有机溴化物的溴同位素测试技术及其生物地球化学指示意义

doi:10.11867/j.issn.1001-8166.2011.08.0811

有机溴化物已成为继有机氯化物之后又一值得关注的全球性新兴持久性有机污染物。稳定Br同位素测试技术的快速发展，为有机溴化物生物地球化学循环研究提供了更为有效的技术支撑。在综述稳定Br同位素研究进展的基础上认为：①基于GC-MC-ICPMS技术基础上的有机单体Br同位素（CSIA-OBr）是Br同位素研究的主要趋势，难点是Br同位素数据的校正；②相对于C、H同位素，CSIA-OBr在指示有机溴化物的来源、传输途径、生物降解过程等方面提供更直接的信息，难点是微生物作用下稳定Br同位素的分馏机理研究；③C、H、Br多同位素的同时测定技术及指示意义研究显示出广阔的发展和应用前景。

关键词: 有机溴化物, 稳定Br同位素, GC-MC-ICPMS技术, 生物地球化学

Brominated Organic Compounds (BOCs) have become emerging global persistent organic pollutants and attract the most attention following chlorinated organic compounds. The rapid development of analytical methods for bromine isotope makes it possible and effective for further research on biogeochemical cycle of BOCs in the environment. Based on the overview of studies of bromine stable isotope (⁸¹Br) of BOCs, we think that: ①Compound-Specific Isotope Analysis of organobromine compound (CSIA-OBr) based on the technique of gas chromatography/ multicollector inductively coupled plasma mass spectrometry (GC-MC-ICPMS) is the main trend of studies of bromine isotope, and its difficulty is the correction of bromine isotope data; ②Compared with C and H isotopes, CSIA-OBr provides more direct information for identification of BOCs sources, transmission and biodegradation, and its difficulty is the fractionation mechanism of bromine isotope by microorganisms; ③Simultaneous determination for multiisotopes of C, H and Br and studies of significances of these three isotopes reveal a bright future for their development and application.

Key words: Brominated organic compounds, Bromine stable isotope, GC-MC-ICPMS, Biogeochemical cycle

中图分类号:

