Assessment of photon and proton-induced activation in particles accelerators.

IF 0.8 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Radiation protection dosimetry Pub Date : 2024-11-13 DOI:10.1093/rpd/ncae146

Abdel-Mjid Nourreddine, Jonathan Collin, Nicolas Arbor, François Begin, Massimo Barbagallo, Federico Carminati, Giuliana Galli Carminati, Jean-Michel Horodynski

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引用次数: 0

Abstract

Nuclear activation affects all operating, future, or dismantled particle accelerators used in various fields, from medical applications to industrial applications. This work is concerned with the study of the radioactivity induced in various materials (Sc, Cu, Tb, Ta, W, Au) irradiated by hard Bremsstrahlung photons from an electron beam and by secondary neutrons induced by a proton beam. In both cases, the primary beam features an 18 MeV kinetic energy. We have performed Monte Carlo simulations with MCNP, GEANT4, FLUKA, and PHITS, coupled with the analytical codes CINDER'90 or FISPACT-II, to estimate the threshold reaction rates and the induced radioactivity in the samples. We compared the simulations with experimental activation measurements performed by high-resolution gamma spectrometry at a decommissioned medical LINAC and around the CYRCé cyclotron. We also used CR-39 solid-state nuclear track detectors to characterize the thermal and fast neutron components of the secondary fields.

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评估粒子加速器中的光子和质子诱导活化。

核活化影响着从医疗应用到工业应用等各个领域使用的所有正在运行的、未来的或已拆除的粒子加速器。这项工作主要研究各种材料（Sc、Cu、Tb、Ta、W、Au）在电子束产生的硬轫致辐射光子和质子束产生的二次中子辐照下产生的放射性。在这两种情况下，主束的动能都是 18 兆电子伏特。我们使用 MCNP、GEANT4、FLUKA 和 PHITS 以及分析代码 CINDER'90 或 FISPACT-II 进行了蒙特卡罗模拟，以估算样品中的阈值反应速率和诱导放射性。我们将模拟结果与在退役的医用 LINAC 和 CYRCé 回旋加速器周围通过高分辨率伽马能谱仪进行的实验活化测量结果进行了比较。我们还使用 CR-39 固态核轨道探测器来描述二次场的热中子和快中子成分。

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.