广东省伴生放射性矿周围土壤放射性水平分析

doi:10.16258/j.cnki.1674-5906.2023.09.016

生态环境学报 ›› 2023, Vol. 32 ›› Issue (9): 1692-1699.DOI: 10.16258/j.cnki.1674-5906.2023.09.016

广东省伴生放射性矿周围土壤放射性水平分析

宁健(), 程晓波, 苏超丽, 汤泽平, 余泽峰

广东省环境辐射监测中心，广东广州 510300

收稿日期:2023-06-07 出版日期:2023-09-18 发布日期:2023-12-11
作者简介:宁健（1978年生），男，高级工程师，从事辐射环境监测、评价与研究工作。E-mail: 18304252@qq.com
基金资助:
广东省生态环境厅2020年广东省辐射项目监督性监测专项资金资助(粤环办函[2020]7号)

Analysis of Soil Radioactivity Levels around NORM Facilities in Guangdong Province

NING Jian(), CHENG Xiaobo, SU Chaoli, TANG Zeping, YU Zefeng

Guangdong Environmental Radiation Monitoring Center, Guangzhou 510300, P. R. China

Received:2023-06-07 Online:2023-09-18 Published:2023-12-11

摘要/Abstract

摘要：

土壤放射性污染、特别是天然放射性核素产生的污染因其半衰期长、治理难度大一直是重点关注领域；目前对土壤放射性污染研究集中在核设施、铀矿冶等领域，伴生放射性矿运行对周围土壤的放射性污染关注较少，广东省伴生放射性矿周围土壤放射性水平分析研究尚处于探索阶段。为掌握广东省伴生放射性矿周围土壤放射性水平，按照《土壤中放射性核素的γ能谱分析方法》（GB/T 11743—2013），分析广东省26家伴生放射性矿企业厂界下风向、周围居民点和对照点土壤中U-238、Ra-226、Th-232等关键核素活度浓度。结果表明，厂界土壤中U-238、Ra-226、Th-232活度浓度最大值分别为 (378±15)、(207±8)、(487±19) Bq•kg⁻¹，居民点土壤中U-238、Ra-226、Th-232活度浓度最大值分别为 (337±13)、(139±6)、(233±9) Bq•kg⁻¹，伴生放射性矿开发利用企业厂界外土壤没有放射性污染；有8家企业生产活动可能使得厂界周围土壤放射性水平超过当地环境本底水平，其余企业厂界土壤放射性水平与本底水平相当，反映出部分企业生产抬升周围土壤放射性水平；或与本底水平掌握不够精细有关。约2/3企业厂界下风向土壤中放射性核素活度浓度高于敏感点和对照点，企业生产经营活动存在含放射性渣料洒落、飘逸出厂界等现象；另约1/3企业厂界下风向土壤放射性水平与周围居民点处无明显差异，企业日常辐射环境管理规范。通过对广东省伴生放射性矿周围土壤放射性水平进行分析，对伴生放射性矿开发利用企业提出日常辐射环境管理要求，向生态环境主管部门提出建议，以促进伴生放射性矿开发利用行业健康发展。

关键词: 广东省, 伴生放射性矿, 土壤, γ能谱分析, 放射性水平, 辐射环境管理

Abstract:

