青岛市地表伽玛辐射特征及环境影响评价

对青岛市1 500 km 2范围内大密度土壤放射性核素和地表γ 辐射测量,系统深入研究了其放射性特征、分布规律及其影响因素。结果表明,青岛市土壤中核素232 Th 和40 K 的放射性比活度偏高,而238U 偏低。地表γ 辐射剂量率( 平均值91. 87 nGy /h) 略高于全国和世界平均值。研究发现,地表 93. 14%的γ 辐射来自地面放射性核素238U、232 Th 和40K 的γ 辐射,其中232 Th 和40K 的贡献占81. 21%,是主要的贡献者。地质背景决定地面γ 辐射剂量率值,燕山期各类花岗岩是导致青岛市区-王哥庄一带γ 辐射剂量率偏高的主要原因; 同时环境因素( 路面材料、地貌景观) 对其剂量率也存在一定影响。虽然研究区的γ 辐射剂量率较高,但其年有效剂量( 0. 56 mSv) 低于公众照射年剂量当量限值 ( 1. 0 mSv) ,人居环境基本不受影响。     

资源地区空气氡浓度调查与剂量估算

对广西资源地区大气中氡的调查结果显示，该区室内、外大气中平均氡浓度分别为101.0Bq/m^3和104.6Bq/m^3，是世界平均值的10倍和2.5倍；计算了氡子体所致的年有效剂量，由氡子体照射对成人和儿童所致年均有效剂量分别为6.2mSv/a和9.2mSv/a，是世界平均值的5倍。     

大伙房水库输水工程放射性调查及影响评价

在输水工程隧洞穿过地区开展放射性调查，测量地表岩石γ照射量率和氡气析出率，分析钻孔岩心、地表岩石及水体样品中的放射性元素U、Th、Ra、K及总α、总β。根据调查和分析结果，预测放射性对施工人员和被输送水体产生的影响。     

大连市区地表天然放射性水平调查

利用ARD型γ能谱仪对辽宁省大连市区地表天然放射性核素²³⁸U、²³²Th、⁴⁰K含量进行了现场测量.调查结果显示,大连市区²³⁸U、²³²Th、⁴⁰K比活度平均值分别为23.09 Bq/kg（范围值1.24~151.91 Bq/kg）、18.99 Bq/kg（范围值0.41~92.57 Bq/kg）、386.39 Bq/kg（范围值31.30~1095.50 Bq/kg）,均显著低于全国和世界的平均值.在测得的²³⁸U、²³²Th、⁴⁰K含量基础上,计算了距地面1 m高处空气中γ辐射吸收剂量率、外照射指数、内照射指数和年有效剂量等参数,并据此对大连市区天然放射性水平进行了评价.空气中γ辐射吸收剂量率（Dr）平均值为39.04 nGy/h,远低于全国（81.5 nGy/h）和世界（80 nGy/h）平均水平.外照射指数、内照射指数平均值分别为0.23、0.12,均远小于国家对建筑材料外照射指数的限值1.年有效剂量为0.048 mSv,远低于世界年平均有效剂量（0.46 mSv）以及公众外照射年有效剂量（1.0 mSv）的限值.评价结果表明,大连市区地表天然放射性辐射处于安全的水平.     

西北某引水工程水质天然放射性调查及评价

通过对该引水工程涉及区钻孔岩心伽玛照射量率测量和区域伽玛照射量率调查以及岩石、土壤、底泥以及地表水、地下水中天然放射性核素U、226Ra、Th、40K及总α、总β放射性水平调查,结果表明,工程涉及区属于天然放射性低背景区,地表及地下水水质较好,能满足引水工程的要求,该引水工程是可行的。     

