[1] Boyer C, Vichot L, Fromm M, et al. Tritium in plants:A review of current knowledge[J]. Environmental and Experimental Botany, 2009,67(1):34-51. [2] Herranz M, Alegria N, Idoeta R, et al. Sampling tritiated water vapor from the atmosphere by an active system using silica gel[J]. Radiation Physics and Chemistry, 2011,80(11):1172-1177. [3] Little M.P, Lambert B E. Systematic review of experimental studies on the relative biological effectiveness of tritium[J]. Radiation and Environmental Biophysics, 2008,47(1):71-93. [4] Marang L, Siclet F, Luck M, et al. Modelling tritium flux from water to atmosphere:application to the Loire River[J]. Journal of Environmental Radioactivity, 2011,102(3):244-251. [5] Noguchi H, Fukutani S, Yokoyama S, et al. Deposition of tritiated water vapour to water surface in an outdoor field[J]. Radiation Protection Dosimetry, 2001, 93(2):167-172. [6] Belot Y, Tritium in plants-A review[J]. Radiation Protection Dosimetry, 1986, 16(1-2):101-105. [7] Rosanvallon S, Torcy D, Chon J K, et al. Waste management plans for ITER[J]. Fusion Engineering and Design, 2016, 109(B):1442-1446. [8] Seethapathy S, Górecki T, Li X. Passive sampling in environmental analysis[J]. Journal of Chromatography A, 2008,1184(1-2):234-253. [9] Gorecki T, Namiesnik J. Passive sampling[J]. Trac-Trends in Analytical Chemistry, 2002, 21(4):276-291. [10] Stephenson J. A diffusion sampler for tritiated-water vapor[C] Health Physics, 1984, 46(3):718-718. [11] Stephenson J. Re-evaluation of the diffusion sampler for tritiated water vapour[R]. Ontario Hydro Report HSD-SD-90-20, 1990. [12] Wood M.J, Mcelroy R, Surette R.A, et al. Tritium sampling and measurement[J]. Health Physics, 1993,65(6):610-627. [13] Wood M J. Outdoor field evaluation of passive tritiated water vapor samplers at Canadian power reactor sites[J]. Health Physics, 1996, 70(2):258-267. [14] 杨海兰,温雪莲,吴斌.被动式氚取样器性能的实验研究[J].辐射防护通讯, 2001, 21(02):18-23. [15] 杨海兰,温雪莲,吴斌,等.被动式氚取样器性能的实验研究[J].核电子学与探测技术, 2002, 22(06):545-548. [16] 杨怀元. 低水平氚测量进展概况[J]. 辐射防护通讯, 1983, 03:12-18. [17] Iida T, Yokoyama S, Fukuda H, et al. A sample passive method of collecting water-vapor for environmental tritium monitoring[J]. Radiation Protection Dosimetry, 1995, 58(1):23-27. [18] 胡宏杰,赵恒勤,王立卓,等.沸石分子筛的制备及应用[J].矿产保护与利用, 1998, 05:12-15. [19] 段林海.沸石分子筛的吸附扩散及应用[D].兰州:兰州大学化学化工学院, 2006. [20] 任天山,赵秋芬,陈炳如,等.中国环境水氚浓度及其变化[J]. 中华放射医学与防护杂志, 2001, 21(05):68-74. [21] Akata N, Kakiuchi H, Kanno K, et al. Determination of the atmospheric HTO concentration around the nuclear fuel reprocessing plant in Rokkasho by using a passive type sampler[J]. Fusion Science and Technology, 2011, 60(4):1292-1295. [22] Tuduri L, Harner T, Hung H. Polyurethane foam (PUF) disks passive air samplers: Wind effect on sampling rates[J]. Environmental pollution, 2006, 144(2):377-383. [23] Guo H L, Lin H M, Zhang W, et al. Influence of meteorological factors on the atmospheric mercury measurement by a novel passive sampler[J]. Atmospheric environment, 2014, 97(SI):310-315. [24] Plaisance H, Plechocki-Minguy A, Garcia-Fouque S, et al. Influence of meteorological factors on the NO2 measurements by passive diffusion tube[J]. Atmospheric environment, 2004, 38(4):573-580. [25] 尹洪银,邵华,高希宝.气体被动式采样器的研究进展[J].中国卫生检验杂志, 2007,17(3):569-571. [26] 崔九思.扩散法被动式个体采样器的设计原理、试验装置和性能评价方法[J].卫生研究, 1994, 23(S1):1-12. [27] 马晓,唐泉,刘永辉,等.滤膜对α-放射性气溶胶取样性能研究[J].核电子学与探测技术, 2012, 23(01):116-119.