Soil radioactive pollution, especially from naturally occurring radioactive nuclides, has always been a key area of concern due to their long half-lives and high difficulty in management. Currently, research on soil radioactive pollution focused on nuclear facilities, uranium mining and metallurgy. There is less attention on the radioactive pollution of surrounding soil caused by the operation of naturally occurring radioactive material (NORM) enterprises. The analysis and research on the radioactive level of soil around NORM enterprises in Guangdong Province are still in an exploratory stage. In order to explore the radioactive levels in the soil around the mines of NORM enterprises in Guangdong Province, in accordance with the “Determination of radionuclides in soil by gamma spectrometry” (GB/T 11743—2013), we analyzed the activity concentrations of key nuclides, such as U-238, Ra-226 and Th-232 in the soil of 26 NORM enterprises in Guangdong Province. The results showed that the maximum activity concentrations of U-238, Ra-226, and Th-232 in the soils at the factories’ boundaries were (378±15) Bq•kg⁻¹, (207±8) Bq•kg⁻¹, and (487±19) Bq•kg⁻¹, respectively. The maximum activity concentrations of U-238, Ra-226, and Th-232 in the soil of residential areas were (337±13) Bq•kg⁻¹, (139±6) Bq•kg⁻¹, and (233±9) Bq•kg⁻¹, respectively. There was no obvious radioactive pollution in the soil outside the factories’ boundaries of the NORM; There were 8 NORM enterprises whose production activities may cause the soil radioactivity levels around the factories’ boundaries to exceed the local environmental background level, while the soil radioactivity levels at the factories’ boundaries of other NORM facilities were equivalent to the background level. This reflected that some NORM enterprises’ production may raise the surrounding soil radioactivity level. It may also be related to inadequate assessment of the background levels. Approximately two-thirds of the enterprises had higher activity concentrations of radioactive nuclides in the soil downwind from NORM boundaries than the sensitive areas and the control points areas. This may be attributed to the scattering of radioactive residues and emissions outside the boundaries during enterprise production activities. For the remaining one-third of the enterprises, there was no significant difference in radioactivity levels in the soil downwind direction of NORM enterprises’ boundaries compared to the nearby residential areas, indicating that these NORM enterprises adhered to standard daily radiation environmental management. By analyzing the soil radioactivity levels around NORM mines in Guangdong Province, daily radiation environment management requirements are proposed for enterprises involved in the development and utilization of associated radioactive minerals. These suggestions are intended to promote the healthy development of the NORM mining industry and have been submitted to the environmental authorities for consideration.

Key words: Guangdong Province, naturally occurring radioactive material (NORM), soil, γ Energy spectrum analysis, radioactive level, radiation environment management

中图分类号:

宁健, 程晓波, 苏超丽, 汤泽平, 余泽峰. 广东省伴生放射性矿周围土壤放射性水平分析[J]. 生态环境学报, 2023, 32(9): 1692-1699.

NING Jian, CHENG Xiaobo, SU Chaoli, TANG Zeping, YU Zefeng. Analysis of Soil Radioactivity Levels around NORM Facilities in Guangdong Province[J]. Ecology and Environment, 2023, 32(9): 1692-1699.

图/表 8

图1 广东省伴生放射性矿分布图

Figure 1 NORM facilities distribution map of Guangdong Provence

表1 放射性核素分析仪器信息

Table 1 Radionuclide analysis instrument informations

技术指标	技术参数
仪器名称	高纯锗γ能谱仪
生产厂家	Mirion Technologies (Canberra) Inc.
仪器型号	GMX-50220-S
探测器类型	P型
晶体直径	62 mm
晶体高度	58.2 mm
能量分辨率¹⁾	1.81 keV
FWTM/FWHM¹⁾	1.818
相对效率¹⁾	46.6%
峰康比¹⁾	66.2꞉1
校准单位	国防科技工业电离辐射一级计量站
证书编号	GFJGJL1005180004369

图2 GMX-50220-S高纯锗γ能谱仪效率质控图

Figure 2 GMX-50220-S HPGe γ spectrometer efficiency quality control chart

图3 土壤平行样相对偏差

Figure 3 Relative deviation of soil parallel samples

图4 土壤复检样相对偏差

Figure 4 Relative deviation of soil retest samples

图5 广东省伴生放射性矿周围土壤中U-238放射性水平

Figure 5 U-238 radioactivity levels in the soil around NORM facilities, Guangdong Province

图6 广东省伴生放射性矿周围土壤中Ra-226放射性水平

Figure 6 Ra-226 radioactivity levels in the soil around NORM facilities, Guangdong Province

