Estimating Potential Tritium and Plutonium Production in North Korea’s Experimental Light Water Reactor

Patrick J. Park; Alexander Glaser

doi:10.1080/08929882.2024.2444751

Estimating Potential Tritium and Plutonium Production in North Korea’s Experimental Light Water Reactor

Research output: Contribution to journal › Article › peer-review

Abstract

Our work explores North Korea’s 100 MW-th Experimental Light Water Reactor (ELWR) and its potential contributions to the country’s nuclear weapons program. Built at the Yongbyon Nuclear Research Center, the ELWR began operations in October 2023 and represents North Korea’s first attempts at a light-water reactor using domestically-enriched fuel. Our study examines possible configurations for energy generation, tritium production, and tritium-plutonium co-production. Assuming a single-batch core, the ELWR can be used to annually produce 48–82 grams of tritium, which can supply 2–4 new boosted warheads each year, up to a maximum arsenal of 88–150 warheads total. Concurrent production of tritium and weapon-grade plutonium is also possible but requires reprocessing of spent ceramic fuel. Overall, the findings underscore how North Korea’s nuclear capabilities may be advanced through the ELWR’s dual-use potential.

Original language	English (US)
Pages (from-to)	68-82
Number of pages	15
Journal	Science and Global Security
Volume	32
Issue number	1-3
DOIs	https://doi.org/10.1080/08929882.2024.2444751
State	Published - 2024

All Science Journal Classification (ASJC) codes

General Engineering

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10.1080/08929882.2024.2444751

Cite this

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title = "Estimating Potential Tritium and Plutonium Production in North Korea{\textquoteright}s Experimental Light Water Reactor",

abstract = "Our work explores North Korea{\textquoteright}s 100 MW-th Experimental Light Water Reactor (ELWR) and its potential contributions to the country{\textquoteright}s nuclear weapons program. Built at the Yongbyon Nuclear Research Center, the ELWR began operations in October 2023 and represents North Korea{\textquoteright}s first attempts at a light-water reactor using domestically-enriched fuel. Our study examines possible configurations for energy generation, tritium production, and tritium-plutonium co-production. Assuming a single-batch core, the ELWR can be used to annually produce 48–82 grams of tritium, which can supply 2–4 new boosted warheads each year, up to a maximum arsenal of 88–150 warheads total. Concurrent production of tritium and weapon-grade plutonium is also possible but requires reprocessing of spent ceramic fuel. Overall, the findings underscore how North Korea{\textquoteright}s nuclear capabilities may be advanced through the ELWR{\textquoteright}s dual-use potential.",

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year = "2024",

doi = "10.1080/08929882.2024.2444751",

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AU - Park, Patrick J.

AU - Glaser, Alexander

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N2 - Our work explores North Korea’s 100 MW-th Experimental Light Water Reactor (ELWR) and its potential contributions to the country’s nuclear weapons program. Built at the Yongbyon Nuclear Research Center, the ELWR began operations in October 2023 and represents North Korea’s first attempts at a light-water reactor using domestically-enriched fuel. Our study examines possible configurations for energy generation, tritium production, and tritium-plutonium co-production. Assuming a single-batch core, the ELWR can be used to annually produce 48–82 grams of tritium, which can supply 2–4 new boosted warheads each year, up to a maximum arsenal of 88–150 warheads total. Concurrent production of tritium and weapon-grade plutonium is also possible but requires reprocessing of spent ceramic fuel. Overall, the findings underscore how North Korea’s nuclear capabilities may be advanced through the ELWR’s dual-use potential.

AB - Our work explores North Korea’s 100 MW-th Experimental Light Water Reactor (ELWR) and its potential contributions to the country’s nuclear weapons program. Built at the Yongbyon Nuclear Research Center, the ELWR began operations in October 2023 and represents North Korea’s first attempts at a light-water reactor using domestically-enriched fuel. Our study examines possible configurations for energy generation, tritium production, and tritium-plutonium co-production. Assuming a single-batch core, the ELWR can be used to annually produce 48–82 grams of tritium, which can supply 2–4 new boosted warheads each year, up to a maximum arsenal of 88–150 warheads total. Concurrent production of tritium and weapon-grade plutonium is also possible but requires reprocessing of spent ceramic fuel. Overall, the findings underscore how North Korea’s nuclear capabilities may be advanced through the ELWR’s dual-use potential.

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Estimating Potential Tritium and Plutonium Production in North Korea’s Experimental Light Water Reactor

Abstract

All Science Journal Classification (ASJC) codes

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