The importance of time-resolved personal Dosimetry in space: The ISS Crew Active Dosimeter

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-11-01 DOI:10.1016/j.lssr.2023.08.004
Ramona Gaza , A. Steve Johnson , Bryan Hayes , Thomas Campbell-Ricketts , Jani Rakkola , Mena Abdelmelek , Cary Zeitlin , Stuart George , Nicholas Stoffle , Andrew Castro , Clif Amberboy , Edward Semones
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Abstract

Monitoring space radiation is of vital importance for risk reduction strategies in human space exploration. Radiation protection programs on Earth and in space rely on personal and area radiation monitoring instruments. Crew worn radiation detectors are crucial for successful crew radiation protection programs since they measure what each crewmember experiences in different shielding configurations within the space habitable volume. The Space Radiation Analysis Group at NASA Johnson Space Center investigated several compact, low power, real-time instruments for personal dosimetry. Following these feasibility studies, the Crew Active Dosimeter (CAD) has been chosen as a replacement for the legacy crew passive radiation detectors. The CAD device, based on direct ion storage technology, was developed by Mirion Dosimetry Services to meet the specified NASA design requirements for the International Space Station (ISS) and Artemis programs. After a successful Technology demonstration on ISS, the CAD has been implemented for ISS Crew operations since 2020. The current paper provides an overview of the CAD development, ISS results and comparison with the ISS Radiation Assessment Detector (RAD) and the Radiation Environment Monitor 2 (REM2) instruments.

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时间分辨个人剂量测定在太空中的重要性:国际空间站乘员主动剂量计
监测空间辐射对人类空间探索中的风险降低战略至关重要。地球和太空的辐射防护计划依赖于个人和区域辐射监测仪器。机组人员佩戴的辐射探测器对机组人员辐射防护计划的成功至关重要,因为它们可以测量每个机组人员在空间宜居空间内不同屏蔽配置下的体验。美国国家航空航天局约翰逊航天中心的空间辐射分析小组研究了几种用于个人剂量测定的紧凑、低功耗实时仪器。根据这些可行性研究,选择了机组人员主动剂量计(CAD)作为传统机组人员被动辐射探测器的替代品。该CAD设备基于直接离子存储技术,由Mirion剂量测定服务公司开发,以满足美国国家航空航天局对国际空间站(ISS)和阿尔忒弥斯项目的特定设计要求。在国际空间站成功进行技术演示后,自2020年以来,国际空间站机组人员的操作已经实施了CAD。本文概述了CAD的发展、ISS的结果以及与ISS辐射评估探测器(RAD)和辐射环境监测器2(REM2)仪器的比较。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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