图7 广东省伴生放射性矿周围土壤中Th-232放射性水平

Figure 7 Th-232 radioactivity levels in the soil around NORM facilities, Guangdong Province

参考文献 40

[1]	ALAZEMI N, BAJOGA A D, BRADLEY D A, et al., 2016. Soil radioactivity levels, radiological maps and risk assessment for the state of Kuwait[J]. Chemosphere, 154: 55-62. DOI PMID
[2]	ALI M, IQBAL S, WASIM M, et al., 2013. Soil radioactivity levels and radiological risk assessment in the highlands of Hunza, Pakistan[J]. Radiation protection dosimetry, 153(3): 390-399. DOI PMID
[3]	ERKHEMBAYAR T, NOROV N, KHUUKHENKHUU G, et al., 2009. The study of soil radioactivity around central region of Mongolia[J]. AIP Conference Proceedings, 1109(1): 148-151.
[4]	FERNANDO C A R, DEJANIRA C L, MONICA A P R, et al., 2017. Mapping soil radioactivity in the Fernando de Noronha archipelago, Brazil[J]. Journal of Radioanalytical and Nuclear Chemistry, 311(1): 577-587. DOI URL
[5]	MISTURA A, PEANE M, IYABO U, et al., 2020. Assessment of environmental radiation exposure from soil radioactivity around the Southern area of Chad[J]. Radiation Protection and Environment, 43(2): 70-76. DOI URL
[6]	RIKHVANOV L P, ZLOBINA A N, WANG N P, et al., 2016. The nature of high soil radioactivity in Chinese Province Guangdong[J]. Procedia Chemistry, 10: 460-466. DOI URL
[7]	SUNDAY B I, OLADELE S A, ADESEYE M A, 2013. Effect of geology on soil radioactivity and risks to humans based on data from several towns in Nigeria[J]. Environmental Forensics, 14(3): 240-247. DOI URL
[8]	TAKRID M N, HAYDAR A H, ABBAS N M, et al., 2018. Radiation hazard assessment by measuring of soil radioactivity levels in Al-anbar (Al-fallujah District) and Wasit Governorate in Iraq[J]. International Journal of High Energy Physics, 5(1): 5-5. DOI URL
[9]	陈柏迪, 朱志如, 陈志东, 等, 2022. 某稀土企业伴生放射性固体废物暂存库下方土壤放射性核素及重金属纵向分布[J]. 有色金属(冶炼部分) (8): 121-125.
	CHEN B D, ZHU Z R, CHEN Z D, et al., 2022. Vertical distribution of radionuclides and heavy metals in soil below temporary repositories of solid wastes associated with radioactivity in a rare earth enterprise[J]. Nonferrous Metals (Extractive Metallurgy) (8): 121-125.
[10]	陈思, 安莲英, 2013. 土壤放射性污染主要来源及修复方法研究进展[J]. 广东农业科学, 40(1): 174-177.
	CHEN S, AN L Y, 2013. Research progress of radioactive contamination in soil and remediation methods[J]. Guangdong Agricultural Sciences, 40(1): 174-177.
[11]	董涛, 2019. 新疆主要城市土壤放射性核素含量变化分析[J]. 干旱环境监测, 33(3): 125-129.
	DONG T, 2019. Changes of soil radionuclide content in Major Cities in Xinjiang[J]. Arid Environmental Monitoring, 33(3): 125-129.
[12]	冯奕达, 张保生, 2018. 伴生矿开发利用对环境的放射性影响及污染防治措施[J]. 环境与发展, 30(5): 76-77, 85.
	FENG Y D, ZHANG B S, 2018. The associated ore development and utilization of environmental radiation and pollution prevention and control measures[J]. Environmental and Development, 30(5): 76-77, 85. DOI URL
