Detection of Fuel Release in a Nuclear Accident: A Method for Preconcentration and Isolation of Reactor-Borne 239Np Using Ion-Specific Extraction Chromatography

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Authors

  • Brett L. Rosenberg
  • Katsumi Shozugawa
  • Georg Steinhauser

Research Organisations

External Research Organisations

  • Colorado State University
  • University of Tokyo
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Details

Original languageEnglish
Pages (from-to)8651-8656
Number of pages6
JournalAnalytical chemistry
Volume87
Issue number17
Early online date14 Aug 2015
Publication statusPublished - 1 Sept 2015

Abstract

Although actinides are the most informative elements with respect to the nature of a nuclear accident, plutonium analysis is complicated by the background created by fallout from atmospheric nuclear explosions. Therefore, we propose 239Np, a short-lived actinide that emits several γ rays, as a preferred proxy. The aim of this study was to screen ion specific extraction chromatography resins (RE-, TEVA-, UTEVA-, TRU-, and Actinide-Resin) for the highest possible recovery and separation of trace amounts of 239Np from samples with large activities of fission products such as radiocesium, radioiodine, and, most importantly, radiotellurium, the latter of which causes spectral interference in gamma spectrometry through overlapping peaks with 239Np. The investigated environmental media for these separations were aqueous solutions simulating rainwater and soil. Spiked samples containing 239Np and the aforementioned volatile radionuclides were separated through extraction chromatographic columns to ascertain the most effective means of separating 239Np from other fission products for detection by gamma spectroscopy. We propose a method for nuclear accident preparedness based on the use of Eichrom's RE-Resin. The proposed method was found most effective for isolating 239Np from interfering radionuclides in both aqueous solution and soil using 8 M HNO3 as the loading solution and H2O as the eluent. The RE-Resin outperforms the more commonly used TEVA-Resin because the TEVA-Resin showed a higher affinity for interfering radiotellurium and radioiodine. (Figure Presented).

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Detection of Fuel Release in a Nuclear Accident: A Method for Preconcentration and Isolation of Reactor-Borne 239Np Using Ion-Specific Extraction Chromatography. / Rosenberg, Brett L.; Shozugawa, Katsumi; Steinhauser, Georg.
In: Analytical chemistry, Vol. 87, No. 17, 01.09.2015, p. 8651-8656.

Research output: Contribution to journalArticleResearchpeer review

Rosenberg BL, Shozugawa K, Steinhauser G. Detection of Fuel Release in a Nuclear Accident: A Method for Preconcentration and Isolation of Reactor-Borne 239Np Using Ion-Specific Extraction Chromatography. Analytical chemistry. 2015 Sept 1;87(17):8651-8656. Epub 2015 Aug 14. doi: 10.1021/acs.analchem.5b02265
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title = "Detection of Fuel Release in a Nuclear Accident: A Method for Preconcentration and Isolation of Reactor-Borne 239Np Using Ion-Specific Extraction Chromatography",
abstract = "Although actinides are the most informative elements with respect to the nature of a nuclear accident, plutonium analysis is complicated by the background created by fallout from atmospheric nuclear explosions. Therefore, we propose 239Np, a short-lived actinide that emits several γ rays, as a preferred proxy. The aim of this study was to screen ion specific extraction chromatography resins (RE-, TEVA-, UTEVA-, TRU-, and Actinide-Resin) for the highest possible recovery and separation of trace amounts of 239Np from samples with large activities of fission products such as radiocesium, radioiodine, and, most importantly, radiotellurium, the latter of which causes spectral interference in gamma spectrometry through overlapping peaks with 239Np. The investigated environmental media for these separations were aqueous solutions simulating rainwater and soil. Spiked samples containing 239Np and the aforementioned volatile radionuclides were separated through extraction chromatographic columns to ascertain the most effective means of separating 239Np from other fission products for detection by gamma spectroscopy. We propose a method for nuclear accident preparedness based on the use of Eichrom's RE-Resin. The proposed method was found most effective for isolating 239Np from interfering radionuclides in both aqueous solution and soil using 8 M HNO3 as the loading solution and H2O as the eluent. The RE-Resin outperforms the more commonly used TEVA-Resin because the TEVA-Resin showed a higher affinity for interfering radiotellurium and radioiodine. (Figure Presented).",
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T1 - Detection of Fuel Release in a Nuclear Accident

