DERIVATION OF RISK SCREENING VALUES FOR RADIOACTIVE CONTAMINATION OF SOIL IN NUCLEAR FACILITY DECOMMISSIONING

TENG Keyan; SUN Hongtu; ZENG Yufeng; ZHENG Guofeng

doi:10.13205/j.hjgc.202307032

Volume 41 Issue 7

Jul. 2023

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2023 > 41(7): 235-240

CAO Lixia, LI Wenshuan, LIN Xin, LI Xiaojun, FU Wanlong. EFFECTS OF SELENIUM APPLICATION ON ARSENIC UPTAKE AND ACCUMULATION IN RICE[J]. ENVIRONMENTAL ENGINEERING , 2023, 41(7): 271-276. doi: 10.13205/j.hjgc.202307036

Citation:

TENG Keyan, SUN Hongtu, ZENG Yufeng, ZHENG Guofeng. DERIVATION OF RISK SCREENING VALUES FOR RADIOACTIVE CONTAMINATION OF SOIL IN NUCLEAR FACILITY DECOMMISSIONING[J]. ENVIRONMENTAL ENGINEERING , 2023, 41(7): 235-240. doi: 10.13205/j.hjgc.202307032

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DERIVATION OF RISK SCREENING VALUES FOR RADIOACTIVE CONTAMINATION OF SOIL IN NUCLEAR FACILITY DECOMMISSIONING

doi: 10.13205/j.hjgc.202307032

The Nuclear and Radiation Safety Center of MEE, Beijing 100082, China

Received Date: 2022-08-03

Abstract

Abstract

The Law of Soil Pollution Prevention and Control of the People's Republic of China has stipulated that we should implement a soil pollution risk control system. However, the risk control system of soil radioactive pollution has not been established, and no screening value of soil radioactive pollution for risk control has been formulated. The research selected 0.01 mSv/a as a screening value to determine dosage guidelines, used RESRAD software program to calculate and deduce the screening values of soil radioactive contamination risk, according to different land-use types, and then compared the calculated results with the nuclide screening values recommend by United States NRC, and determined the soil risk screening values of 9 nuclide species. The research can provide a basis for improving the soil radioactivity risk control standards in China.
- risk management and control,
- soil,
- radioactive contamination,
- screening value,
- RESRAD

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References(12)

References

[1]	张蕴.双碳目标下我国核电发展趋势分析[J].核科学与工程,2021,41(6):1347-1351.
[2]	黄国鑫,刘瑞平,杨瑞杰,等.我国农用地土壤重金属污染风险管控研究进展与实践要求[J].环境工程,2022,40(1):216-233.
[3]	刘立波,李国清,靳立强,等.我国核设施退役治理标准化现状及建议[J].辐射防护,2016,36(5):326-333.
[4]	国家环境保护总局.拟开放场址土壤中剩余放射性可接受水平规定(暂行):HJ/T 53-2000[S].北京:中国环境科学出版社,2000.
[5]	黄乃明,邓飞,莫光华.HJ 53-2000在某放射性废物填埋场搬迁及其污染土壤清理中的应用[J].辐射防护通讯,2003,23(5):27-31.
[6]	International Atomic Energy Agency (IAEA).WS-G-5.1:Release of Sites from Regulatory Control on Termination of Practices[R].2006.
[7]	U.S.Nuclear Regulatory Commission.10 CFR Part 20:Standards for Protection against Radiation[R].1989.
[8]	U.S.Nuclear Regulatory Commission.NUREG-1757:Decommissioning Process for Materials Licensees Final Report[R].2006.
[9]	International Atomic Energy Agency (IAEA).GSR Part 3:Radiation Protection and Safety of Radiation Sources:International Basic Safety Standards[R].2011.
[10]	刘爱华,黄丹,贾传钊,等.RESRAD程序在极低放废物填埋场辐射影响评价中的应用研究[J].原子能科学技术,2014,48(增刊1):743-749.
[11]	U.S.Nuclear Regulatory Commission.RG 183:alternative radiological source terms for evaluating design basis accidents at nuclear power reactors[R].2000.
[12]	KATTI S K,RAO A V.Handbook of the poisson distribution[J].Journal of the Operational Research Society, 1967,10(2):412-412.

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