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Main Authors: Kim, G. B., Kavner, A. R. L., Parsons-Davis, T., Friedrich, S., Drury, O. B., Lee, D., Zhang, X., Hines, N., Boyd, S. T. P., Weidenbenner, S., Schreiber, K., Martinson, S., Smith, C., McNeel, D., Salazar, S., Koehler, K., Carpenter, M., Croce, M., Schmidt, D., Ullom, J.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.05200
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author Kim, G. B.
Kavner, A. R. L.
Parsons-Davis, T.
Friedrich, S.
Drury, O. B.
Lee, D.
Zhang, X.
Hines, N.
Boyd, S. T. P.
Weidenbenner, S.
Schreiber, K.
Martinson, S.
Smith, C.
McNeel, D.
Salazar, S.
Koehler, K.
Carpenter, M.
Croce, M.
Schmidt, D.
Ullom, J.
author_facet Kim, G. B.
Kavner, A. R. L.
Parsons-Davis, T.
Friedrich, S.
Drury, O. B.
Lee, D.
Zhang, X.
Hines, N.
Boyd, S. T. P.
Weidenbenner, S.
Schreiber, K.
Martinson, S.
Smith, C.
McNeel, D.
Salazar, S.
Koehler, K.
Carpenter, M.
Croce, M.
Schmidt, D.
Ullom, J.
contents Decay energy spectrometry (DES) is a novel radiometric technique for high-precision analysis of nuclear materials. DES employs the unique thermal detection physics of cryogenic microcalorimeters with ultra-high energy resolution and 100$\%$ detection efficiency to accomplish high precision decay energy measurements. Low-activity nuclear samples of 1 Bq or less, and without chemical separation, are used to provide elemental and isotopic compositions in a single measurement. Isotopic ratio precisions of 1 ppm - 1,000 ppm (isotope dependent), which is close to that of the mass spectrometry, have been demonstrated in 12-hour DES measurements of ~5 Bq samples of certified reference materials of uranium (U) and plutonium (Pu). DES has very different systematic biases and uncertainties, as well as different sensitivities to nuclides, compared to mass-spectrometry techniques. Therefore, the accuracy and confidence of nuclear material assays can be improved by combining this new technique with existing mass-spectrometry techniques. Commercial-level DES techniques and equipment are being developed for the implementation of DES at the Nuclear Material Laboratory (NML) of International Atomic Energy Agency (IAEA) to provide complementary measurements to the existing technologies. The paper describes details of DES measurement methods, as well as DES precision and accuracy to U and Pu standard sources to discuss its capability in analysis of nuclear safeguards samples.
format Preprint
id arxiv_https___arxiv_org_abs_2406_05200
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Decay Energy Spectrometry for Improved Nuclear Material Analysis at the IAEA NML
Kim, G. B.
Kavner, A. R. L.
Parsons-Davis, T.
Friedrich, S.
Drury, O. B.
Lee, D.
Zhang, X.
Hines, N.
Boyd, S. T. P.
Weidenbenner, S.
Schreiber, K.
Martinson, S.
Smith, C.
McNeel, D.
Salazar, S.
Koehler, K.
Carpenter, M.
Croce, M.
Schmidt, D.
Ullom, J.
Instrumentation and Detectors
Nuclear Experiment
Decay energy spectrometry (DES) is a novel radiometric technique for high-precision analysis of nuclear materials. DES employs the unique thermal detection physics of cryogenic microcalorimeters with ultra-high energy resolution and 100$\%$ detection efficiency to accomplish high precision decay energy measurements. Low-activity nuclear samples of 1 Bq or less, and without chemical separation, are used to provide elemental and isotopic compositions in a single measurement. Isotopic ratio precisions of 1 ppm - 1,000 ppm (isotope dependent), which is close to that of the mass spectrometry, have been demonstrated in 12-hour DES measurements of ~5 Bq samples of certified reference materials of uranium (U) and plutonium (Pu). DES has very different systematic biases and uncertainties, as well as different sensitivities to nuclides, compared to mass-spectrometry techniques. Therefore, the accuracy and confidence of nuclear material assays can be improved by combining this new technique with existing mass-spectrometry techniques. Commercial-level DES techniques and equipment are being developed for the implementation of DES at the Nuclear Material Laboratory (NML) of International Atomic Energy Agency (IAEA) to provide complementary measurements to the existing technologies. The paper describes details of DES measurement methods, as well as DES precision and accuracy to U and Pu standard sources to discuss its capability in analysis of nuclear safeguards samples.
title Decay Energy Spectrometry for Improved Nuclear Material Analysis at the IAEA NML
topic Instrumentation and Detectors
Nuclear Experiment
url https://arxiv.org/abs/2406.05200