[13]	高柏, 高杨, 蒋文波, 等, 2021. 铀矿区放射性污染土壤修复技术研究进展[J]. 有色金属 (冶炼部分) (8): 28-36.
	GAO B, GAO Y, JIANG W B, et al., 2021. Research progress on remediation technology of radioactive contanminated soil in uranium mining area[J]. Nonferrous Metals (Extractive Metallurgy) (8): 28-36.
[14]	高思旖, 杨春, 谢树军, 等, 2023. 我国伴生放射性矿辐射环境监管的思考[J]. 核技术, 46(1): 4-10.
	GAO S Y, YANG C, XIE S J, et al., 2023. Consideration on radiation environmental supervision of associated radioactive mines[J]. Nuclear Techniques, 46(1): 4-10.
[15]	广东省生态环境厅, 2021. 广东省伴生放射性矿产资源开发利用企业名录 (2021年版)[EB/OL]. http://gdee.gd.gov.cn/zwxx_1/content/post_3846728.html.
	Department of Ecology and Environment of Guangdong Province, 2021. Catalogue for Development and Utilization of NORM Enterprises in Guangdong Province (2021 Edition) [EB/OL]. http://gdee.gd.gov.cn/zwxx_1/content/post_3846728.html.
[16]	江光, 2017. 关于伴生放射性矿辐射环境监管的政策解读和工作思路[J]. 环境保护, 45(18): 28-31.
	JIANG G, 2017. Policy interpretation and working ideas on environmental supervision of associated ore radiation[J]. Environmental Protection, 45(18): 28-31.
[17]	孔令海, 袁洋, 范真真, 等, 2022. ×新区土壤中放射性核素水平评估[J]. 核电子学与探测技术, 42(2): 265-268.
	KONG L H, YUAN Y, FAN Z Z, et al., 2022. Evaluation of radionuclide level in soil of Xiong’an New Area[J]. Nuclear Electronics & Detection Technology, 42(2): 265-268.
[18]	李冠超, 史天成, 杨波, 等, 2021. 某稀土冶炼厂及周边环境土壤中放射性核素分布特征与风险评价[J]. 有色金属 (冶炼部分) (8): 119-126.
	LI G C, SHI T C, YANG B, et al., 2021. Distribution characteristics and risk assessment of radionuclide in soil of a Rrare-earth smelter and its surrounding environment[J]. Nonferrous Metals (Extractive Metallurgy) (8): 119-126.
[19]	李文文, 汪杰, 黄涛, 等, 2022. 安徽铜陵硫化物尾矿区矿砂、土壤和沉积物的天然放射性评价[J]. 生态毒理学报, 17(2): 290-298.
	LI W W, WANG J, HUANG T, et al., 2022. Natural radioactivity evaluation of ores, soils and sediments around sulfide tailings at Tongling City, Anhui Province[J]. Asian Journal of Ecotoxicology, 17(2): 290-298.
[20]	李雨芯, 贺良国, 2023. 四川省土壤天然放射性核素含量调查及人群癌症风险评估[J]. 现代预防医学, 50(6): 1009-1014.
	LI Y X, HE L G, 2023. Natural radionuclides content in soil and cancer risk, Sichuan[J]. Modern Preventive Medicine, 50(6): 1009-1014.
[21]	李政儒, 黄艳茹, 张苏雅拉吐, 等, 2022. 盘锦市表层土壤放射性核素含量调查分析[J]. 中国辐射卫生, 31(6): 687-693.
	LI Z R, HUANG Y R, ZHANG S Y L T, et al., 2022. Analysis of radionuclide content in the surface soil of Panjin, China[J]. Chinese Journal of Radiological Health, 31(6): 687-693.
[22]	刘春雨, 于洋, 2018. 哈尔滨燃煤电厂周围土壤放射性水平的分析[J]. 辐射防护, 38(1): 26-32.
	LIU C Y, YU Y, 2018. Analysis of radiation level in soil around coal-fired power plants in Harbin[J]. Radiation Protection, 38(1): 26-32.
