张慧芳, 刘红艳, 任越, 李幼忱, 王仲文. 基于钚内照射剂量重建的尿钚分析方法[J]. 中国辐射卫生, 2019, 28(4): 469-472.
ZHANG Huifang, LIU Hongyan, REN Yue, LI Youchen, WANG Zhongwen. Analytical methods of plutonium in urine based on the internal dose reconstruction. , 2019, 28(4): 469-472.
[1] 朱寿彭.放射毒理学[M].北京:原子能出版社,1983:157. [2] 姜圣阶.核燃料后处理工学[M].北京:原子能出版社,1995:1. [3] 朱寿彭.放射毒理学[M].北京:原子能出版社,1983:157-160. [4] 夏益华.高等电离辐射防护教程[M].哈尔滨:哈尔滨工程大学出版社,2010. [5] 朱寿彭.放射毒理学[M].北京:原子能出版社,1983:172-173. [6] Centers for Disease Control and Prevention. NIOSH study Hanford site. Atlanta, GA:CDC; ORAUT-TKBS-0006-5; 2015. https://www.cdc.gov/niosh/ocas/pdfs/tbd/hanford5-r6.pdf. [7] Khokhryakov V. V., Khokhryakov V. F., Suslova K. G.,et al. Mayak worker dosimetry system (MWDS-2008):Assessment of internal dose from measurement results of plutonium activity in urine[J]. Health Phys,104(4):366-378. [8] 中华人民共和国核工部部标准. EJ 274-19887尿中钚的分析方法[S].北京:中国标准出版社,1987. [9] Maxwell S L Ⅲ, Culligan B K. New column separation method for emergency urine samples[J]. J Radioanal Nucl Chem, 2009, 279(1):105-111. [10] Maxwell S L Ⅲ, Culligan B K. Rapid separation method for emergency water and urine samples[J]. J Radioanal Nucl Chem, 2009, 279(3):901-907. [11] Maxwell S L Ⅲ. Rapid analysis of emergency urine and water samples[J]. J Radioanal Nucl Chem, 2008, 275(3):497-502. [12] 宋建刚,张荣德,杨艳.尿钚快速测定的优化设计[J].辐射防护,2008,28(1),57-60. [13] 李烨,谭昭怡,田俊华,等.尿中钚的分析及内照射剂量估算,2014年全国核与辐射设施退役学术交流会议论文,491-495. [14] Moorthy A R, Schopfer C J, Banerjee S. Plutonium from atmospheric weapons testing:fission track analysis of urine samples[J]. Anal Chem, 1988, 60(14):857A-860A. [15] 赵淑权,孙连陞.尿钚裂变径迹分析方法与马绍尔居民钚-239内照射剂量估算[J].中华放射医学与防护杂志1995,15(4),237-242. [16] Maxwell S L Ⅲ, Jones V D. Rapid determination of actinides in urine by inductively coupled plasma mass spectrometry and alpha spectrometry:A hybrid approach[J]. Talanta, 2009, 80(1):143-150. [17] Vostrotin V V, Fell T P, Smith T J, et al. Retrospective estimation of Plutonium-239 doses from transfer to the fetus for Mayak PA workers[J]. International Journal of Radiation Biology, 2014, 90(11):1036-1042. [18] Hamilton T, Brown T, Hickman D, et al. Low-level plutonium bioassay measurements at the Lawrence Livermore national laboratory[R]. Office of Scientific and Technical Information (OSTI), 2007. DOI:10.2172/957611. [19] Elliot N L, Bickel G A, Linauskas S H, et al. Determination of femtogram quantities of 239Pu and 240Pu in bioassay samples by thermal ionization mass spectrometry[J]. J Radioanal Nucl Chem, 2006, 267(3):637-650. [20] LaMont S P, Shick C R, Cable-Dunlap P, et al. Plutonium determination in bioassay samples using radiochemical thermal ionization mass spectrometry[J]. J Radioanal Nucl Chem, 2005, 263(2):477-481. [21] Wacker L, Chamizo E, Fifield L K, et al. Measurement of actinides on a compact AMS system working at 300kV[J]. Nuclear Instruments and Methods in Physics Research Section B:Beam Interactions with Materials and Atoms, 2005, 240(1/2):452-457. [22] Vockenhuber C, Alfimov V, Christl M, et al. The potential of He stripping in heavy ion AMS[J]. Nuclear Instruments and Methods in Physics Research Section B:Beam Interactions with Materials and Atoms, 2013, 294:382-386. [23] Dai X X, Christl M, Kramer-Tremblay S, et al. Ultra-trace determination of plutonium in urine samples using a compact accelerator mass spectrometry system operating at 300 kV[J]. J Anal At Spectrom, 2012, 27(1):126-130. [24] Mendoza H. H, Chamizo E., Delgado A., et al. Reassessment of 239Pu on planchets from human urine samples at ultra-trace levels using aridus-ICP-SFMS and AMS[J]. Radiat. Prot. Dosim., 2012, 152(4), 296-303.