Harold L Beck1, André Bouville2, Steven L Simon3, Lynn R Anspaugh4, Kathleen M Thiessen5, Sergey Shinkarev6, Konstantin Gordeev7. 1. US Department of Energy (retired), New York, NY. 2. National Cancer Institute (retired), Bethesda, MD. 3. National Cancer Institute, Bethesda, MD. 4. Department of Radiology, University of Utah (Emeritus), Henderson, NV. 5. Oak Ridge Center for Risk Analysis, Inc., Oak Ridge, TN. 6. State Research Center-Burnasyan Federal Medical Biophysical Center, Federal Medical Biological Agency, Moscow, Russian Federation. 7. State Research Center-Institute of Biophysics of the Ministry of Health, Moscow, Russian Federation (deceased).
Abstract
ABSTRACT: This paper describes a relatively simple model developed from observations of local fallout from US and USSR nuclear tests that allows reasonable estimates to be made of the deposition density (activity per unit area) on both the ground and on vegetation for each radionuclide of interest produced in a nuclear fission detonation as a function of location and time after the explosion. In addition to accounting for decay rate and in-growth of radionuclides, the model accounts for the fractionation (modification of the relative activity of various fission and activation products in fallout relative to that produced in the explosion) that results from differences in the condensation temperatures of the various fission and activation products produced in the explosion. The proposed methodology can be used to estimate the deposition density of all fallout radionuclides produced in a low yield, low altitude fission detonation that contribute significantly to dose. The method requires only data from post-detonation measurements of exposure rate (or beta or a specific nuclide activity) and fallout time-of-arrival. These deposition-density estimates allow retrospective as well as rapid prospective estimates to be made of both external and internal radiation exposure to downwind populations living within a few hundred kilometers of ground zero, as described in the companion papers in this volume.
ABSTRACT: This paper describes a relatively simple model developed from observations of local fallout from US and USSR nuclear tests that allows reasonable estimates to be made of the deposition density (activity per unit area) on both the ground and on vegetation for each radionuclide of interest produced in a nuclear fission detonation as a function of location and time after the explosion. In addition to accounting for decay rate and in-growth of radionuclides, the model accounts for the fractionation (modification of the relative activity of various fission and activation products in fallout relative to that produced in the explosion) that results from differences in the condensation temperatures of the various fission and activation products produced in the explosion. The proposed methodology can be used to estimate the deposition density of all fallout radionuclides produced in a low yield, low altitude fission detonation that contribute significantly to dose. The method requires only data from post-detonation measurements of exposure rate (or beta or a specific nuclide activity) and fallout time-of-arrival. These deposition-density estimates allow retrospective as well as rapid prospective estimates to be made of both external and internal radiation exposure to downwind populations living within a few hundred kilometers of ground zero, as described in the companion papers in this volume.
Authors: Konstantin Gordeev; Sergey Shinkarev; Leonid Ilyin; André Bouville; Masaharu Hoshi; Nickolas Luckyanov; Steven L Simon Journal: J Radiat Res Date: 2006-02 Impact factor: 2.724
Authors: Steven L Simon; Harold L Beck; Konstantin Gordeev; André Bouville; Lynn R Anspaugh; Charles E Land; Nicholas Luckyanov; Sergey Shinkarev Journal: J Radiat Res Date: 2006-02 Impact factor: 2.724
Authors: André Bouville; Harold L Beck; Kathleen M Thiessen; F Owen Hoffman; Nancy Potischman; Steven L Simon Journal: Health Phys Date: 2020-10 Impact factor: 1.316
Authors: Dunstana R Melo; Luiz Bertelli; Shawki A Ibrahim; Lynn R Anspaugh; André Bouville; Steven L Simon Journal: Health Phys Date: 2022-01-01 Impact factor: 1.316
Authors: Kathleen M Thiessen; F Owen Hoffman; André Bouville; Lynn R Anspaugh; Harold L Beck; Steven L Simon Journal: Health Phys Date: 2022-01-01 Impact factor: 1.316
Authors: André Bouville; Harold L Beck; Lynn R Anspaugh; Konstantin Gordeev; Sergey Shinkarev; Kathleen M Thiessen; F Owen Hoffman; Steven L Simon Journal: Health Phys Date: 2022-01-01 Impact factor: 1.316
Authors: Lynn R Anspaugh; André Bouville; Kathleen M Thiessen; F Owen Hoffman; Harold L Beck; Konstantin I Gordeev; Steven L Simon Journal: Health Phys Date: 2022-01-01 Impact factor: 1.316
Authors: Steven L Simon; André Bouville; Harold L Beck; Lynn R Anspaugh; Kathleen M Thiessen; F Owen Hoffman; Sergey Shinkarev Journal: Health Phys Date: 2022-01-01 Impact factor: 1.316