[23]	吕彩霞, 谢树军, 廖运璇, 等, 2021. 伴生放射性矿开发利用辐射环境安全监管法规体系的现状[J]. 中国矿业, 30(8): 36-40.
	LÜ C X, XIE S J, LIAO Y X, et al., 2021. Current situation of the regulatory system of radiation environmental safety for the development and utilization of associated radioactive mines[J]. China Mining Magazine, 30(8): 36-40.
[24]	毛彦明, 李冠超, 阙泽胜, 等, 2022. 广东省某地重点矿山天然放射性环境调查与监测[J]. 世界核地质科学, 39(3): 614-622.
	MAO Y M, LI G C, QUE Z S, et al., 2022. Investigation and monitoring of natural radioactive environment in key mines of an area in Guangdong Province[J]. World Nuclear Geoscience, 39(3): 614-622.
[25]	生态环境部, 2018. 关于发布《伴生放射性矿开发利用企业环境辐射监测及信息公开办法 (试行)》的公告[EB/OL]. https://www.mee.gov.cn/xxgk2018/xxgk/xxgk03/201807/t20180711_630057.html.
	Ministry of Ecology and Environment, 2018. Announcement on the Issuance of the “Measures for Environmental Radiation Monitoring and Information Disclosure in the Development and Utilization of NORM Enterprises (Trial)”[EB/OL]. https://www.mee.gov.cn/xxgk2018/xxgk/xxgk03/201807/t20180711_630057.html.
[26]	生态环境部, 2020. 关于发布《矿产资源开发利用辐射环境监督管理名录》的公告[EB/OL]. https://www.mee.gov.cn/xxgk2018/xxgk/xxgk01/202011/t20201127_810163.html.
	Ministry of Ecology and Environment, 2020. Announcement on the Issuance of the “Catalogue of Radiation Environment for the Utilization of Mineral Resources”[EB/OL]. https://www.mee.gov.cn/xxgk2018/xxgk/xxgk01/202011/t20201127_810163.html.
[27]	孙功明, 林健, 李冠超, 2021. 广东省某伴生放射性矿开发利用企业辐射环境监测[J]. 辐射防护通讯, 41(1): 16-21.
	SUN G M, LIN J, LI G C, 2021. Radiation environment monitoring of a NORM development and utilization enterprise in Guangdong[J]. Radiation Protection Bulletin, 41(1): 16-21.
[28]	王茜, 杜云武, 李雪泓, 等, 2019. 西藏自治区土壤中放射性核素水平分布研究[J]. 环境与发展, 31(2): 112-114.
	WANG Q, DU Y W, LI X H, et al., 2019. Study on the distribution of radionuclide levels in the soil of Tibet autonomous region[J]. Environmental and Development, 31(2): 112-114.
[29]	闫双华, 李建辉, 2023. 云南某伴生放射性矿采矿区放射性水平调查[J]. 环境科学导刊, 42(2): 96-98.
	YAN S H, LI J H, 2023. Investigation of the radioactivity level in the mining area of an associated radioactivity mine in Yunnan[J]. Environmental Science Survey, 42(2): 96-98.
[30]	杨剑洲, 龚晶晶, 唐世新, 等, 2020. 广东省部分地区土壤放射性核素的测定和剂量评估[J]. 物探与化探, 44(2): 419-425.
	YANG J Z, GONG J J, TANG S X, et al., 2020. The determination of radioactivity concentrations in soil samples and dose assessment in parts of Guangdong Province[J]. Geophysical and Geochemical Exploration, 44(2): 419-425.
[31]	杨永虎, 孔利锋, 李宗硕, 等, 2017. 准东煤矿开采区土壤中天然放射性水平环境调查及评价[J]. 新疆环境保护, 39(2): 23-27.
	YANG Y H, KONG L F, LI Z S, et al., 2017. Environmental investigation and assessment of natural radioactivity in soil in the mining area of Zhundong[J]. Environmental Protection of Xinjiang, 39(2): 23-27.
