Results of long-term radiation environment monitoring by the Russian RMS system on board Zvezda module of the ISS

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-11-01 DOI:10.1016/j.lssr.2022.11.002

Victor Benghin , Vyacheslav Shurshakov , Vladislav Osedlo , Victor Mitrikas , Sergey Drobishev , Oleg Nechaev , Ivan Zolotarev , Lidia Bratolubova-Tsulukidze

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Abstract

The Radiation monitoring system (RMS) continuously operated in various configurations since the launch of the Zvezda module of the International Space Station (ISS). The RMS consisted of 7 units, namely: the R-16 dosimeter, 4 DB-8 dosimeters, utility and data collection units. The obtained data covers a time of 22 years. This paper analyses the radiation environment variations on board the “Zvezda” module. Variations of the onboard daily dose rate associated with changes of ISS altitude and 11-year cycle galactic cosmic rays’ variations are analyzed and discussed. It is shown that the observed increase in the daily dose from 0.20 - 0.25 to 0.35 - 0.50 mGy/day is mostly due to the increase of ISS orbit altitude, resulting in a substantial increase of the dose contribution from the South Atlantic Anomaly (SAA) Region. Dose rate variations in the SAA as well as latitude and longitude dose rate distributions are discussed in detail. Analysis confirms that the well-known westward drift effect of the SAA is clearly visible from radiation dose measurements on the ISS.

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国际空间站“星号”舱上俄罗斯RMS系统长期辐射环境监测结果

自国际空间站Zvezda舱发射以来，辐射监测系统（RMS）一直以各种配置运行。RMS由7个单元组成，即：R-16剂量计、4个DB-8剂量计、公用设施和数据收集单元。所获得的数据涵盖了22年的时间。本文分析了“Zvezda”模块上的辐射环境变化。分析和讨论了星载日剂量率随国际空间站高度变化和11年周期银河宇宙射线变化的变化。研究表明，观测到的日剂量从0.20-0.25 mGy/天增加到0.35-0.50 mGy/日，主要是由于国际空间站轨道高度的增加，导致南大西洋异常区的剂量贡献显著增加。详细讨论了SAA中的剂量率变化以及纬度和经度剂量率分布。分析证实，从国际空间站的辐射剂量测量中可以清楚地看到众所周知的SAA向西漂移效应。

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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