T2 - A Method for Preconcentration and Isolation of Reactor-Borne 239Np Using Ion-Specific Extraction Chromatography

AU - Rosenberg, Brett L.

AU - Shozugawa, Katsumi

AU - Steinhauser, Georg

N1 - This study was supported by Grant Number T42OH009229-07 from the CDC NIOSH Mountain and Plains Education and Research Center. Its contents are solely the responsibility of the authors and do not necessarily represent the official views of the CDC NIOSH and MAP ERC. The authors also gratefully acknowledges funding by the U.S. Nuclear Regulatory Commission (NRC), Grant Number NRC-HQ-12-G-38- 0044. We thank James Self from the CSU Soil Testing Lab for the analysis of the deionized water.

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N2 - Although actinides are the most informative elements with respect to the nature of a nuclear accident, plutonium analysis is complicated by the background created by fallout from atmospheric nuclear explosions. Therefore, we propose 239Np, a short-lived actinide that emits several γ rays, as a preferred proxy. The aim of this study was to screen ion specific extraction chromatography resins (RE-, TEVA-, UTEVA-, TRU-, and Actinide-Resin) for the highest possible recovery and separation of trace amounts of 239Np from samples with large activities of fission products such as radiocesium, radioiodine, and, most importantly, radiotellurium, the latter of which causes spectral interference in gamma spectrometry through overlapping peaks with 239Np. The investigated environmental media for these separations were aqueous solutions simulating rainwater and soil. Spiked samples containing 239Np and the aforementioned volatile radionuclides were separated through extraction chromatographic columns to ascertain the most effective means of separating 239Np from other fission products for detection by gamma spectroscopy. We propose a method for nuclear accident preparedness based on the use of Eichrom's RE-Resin. The proposed method was found most effective for isolating 239Np from interfering radionuclides in both aqueous solution and soil using 8 M HNO3 as the loading solution and H2O as the eluent. The RE-Resin outperforms the more commonly used TEVA-Resin because the TEVA-Resin showed a higher affinity for interfering radiotellurium and radioiodine. (Figure Presented).

AB - Although actinides are the most informative elements with respect to the nature of a nuclear accident, plutonium analysis is complicated by the background created by fallout from atmospheric nuclear explosions. Therefore, we propose 239Np, a short-lived actinide that emits several γ rays, as a preferred proxy. The aim of this study was to screen ion specific extraction chromatography resins (RE-, TEVA-, UTEVA-, TRU-, and Actinide-Resin) for the highest possible recovery and separation of trace amounts of 239Np from samples with large activities of fission products such as radiocesium, radioiodine, and, most importantly, radiotellurium, the latter of which causes spectral interference in gamma spectrometry through overlapping peaks with 239Np. The investigated environmental media for these separations were aqueous solutions simulating rainwater and soil. Spiked samples containing 239Np and the aforementioned volatile radionuclides were separated through extraction chromatographic columns to ascertain the most effective means of separating 239Np from other fission products for detection by gamma spectroscopy. We propose a method for nuclear accident preparedness based on the use of Eichrom's RE-Resin. The proposed method was found most effective for isolating 239Np from interfering radionuclides in both aqueous solution and soil using 8 M HNO3 as the loading solution and H2O as the eluent. The RE-Resin outperforms the more commonly used TEVA-Resin because the TEVA-Resin showed a higher affinity for interfering radiotellurium and radioiodine. (Figure Presented).

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