[32]	曾庆卓, 陈联光, 郑伟, 1985. 广东省土壤中天然放射性核素含量调查研究[C]// 国家环境保护局. 中国环境天然放射性水平. 北京: 国家环境保护局: 516-518.
	ZENG Q Z, CHEN L G, ZHENG W, 1985. Investigation of Natural Radionuclide Contents in Soil in Guangdong Province[C]// State Environmental Protection Administration of China. Natural environmental radioactivity level in China. Beijing: State Environmental Protection Administration of China: 516-518.
[33]	浙江省辐射环境监测站 (生态环境部辐射环境监测技术中心), 2021. 辐射环境监测技术规范: HJ 61—2021[S].
	Zhejiang Province Radiation Environmental Monitoring Center (Radiation Monitoring Technical Center of Ministry of Ecology and Environment), 2021. Technical specification for radiation environmental monitoring: HJ 61—2021[S].
[34]	张悦, 刘佳伟, 2017. 鞍山市某区域土壤放射性水平的分析[J]. 鞍山师范学院学报, 19(4): 14-17.
	ZHANG Y, LIU J W, 2017. Radioactive study on soil in a region of Anshan[J]. Journal of Anshan Normal University, 19(4): 14-17.
[35]	张博, 高柏, 马文洁, 等, 2023. 某铀矿及周边地区土壤放射性水平调查与评价[J]. 生态毒理学报, 18(4): 369-383.
	ZHANG B, GAO B, MA W J, et al., 2023. Investigation and evaluation of soil radioactivity levels in a uranium mine and surrounding areas[J]. Asian Journal of Ecotoxicology, 18(4): 369-383.
[36]	张家佳, 彭崇, 郭凯行, 等, 2023. 广西某铀矿山周围土壤和大米放射性调查及评价[J]. 铀矿冶, 42(1): 91-96.
	ZHANG J J, PENG C, GUO K H, et al., 2023. Radioactive investigation and evaluation of soil and rice around the uranium mine in Guangxi[J]. Uranium Mining and Metallurgy, 42(1): 91-96.
[37]	郑存德, 刘清宽, 董国超, 等, 2022. 丹东地区土壤天然放射性核素本底值调查研究[J]. 辐射防护, 42(6): 579-584.
	ZHENG C D, LIU Q K, DONG G C, et al., 2022. Study on background value of soil natural radionuclides in Dandong area[J]. Radiation Protection, 42(6): 579-584.
[38]	中华人民共和国国务院, 1994. 中华人民共和国矿产资源法实施细则.[EB/OL]. https://flk.npc.gov.cn/detail2.html?ZmY4MDgwODE2ZjNj YmIzYzAxNmY0MTMwMzdhZjFiY2U.
[39]	钟可意, 王笠成, 邵波霖, 等, 2022. 某铀水冶厂周边土壤放射性核素U和Th分布特征及污染评价[J]. 生态毒理学报, 17(4): 460-470.
	ZHONG K Y, WANG L C, SHAO B L, et al., 2022. Distribution characteristics and pollution evaluation of soil radionuclides U and Th around a uranium hydrometal lurgy hydrometallurgy plant[J]. Asian Journal of Ecotoxicology, 17(4): 460-470.
[40]	中国疾病预防控制中心辐射防护与核安全医学所, 新疆维吾尔自治区疾病预防控制中心, 包钢集团公司劳动卫生职业病防治研究所, 2013. 土壤中放射性核素的γ能谱分析方法: GB/T 11743—2013[S].
	National Institute of Radiological Protection, Chinese Center for Disease Control and Prevention, The Center for Disease Control and Prevention of Xinjiang Uygur Autonomous Region, Baotou Iron and Steel Group Corporation Labor Health and Occupational Disease Prevention Institute,2013. Determination of radionuclides in soil by gamma spectrometryl: GB/T 11743—2013[S].

广东省伴生放射性矿周围土壤放射性水平分析

Analysis of Soil Radioactivity Levels around NORM Facilities in Guangdong Province

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