青岛市地表天然放射性水平及其主控因素特征

通过对青岛市1500km^2范围内大密度土壤放射性核素（^238U、^232Th和^40K）和地表γ辐射测量,系统深入地研究了其放射性特征、分布规律及其影响因素。结果表明,青岛市土壤中核素^232Th和咏的放射性比活度偏高,而^238U偏低。地表γ辐射吸收剂量率（平均值91．87nGy·h^-1）略高于全国和世界平均值,研究发现地表93．14％的γ辐射来自地面放射性核素^238U、^232Th和^40K）的．γ辐射,其中^232Th和^40K的贡献占81．21％,是主要的贡献者。地质背景是影响地面γ辐射吸收剂量率的主要因素,燕山期各类花岗岩是导致青岛市区-王哥庄-带γ辐射吸收剂量率偏高的主要原因;同时环境因素（路面材料、地貌景观）对地表γ辐射吸收剂量率也存在一定影响。虽然研究区的γ辐射吸收剂量率较高,但其年有效剂量（0．56 mSv）远低于公众照射年剂量当量限值1.0 mSv,人居环境基本不受影响。     

环境水样中铀、钍、镭和铅同位素及其比值的系统分析

本文研究了从5L水中用铁、铅、钡和铈作载体,系统分析~(234)U、~(238)U、~(228)Th、~(230)Th~(232)Th、~(224)Ra、~(226)Ra、~(228)Ra和~(210)Pb的含量或比值。铀、钍经Fe(OH)_3沉淀富集后用TBP萃淋树脂柱分离,用激光荧光和比色法测定,同位素比值用α谱仪测量,化学回收率在90％以上,测量下限分别为1μg/L和3μg/L。镭、铅经硫酸盐沉淀富集后,用EDTA在不同pH条件下分离,~(224)Ra和~(226)Ra用射气法测定,~(228)Ra和~(210)Pb分别用其β子体~(228)Ac和~(210)Bi在低本底β装置上测量,测量下限分别为2.5×10~(-2)、8×10~(-3)、4×10~(-3)和5×10~(-3)Bq/L。     

广东省部分地区土壤放射性核素的测定和剂量评估

天然及人工放射性是目前生态研究领域的热点之一。在本次试验中,抽查了广东省内不同土壤(沉积物)类型中放射性核素~(238)U、~(232)Th、~(226)Ra和~(40)K的含量,49件样品中~(238)U、~(232)Th、~(226)Ra和~(40)K的含量分别为84.3(17.9～209.1)Bq/kg、103.0(10.6～263.8)Bq/kg、77.7(12.0～206.0)Bq/kg和463.3(15.3～1557.6)Bq/kg,地表空气中的伽马吸收剂量率为126.8(27.2～265.9)nGy/h。研究区样品的等效镭为260.7(33.5～619.0)Bq/kg,外部危害指数值为1.2(0.15～2.8),年有效剂量率确定在155.5(33.3～326.1)μSv/y。将每件样品分为岩石背景、地貌背景和土壤类型三个变量因子,随机森林分析表明,样品中的放射性核素分布主要受控于不同的岩石背景,其次为土壤类型和地貌特征。与国内外不同地区的研究对比,广东省内土壤样品中的放射性核素浓度高于国内和全球的平均值,但放射性水平在安全范围内。     

青岛市天然放射性环境地质调查

对青岛地区进行了大规模的天然放射性环境地质调查和评价中发现,青岛地区陆地伽马辐射剂量率虽然略高于全国和山东省的平均水平,但仍属于天然辐射安全区域.测区的伽马辐射剂量率值总体上决定于岩性.伽马辐射剂量率都来自于²³⁸U、²³²Th、⁴⁰K的贡献,但是与其他地区不同,⁴⁰K和²³²Th对剂量率的贡献要大于²³⁸U.此外,一些公路、建筑等建造材料中的放射性核素的含量直接影响着这些工程的放射剂量,主要是在建造这些工程时所选用的石材、石料和水泥等,都会对当地的放射剂量有着重大的影响.     

