A method to determine the distance, shielding and activity of orphan 137Cs sources in mobile gamma spectrometric search.

IF 0.7 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Radiation protection dosimetry Pub Date : 2025-08-26 DOI:10.1093/rpd/ncaf016

Christopher Rääf, Mattias Jönsson, Marius-Catalin Dinca, Robert Finck

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Abstract

A mobile gamma spectrometer's series of pulse height distributions (gamma spectra) acquired when passing a point source contains enough information to derive the distance to the source, its shielding and activity. Two Excel routines, SODAC and SSC, have been developed to determine these source parameters. SODAC determines the source-road distance by finding the best fit of the measured series of the primary photon peak count rates to a count rate function characteristic of the distance to the source. A possible source shield reduces the primary count rate and raises the count rate from Compton scattered photons in the shield. SSC calculates the shield mass thickness for common building material using ratio functions of scattered to primary count rates obtained from measurements on known shielding geometries. SODAC then calculates the source activity. The technique was practically tested for 137Cs point sources but can also be applied to other gamma-emitting radionuclides.

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移动伽马能谱搜索中孤儿137Cs源距离、屏蔽和活度的确定方法。

移动伽马能谱仪通过点源时获得的一系列脉冲高度分布（伽马能谱）包含了足够的信息，可以推导出到源的距离、屏蔽和活动。已经开发了两个Excel例程SODAC和SSC来确定这些源参数。SODAC通过寻找测量到的主光子峰值计数率序列与与源距离特征的计数率函数的最佳拟合来确定源-路距离。一种可能的源屏蔽降低了主计数率，提高了屏蔽中康普顿散射光子的计数率。SSC计算普通建筑材料的屏蔽质量厚度，使用从已知屏蔽几何形状的测量中获得的散射与主要计数率的比率函数。然后SODAC计算源活动。该技术对137Cs点源进行了实际测试，但也可应用于其他γ -发射放射性核素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Radiation protection dosimetry 环境科学-公共卫生、环境卫生与职业卫生

CiteScore

1.40

自引率

10.00%

发文量

223

审稿时长

6-12 weeks

期刊介绍： Radiation Protection Dosimetry covers all aspects of personal and environmental dosimetry and monitoring, for both ionising and non-ionising radiations. This includes biological aspects, physical concepts, biophysical dosimetry, external and internal personal dosimetry and monitoring, environmental and workplace monitoring, accident dosimetry, and dosimetry related to the protection of patients. Particular emphasis is placed on papers covering the fundamentals of dosimetry; units, radiation quantities and conversion factors. Papers covering archaeological dating are included only if the fundamental measurement method or technique, such as thermoluminescence, has direct application to personal dosimetry measurements. Papers covering the dosimetric aspects of radon or other naturally occurring radioactive materials and low level radiation are included. Animal experiments and ecological sample measurements are not included unless there is a significant relevant content reason.