Lynn R Anspaugh1, André Bouville2, Kathleen M Thiessen3, F Owen Hoffman4, Harold L Beck5, Konstantin I Gordeev6, Steven L Simon7. 1. Department of Radiology, University of Utah, Emeritus, Henderson, NV. 2. National Cancer Institute, Retired, Bethesda, MD. 3. Oak Ridge Center for Risk Analysis, Oak Ridge, TN. 4. Oak Ridge Center for Risk Analysis, Retired, Oak Ridge, TN. 5. Department of Energy, Retired, New York, NY. 6. Burnasyan Federal Medical Biophysical Center, Deceased, Moscow, Russian Federation. 7. National Cancer Institute, Bethesda, MD.
Abstract
ABSTRACT: The purpose of this paper is to provide a methodology for the calculation of internal doses of radiation following exposure to radioactive fallout from the detonation of a nuclear fission device. Reliance is on methodology previously published in the open literature or in reports not readily available, though some new analysis is also included. Herein, we present two methodologic variations: one simpler to implement, the other more difficult but more flexible. The intention is to provide in one place a comprehensive methodology. Pathways considered are (1) the ingestion of vegetables and fruits contaminated by fallout directly, (2) the ingestion of vegetables and fruits contaminated by continuing deposition by rain- or irrigation-splash and resuspension, (3) the ingestion of vegetables and fruits contaminated by absorption of radionuclides by roots after tillage of soil, (4) the non-equilibrium transfer of short-lived radionuclides through the cow-milk and goat-milk food chains, (5) the equilibrium transfer of long lived radionuclides through milk and meat food chains, and (6) inhalation of descending fallout. Uncertainty in calculated results is considered. This is one of six companion papers that describe a comprehensive methodology for assessing both external and internal dose following exposures to fallout from a nuclear detonation. Input required to implement the dose-estimation model for any particular location consists of an estimate of the post-detonation external gamma-exposure rate and an estimate of the time of arrival of the fallout cloud. The additional data required to make such calculations are included in the six companion papers.
ABSTRACT: The purpose of this paper is to provide a methodology for the calculation of internal doses of radiation following exposure to radioactive fallout from the detonation of a nuclear fission device. Reliance is on methodology previously published in the open literature or in reports not readily available, though some new analysis is also included. Herein, we present two methodologic variations: one simpler to implement, the other more difficult but more flexible. The intention is to provide in one place a comprehensive methodology. Pathways considered are (1) the ingestion of vegetables and fruits contaminated by fallout directly, (2) the ingestion of vegetables and fruits contaminated by continuing deposition by rain- or irrigation-splash and resuspension, (3) the ingestion of vegetables and fruits contaminated by absorption of radionuclides by roots after tillage of soil, (4) the non-equilibrium transfer of short-lived radionuclides through the cow-milk and goat-milk food chains, (5) the equilibrium transfer of long lived radionuclides through milk and meat food chains, and (6) inhalation of descending fallout. Uncertainty in calculated results is considered. This is one of six companion papers that describe a comprehensive methodology for assessing both external and internal dose following exposures to fallout from a nuclear detonation. Input required to implement the dose-estimation model for any particular location consists of an estimate of the post-detonation external gamma-exposure rate and an estimate of the time of arrival of the fallout cloud. The additional data required to make such calculations are included in the six companion papers.
Authors: Steven L Simon; Nicholas Luckyanov; André Bouville; Lester VanMiddlesworth; Robert M Weinstock Journal: Health Phys Date: 2002-06 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: Harold L Beck; André Bouville; Steven L Simon; Lynn R Anspaugh; Kathleen M Thiessen; Sergey Shinkarev; Konstantin Gordeev 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: 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