华东地区含煤岩系天然放射性水平与生态健康风险评价

本次研究基于地表γ辐射剂量率、氡放射性测量及²³⁸U、²³²Th、²²⁶Ra、⁴⁰K放射性核素测试,识别华东地区含煤岩系的放射性异常地层,评价区域典型煤矿区空气、固体、水体、植物介质的天然放射性水平。结果显示：赋存于石炭系、二叠系的普通煤田与赋存于寒武系的石煤矿区呈现显著差异的天然放射性水平。普通煤田矿区地表γ辐射剂量率、氡放射性测量值总体上处于本底水平范围,矿区固体介质、水体、植物样品核素含量处于正常水平,不存在放射性污染。华东地区石煤分布带,属于放射性γ辐射高背景区,石煤矿区的原煤、煤矸石、土壤、岩石等固体介质的²³⁸U、²²⁶Ra核素富集明显,并显示更为显著的空间变异性。区域石煤条带监测矿区居民源于γ外照射引起的吸收剂量均超过国际标准限值1 mSv/a,总有效剂量均超过了2 mSv/a,地下水总α、总β浓度为限值的10~30倍,放射性污染不容忽视。华东地区石煤矿区公众所受辐射剂量较高,矿区的地下水、建材、植物等介质已经出现零星的放射性污染,应加强石煤矿区放射性环境监测,及时采取适当的控制措施。     

安徽铁炉地区放射性污染调查分析及防治措施

对安徽东至县铁炉地区开展了放射性污染调查工作,并提出了防治方案和治理措施。其方法是采用6台FD-3013γ辐射仪、1台FD-3022N道γ谱仪和1台FD-3017氡射气仪对该地区进行大比例尺地面γ辐射剂量率、地面γ能谱、水中氡浓度等测量。获得了该地区γ辐射剂量率为0．11～4.38μGy/h;铀质量活度为123-1 230Bq／kg,钍质量活度为21-411 Bq/kg,钾质量活度为264-528Bq／kg;水中铀活度浓度为4-12 300 Bq／L,水中氡活度浓度为2-155Bq／L;剥露的岩矿、矿渣中铀质量活度为1230-151 290 Bq／kg,钍质量活度为25-411 Bq／kg。该地区地面γ辐射剂量率、地层中铀、钍质量活度均高于安徽省平均值,而剥露的岩矿、矿渣中铀质量活度远大于地层中的铀质量活度,是该地区环境中最大的潜在污染源之一,并为此提出了4项治理措施。     

Study of radium content and radon exhalation rates in soil samples of northern India

Radon is a radioactive hazardous and ubiquitous gas. It has been recognized to be one of the major contributors to natural radiation even causing lung cancer if present at enhanced levels. There are large variations in data available in the literature for radium content and radon exhalation rates of various materials. It is a well-documented fact that radon exhalation from the ground surface depends upon a number of parameters such as soil grain size, soil porosity and radium content. For this purpose, in this study the so-called can technique has been used to measure radium content and exhalation rates of radon in soil samples collected from different places of Aligarh, Etah and Mathura districts of Uttar Pradesh??a province in northern India. These districts lie within the subtropical region of the Indo-Gangetic plains. The values of effective radium content are found to vary from 8.11 to 112.83?Bq?kg^?1 with a mean value of 33.21?Bq?kg^?1 and a standard deviation of 28.15. The values of mass exhalation rates of radon vary from 0.76?×?10^?6 to 15.80?×?10^?6?Bq?kg^?1?day^?1 with a mean value of 4.21?×?10^?6?Bq?kg^?1?day^?1, while the surface exhalation rates vary from 1.97?×?10^?5 to 41.03?×?10^?5?Bq?m^?2?day^?1 with a mean value of 10.93?×?10^?5?Bq?m^?2?day^?1.     

Determination of the radiation dose due to radon ingestion and inhalation

The distribution of radon in ground and surface water samples in Sankey Tank and Mallathahalli Lake areas was determined using Durridge RAD-7 analyzer with RAD H₂O accessory. The radiation dose received by an individual falling under different age groups (viz., 3 months; 1, 5, 10, 15 years and adult) depending upon their average annual water consumption rate was attempted. The mean radon activity in surface water of Sankey Tank and Mallathahalli Lake was 7.24 ± 1.48 and 11.43 ± 1.11 Bq/L, respectively. The average radon activities ranged from 11.6 ± 1.7 to 381.2 ± 2.0 Bq/L and 1.50 ± 0.83 to 18.9 ± 1.59 Bq/L, respectively, in 12 groundwater samples each around Sankey Tank and Mallathahalli Lake areas. Majority of the measured groundwater samples (viz., 100 % in Sankey Tank area and 75 % in Mallathahalli Lake area) showed mean radon values above the EPA’s maximum contaminant level of 11.1 Bq/L and only 66.67 % of samples in Sankey Tank area showed radon above the WHO and EU’s reference level of 100 Bq/L. The overall radiation dose due to radon emanating from water in the study area was increasing with increase in age and water consumption rates, but significantly lower than UNSCEAR and WHO recommended limit of 1 mSv/year except for few groundwater samples in Sankey Tank area (i.e., 0.92, 0.99 and 1.39 mSv/year). The radiation dose rate received by bronchial epithelium via inhalation was very high compared to that by stomach walls via ingestion.     

