A Quantitative Assessment of Indoor Radon Level and Its Annual Effective Dose in Buildings of Gachin Rural District in Hormozgan Province, Iran

Q3 Health Professions

Iranian Journal of Medical Physics Pub Date : 2021-05-01 DOI:10.22038/IJMP.2020.45461.1706

Ali Jamjour, G. Haddadi, M. Haghani, Mohammaad Haghparast, M. Afkhami

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引用次数: 0

Abstract

Introduction: Measurement of indoor radon concentration and its determining factors is crucial for improving public health and developing proper methods that can reduce indoor radon concentrations. This study aimed to measure the indoor radon concentration and to examine its variations in relation to variables, such as the construction materials, ventilation, and age of buildings. Material and Methods: Indoor radon concentrations were measured using solid-state nuclear track detectors (SSNTDs) during winter. Each detector was mounted 50-90 cm above the surface flooring of bedrooms and living rooms. After three months of exposure, the detectors were collected and transferred to a laboratory. They were then etched in 6.25 N NaOH solution in a bath at a constant temperature of 90°C for 240 minutes. Next, the detectors were washed with distilled water and dried. The alpha particle tracks were counted using an automatic alpha track counting system. Results: The mean radon concentration was 53.20 Bq/m3,and 94% of the samples had a radon concentration 3, which is the action level proposed by the World Health Organization (WHO). The annual effective dose varied from 0.25 mSvy-1 to 3.05 mSvy-1, with a mean dose of 0.91 mSvy-1. The results showed that the type of constructed materials and ventilation influence the indoor radon concentration in winter. Conclusion: The annual effective dose in the study area was below the global average of 1.15 mSvy-1. Therefore, local residents must be informed about the health risks of high radon concentrations and understand the role of improved ventilation in reducing the indoor radon levels.

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伊朗霍尔莫兹甘省加钦农村地区建筑物室内氡水平及其年有效剂量的定量评估

引言：测量室内氡浓度及其决定因素对于改善公众健康和开发降低室内氡浓度的适当方法至关重要。这项研究旨在测量室内氡浓度，并检查其与建筑材料、通风和建筑年代等变量的关系。材料和方法：在冬季使用固态核轨道探测器（SSNTD）测量室内氡浓度。每个探测器安装在卧室和客厅地面以上50-90厘米处。暴露三个月后，收集探测器并将其转移到实验室。然后在90°C的恒温槽中，在6.25 N NaOH溶液中蚀刻240分钟。接下来，用蒸馏水清洗检测器并干燥。使用自动阿尔法轨道计数系统对阿尔法粒子轨道进行计数。结果：氡平均浓度为53.20 Bq/m3，94%的样品氡浓度为3，这是世界卫生组织（世界卫生组织）提出的行动水平。年有效剂量从0.25 mSvy-1到3.05 mSvy-1不等，平均剂量为0.91 mSvy-1。结果表明，建筑材料类型和通风方式对冬季室内氡浓度有影响。结论：研究区域的年有效剂量低于1.15 mSvy-1的全球平均水平。因此，必须让当地居民了解高氡浓度对健康的风险，并了解改善通风在降低室内氡水平方面的作用。

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

Iranian Journal of Medical Physics Health Professions-Radiological and Ultrasound Technology

CiteScore

1.00

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： Iranian Journal of Medical Physics (IJMP) is the official scientific bimonthly publication of the Iranian Association of Medical Physicists. IJMP is an international and multidisciplinary journal, peer review, free of charge publication and open access. This journal devoted to publish Original Papers, Review Articles, Short Communications, Technical Notes, Editorial and Letters to the Editor in the field of “Medical Physics” involving both basic and clinical research. Submissions of manuscript from all countries are welcome and will be reviewed by at least two expert reviewers.