Verification of Spent Nuclear Fuel in Sealed Dry Storage Casks via Measurements of Cosmic-Ray Muon Scattering

J. M. Durham; D. Poulson; J. Bacon; D. L. Chichester; E. Guardincerri; C. L. Morris; K. Plaud-Ramos; W. Schwendiman; J. D. Tolman; P. Winston

doi:10.1103/PhysRevApplied.9.044013

Verification of Spent Nuclear Fuel in Sealed Dry Storage Casks via Measurements of Cosmic-Ray Muon Scattering

J. M. Durham, D. Poulson, J. Bacon, D. L. Chichester, E. Guardincerri, C. L. Morris, K. Plaud-Ramos, W. Schwendiman, J. D. Tolman, P. Winston

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

39 Scopus citations

Abstract

Most of the plutonium in the world resides inside spent nuclear reactor fuel rods. This high-level radioactive waste is commonly held in long-term storage within large, heavily shielded casks. Currently, international nuclear safeguards inspectors have no stand-alone method of verifying the amount of reactor fuel stored within a sealed cask. Here we demonstrate experimentally that measurements of the scattering angles of cosmic-ray muons, which pass through a storage cask, can be used to determine if spent fuel assemblies are missing without opening the cask. This application of technology and methods commonly used in high-energy particle physics provides a potential solution to this long-standing problem in international nuclear safeguards.

Original language	English
Article number	044013
Journal	Physical Review Applied
Volume	9
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevApplied.9.044013
State	Published - Apr 10 2018

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10.1103/PhysRevApplied.9.044013

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abstract = "Most of the plutonium in the world resides inside spent nuclear reactor fuel rods. This high-level radioactive waste is commonly held in long-term storage within large, heavily shielded casks. Currently, international nuclear safeguards inspectors have no stand-alone method of verifying the amount of reactor fuel stored within a sealed cask. Here we demonstrate experimentally that measurements of the scattering angles of cosmic-ray muons, which pass through a storage cask, can be used to determine if spent fuel assemblies are missing without opening the cask. This application of technology and methods commonly used in high-energy particle physics provides a potential solution to this long-standing problem in international nuclear safeguards.",

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AU - Guardincerri, E.

AU - Morris, C. L.

AU - Plaud-Ramos, K.

AU - Schwendiman, W.

AU - Tolman, J. D.

AU - Winston, P.

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AB - Most of the plutonium in the world resides inside spent nuclear reactor fuel rods. This high-level radioactive waste is commonly held in long-term storage within large, heavily shielded casks. Currently, international nuclear safeguards inspectors have no stand-alone method of verifying the amount of reactor fuel stored within a sealed cask. Here we demonstrate experimentally that measurements of the scattering angles of cosmic-ray muons, which pass through a storage cask, can be used to determine if spent fuel assemblies are missing without opening the cask. This application of technology and methods commonly used in high-energy particle physics provides a potential solution to this long-standing problem in international nuclear safeguards.

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Verification of Spent Nuclear Fuel in Sealed Dry Storage Casks via Measurements of Cosmic-Ray Muon Scattering

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