https://www.neimagazine.com/news/russia-begins-pilot-production-of-remix-fuel-assemblies-8803273/?cf-view |archive-date=2024-10-19 |access-date=2024-10-19 |website=Nuclear Engineering International |language=en-US}}</ref><ref name=":0">{{Cite journal |date=2016-10-28 |title=Physical and economical aspects of Pu multiple recycling on the basis of REMIX reprocessing technology in thermal reactors |url=https://doi.org/10.1051/epjn/2016034 |journal=EPJ Nuclear Sciences & Technologies |volume=2 |pages=41 |via=EPJ Nuclear Sciences & Technologies}}</ref> After extensive testing in a reactor starting in 2016 <ref>{{Cite web|url=https://www.world-nuclear-news.org/Articles/Russia-loads-REMIX-fuel-into-MIR-research-reactor|title=Russia loads REMIX fuel into MIR research reactor - World Nuclear News|website=www.world-nuclear-news.org}}</ref> Russia is now deploying Remix Fuel as replacement fuel for their [[VVER]] pressurized water reactors as of February 2020.


==References==
==References==
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[[Category:Fuels]]
[[Category:Fuels]]
[[Category:Fuel production]]
[[Category:Fuel production]]
[[Category:Nuclear reprocessing]]

Latest revision as of 13:27, 15 November 2024

REMIX-Fuel (REgenerated MIXture of U, Pu oxides) was developed in Russia to simplify the reprocessing process, reuse spent fuel, reduce the consumption of natural uranium and to enable multi-recycling. [1][2][3]

Compared to "conventional" MOX-fuel

[edit]

MOX or Mixed Oxide Fuel[4] as deployed in some western European and East Asian nations generally consists of depleted uranium mixed with between 4% and 7% reactor grade plutonium. Only a few Generation II and about half of Generation III reactor designs are MOX fuel compliant allowing them to use a 100% MOX fuel load with no safety concerns.

Nuclear physics background

[edit]

However all moderated reactors using lightly enriched uranium fuel produce plutonium in the course of normal operation as Uranium-238 (typically 94% to 97% of the uranium content in lightly enriched uranium[5]) captures neutrons and undergoes successive beta decays until it is transmuted to plutonium-239. This internally produced plutonium increases in percentage until it is common enough that a growing percentage of fission reactions within the fuel are actually within the plutonium generated during the fuel cycle. Approximately half of the plutonium-239 "bred" during the fuel cycle is fissioned and another 25% is transmuted through additional neutron capture into other plutonium isotopes, primarily Pu-240. Virtually all of the minor actinides present in spent nuclear fuel are produced by successive neutron capture of the plutonium produced and as decay products of the more short lived isotopes. As a consequence of these factors the fresh uranium oxide fuel initially generates all of its fission reactions from U-235 but at the end of the cycle this has shifted to 50% U-235/50% Pu-239 fission reactions. In total about 33% of the energy generated by uranium fuel at the end of its life cycle actually comes from the bred and consumed Pu-239. Because the thermal neutron spectrum is not very good for fissioning Pu-239 the fuel shifts from 100% uranium at start of cycle to 96% uranium, 1% plutonium and 3% mixture of transuranic minor actinides and fission products. The longer the fuel remains in the reactor undergoing fission the more the uranium percentage decreases while the other materials increase. In effect all power reactors have been long known to be capable of operating with a mixed fissionable core containing 1% reactor grade plutonium without issues arising like those caused by the more highly concentrated MOX fuel used in western reactors. [6] [7] Ultimately, the spent fuel is removed from power reactors long before all available "fuel" is actually consumed, as neutron poisons and minor actinides with undesirable properties build up to unacceptable levels and alter the reaction parameters too much. Nuclear reprocessing is primarily done to remove undesirable parts of the spent fuel and either re-use the other parts or store them as waste. Reprocessed uranium for example, which is derived from spent fuel, usually has a higher uranium-235 content than natural uranium.

Process

[edit]

Russia spent nearly a decade developing techniques similar to nuclear pyroprocessing that allows them to reprocess spent nuclear fuel without separating the recycled uranium and plutonium as is done in the PUREX chemical reprocessing system used to manufacture MOX fuel.[8][9] Small volumes of enriched uranium are added to this recovered mixture of non-separated uranium and plutonium so that it performs similarly to the fuel made only from freshly enriched uranium.[10][3][2] After extensive testing in a reactor starting in 2016 [11] Russia is now deploying Remix Fuel as replacement fuel for their VVER pressurized water reactors as of February 2020.

References

[edit]
  1. ^ "TVEL outlines innovation in nuclear fuel : Uranium & Fuel - World Nuclear News". www.world-nuclear-news.org.
  2. ^ a b "Physical and economical aspects of Pu multiple recycling on the basis of REMIX reprocessing technology in thermal reactors". EPJ Nuclear Sciences & Technologies. 2: 41. 2016-10-28 – via EPJ Nuclear Sciences & Technologies.
  3. ^ a b Thonney (2021-06-08). "Russia begins pilot production of Remix fuel assemblies". Nuclear Engineering International. Archived from the original on 2024-10-19. Retrieved 2024-10-19.
  4. ^ "MOX, Mixed Oxide Fuel - World Nuclear Association". www.world-nuclear.org.
  5. ^ "Nuclear Fuel Facts: Uranium".
  6. ^ "Nuclear Fuel Fabrication - World Nuclear Association". www.world-nuclear.org.
  7. ^ "REMIX fuel pilot testing starts at Balakovo reactor - World Nuclear News". www.world-nuclear-news.org.
  8. ^ Simpson, Michael; Law, Jack (2024-10-20). "Nuclear Fuel Reprocessing" (PDF). INL Research Library Digital Repository.
  9. ^ "Rosatom has launched facility for REMIX-fuel fabrication". rosatom-asia.com. Archived from the original on 2024-10-19. Retrieved 2024-10-19.
  10. ^ "REMIX fuel ready for final test". World Nuclear News. 2021-11-11. Archived from the original on 2021-11-13. Retrieved 2024-10-19.
  11. ^ "Russia loads REMIX fuel into MIR research reactor - World Nuclear News". www.world-nuclear-news.org.
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