某铀矿山废石堆场氡污染调查

通过对某铀矿山11个废石堆场氡析出率和大气氡浓度的测量及氡所致年有效剂量估算表明,该矿山正在使用的废石堆场氡析出率值均超出了国家规定的管理限值水平,只有退役治理后的废石堆场氡析出率在管理限值以内;矿山废石堆场产生的大气氡浓度值为72.35Bq/m3,其所致的年有效剂量值为0.69mSv。     

Measurement of radon exhalation rate in various building materials and soil samples

Indoor radon is considered as one of the potential dangerous radioactive elements. Common building materials and soil are the major source of this radon gas in the indoor environment. In the present study, the measurement of radon exhalation rate in the soil and building material samples of Una and Hamirpur districts of Himachal Pradesh has been done with solid state alpha track detectors, LR-115 type-II plastic track detectors. The radon exhalation rate for the soil samples varies from 39.1 to 91.2 mBq kg^?1 h^?1 with a mean value 59.7 mBq kg^?1 h^?1. Also the radium concentration of the studied area is found and it varies from 30.6 to 51.9 Bq kg^?1 with a mean value 41.6 Bq kg^?1. The exhalation rate for the building material samples varies from 40.72 (sandstone) to 81.40 mBq kg^?1 h^?1 (granite) with a mean value of 59.94 mBq kg^?1 h^?1.     

Study of the radon concentrations in drinking water from three main cities of Shaanxi Province,China

This paper presents the results of radon concentration measurements in the drinking water from the municipal water supply system and private wells of Xian, Xianyang and Baoji city of Shaanxi province of China. The measurements were carried out on 38 samples. Radon levels in drinking water in Xian, Xianyang and Baoji were found to be 5.78, 13.04 and 15.01 k Bq m^–3, respectively. The AM radon concentration of private well water from Xianyang and Baoji is 28.84 k Bq m^–3 and 38.85 k Bq m^–3, respectively, which is 2.56 times and 3.14 times as high as that of tap water radon, respectively. The radiation risk of radon in water would be due to degassing and not due to drinking water. The domestic use of showers, humidifiers, and cooking, washing up, laundering, etc. may lead to an additional increase of the radon concentration in the indoor air. The observed radon concentration in drinking water from three main cities of Shaanxi Province can contribute to a 4.86 to 32.63% increase in indoor radon concentration and can cause 0.068±0.016 mSv y^–1 to 0.177±0.045 mSv y^–1 extra annual effective dose to males, 0.060±0.014 mSv y^–1 to 0.155±0.039 mSv y^–1 to females. The mean annual effective dose equivalents to males and females of Xianyang and Baoji from well water account for 25.94 to 39.75% of environmental radon and radon daughters annual effective dose equivalents. The radon concentrations in the well water from Xianyang and Baoji will bring a definite additional risk to the population.     

一种简易表面氡析出率测量装置的设计

氡及其子体是天然本底辐射剂量的主要贡献者,是当前的一个研究热点。设计了一种简易的表面氡析出率测量装置,可以用来测量某些样品表面的氡析出率。为了了解所设计装置的性能,对不同氡析出率大小的样品进行了测量,同时对这种防氡涂料的防氡效果进行了测评。测量结果表明,该测量装置可较为准确地给出所测样品的表面氡析出率,且性能稳定、操作简便,可改进余地较大,缺点是测量耗时较长。