P574.2

[1]Emsley J. Nature′s Building Blocks: An A-Z Guide to the Elements[M]. Oxford: Oxford University Press, 2001.
[2]Б.Я.Роэен. ГЕОХИМИЯ БРОМА И ЙОДА [M]. Beijing: Geology Publishing House,1970.[Б.Я.罗津.溴和碘的地球化学[M]. 北京: 地质出版社,1970.]
[3]Mou Baolei. Geochemistry of the Elements[M]. Beijing: Beijing University Press, 1999.[牟保磊.元素地球化学[M]. 北京: 北京大学出版社,1999.]
[4]Liu Ling, Ma Teng, Liu Cunfu, et al. Novel analytical methods of bromine stable isotope (⁸¹Br) and its application in hydrogeology[J].Geological Science and Technology Information,2010, 29(3): 104-109.[刘玲, 马腾, 刘存富, 等. 稳定Br同位素(⁸¹Br)测试新技术与其在水文地质中的应用前景[J].地质科技情报, 2010, 29 (3): 104-109.]
[5]Zeng Zhaohua, Zeng Xueping. The formation of trace element of Br in groundwater and its relationship with the health of people′s community
[J].Jilin Geology,2001,20(1):57-60.[曾昭华, 曾雪萍. 地下水中溴的形成及其与人群健康的关系[J]. 吉林地质, 2001, 20 (1): 57-60.]
[6]Greenwood N N, Earnshaw A. Chemistry of the Elements[M]. Boston: Butterworth-Heinemann, 1997.
[7]Xu Siqi. Distribution, Source and Environmental Significance of Iodine and Bromine Species in Atmospheric Aerosol[D]. Hefei: University of Science and Technology of China, 2010.[徐思琦. 大气气溶胶中碘、溴的形态分布、来源及其环境意义[D]. 合肥: 中国科学技术大学, 2010.]
[8]Sander R, Keene W C, Pszenny A A P, et al. Inorganic bromine in the marine boundary layer: A critical review [J].Atmospheric Chemistry and Physics,2003, 3: 1 301-1 336.
[9]Chen Liqiao, Wei Fusheng. The background value levels of Bromine and londinc in China soils[J].Arid Environmental Monitoring,1991, 5(2): 65-70.[陈立乔, 魏复盛. 中国土壤中溴、碘的背景含量[J]. 干旱环境监测, 1991, 5(2): 65-70.]
[10]Harper D B. Halomethane from halide ion: A highly efficient fungal conversion of environmental significance[J].Nature,1985, 315: 55-57.
[11] Gribble G W. The diversity of naturally occurring organobromine compounds[J]. Chemical Society Reviews,1999, 28(5): 335-346.
[12]Fan X, Xu N J, Shi J G. Bromophenols from the red alga Rhodomela confervoides[J]. Journal of Natural Products,2003, 66(3): 455-458.
[13]Yin Yongguang, Liu Jingfu, Jiang Guibin. Naturally occurring organobromine compounds in marine with environmental concern [J]. Progress in Chemistry,2011, 23(1): 254-260.[阴永光, 刘景富, 江桂斌. 海洋环境中的天然溴代有机物[J]. 化学进展, 2011, 23(1): 254-260.]
[14]Haglund P S, Zook D R, Buser H R,et al. Identification and quantification of Polybrominated Dephenyl Ethers and methoxypolybrominated diphenyl ethers in Baltic biota [J].Environmental Science & Technology,1997, 31(11): 3 281-3 287.
[15]Fu X, Schmitz F J, Govindan M,et al. Enzyme inhibitors: New and known polybrominated phenols and diphenyl ethers from four Indo-Pacific dysidea sponges[J].Journal of Natural Products,1995, 58(9): 1 384-1 391.
[16]Cameron G M, Stapleton B L, Simonsen S M, et al. New sesquiterpene and brominated metabolites from the tropical marine sponge dysidea sp[J]. Tetrahedron,2000, 56(29): 5 247-5 252.
[17]Marsh G, Athanasiadou M, Athanassiadis I, et al. Identification, quantification, and synthesis of a novel dimethoxylated polybrominated biphenyl in marine mammals caught off the coast of Japan[J]. Environmental Science & Technology, 2005, 39 (22): 8 684-8 690.
[18]Teuten E L, Reddy C M. Halogenated organic compounds in archived whale oil: A preindustrial record [J].Environmental Pollution,2007, 145 (3): 668-671.
[19]Vetter W, Turek C, Marsh G, et al. Identification and quantification of new PolyBrominated DiMethoxy-Biphenyls (PBDMBs) in marine mammals from Australia[J]. Chemosphere,2008, 73 (4): 580-586.
[20]Utkina N K, Denisenko V A, Scholokova O V, et al. Spongiadioxins A and B, two new polybrominated dibenzo-p-dioxins from an Australian marine sponge Dysidea dendyi[J]. Journal of Natural Products,2001, 64 (2): 151-153.
[21]Utkina N K, Denisenko V A, Virovaya M V, et al. Two new minor polybrominated dibenzo-p-dioxins from the marine sponge Dysidea dendyi[J].Journal of Natural Products, 2002, 65 (8): 1 213-1 215.
[22]Zheng Hua, Liang Chongshan. Progress of brominated organic pollutants and bromine stable isotope[C]∥Environment Science Association of China ed. Annual Meeting Proceedings of China Environmental Science Society. Beijing: China Environmental Science Press,2010: 4 240-4 242.[郑华，梁重山. 有机溴化物及稳定Br同位素研究进展[C]∥中国环境科学学会编.中国环境科学学会学术年会论文集.北京：中国环境科学出版社，2010：4 240-4 242.]
[23]Ou Yuxiang, Xu Dongmei. Development of brominated flame retardants in international environmental protection legislations[J]. Plastics Additives,2009,(1):13-20.[欧育湘,许冬梅. 国际环保法规中的溴系阻燃剂动态[J]. 塑料助剂, 2009,(1): 13-20.]
[24]Wei Aixue, Wang Xuetong, Xu Xiaobai. The pollution research aspect on Poly-Brominated Diphenyl Esters (PBDEs) compounds in environment[J]. Progress in Chemistry,2006,18(9):1 227-1 233.[魏爱雪,王学彤,徐晓白. 环境中多溴联苯醚类(PBDEs)化合物污染研究[J].化学进展, 2006, 18(9): 1 227-1 233.]
[25]Adriaens P, Gruden C, McCormick M L. Biogeochemistry of Halogenated Hydrocarbons[M]. Amsterdam: Elsevier, 2003.
[26]Watanabe I, Sakai S. Environmental release and behavior of brominated flame retardants[J]. Environment International, 2003, 29 (6): 665-682.
[27]Wania F, Mackay D. Tracking the distribution of persistent organic pollutants[J]. Environmental Science & Technology,1996, 30(9): A390-A396.
[28]Alaee M, Luross J M, Sergeant D B, et al. Distribution of Polybrominated Dephenyl Ethers in the Canadian environment[J]. Organohalogen Compounds,1999, 40: 347-350.
[29]Oros D R, Hoover D, Rodigari F, et al. Levels and distribution of Polybrominated Dephenyl Ethers in water, surface sediments, and bivalves from the San Francisco Estuary [J]. Environmental Science & Technology,2005, 39(1): 33-41.
[30]Wurl O, Obbard J P, Lam P K S. Distribution of organochlorines in the dissolved and suspended phase of the sea-surface microlayer and seawater in Hong Kong, China[J]. Marine Pollution Bulletin, 2006, 52(7): 768-777.
[31]Luo X J, Yu M, Mai B X, et al. Distribution and partition of Polybrominated Diphenyl Ethers(PBDEs) in water of the Zhujiang River Estuary[J]. Chinese Science Bulletin,2008, 53(4): 493-500.
[32]Hayakawa K, Takatsuki H, Watanabe I,et al. PolyBrominated Diphenyl Ethers(PBDEs), Polybrominated Debenzo-p-Dioxins/dibenzofurans (PBDD/Fs) and Monobromopolychlorinated Dibenzo-p-Dioxins/dibenzofurans (MoBPXDD/Fs) in the atmosphere and bulk deposition in Kyoto, Japan[J].Chemosphere,2004, 57(5): 343-356.

[33]Luo Xiaojun, Mai Bixian, Chen Shejun. Advances on study of polybrominated diphenyl ethers[J].Progress in Chemistry,2009, 21(2/3): 359-368.[罗孝俊, 麦碧娴, 陈社军. PBDEs研究最新进展[J]. 化学进展, 2009, 21 (2/3): 359-368.]

[34]Hassanin A, Breivik K, Meijer S N, et al. PBDEs in European background soils: Levels and factors controlling their distribution[J].Environmental Science & Technology, 2004, 38 (3): 738-745.

[35]Zou M Y, Ran Y, Gong J, et al. Polybrominated Dephenyl Ethers in watershed soils of the Pearl River Delta, China: Occurence, inventory, and fate[J]. Environmental Science & Technology,2010, 41: 8 262-8 267.

[36]Liu H, Zhou O, Wang Y,et al. E-waste recycling induced Polybrominated Dephenyl Ethers, polybrominated biphenyls, polychlorinated dibenzo-p-dioxins and dibenzofurans pollution in the ambien environment[J]. Environmental International,2008, 34: 67-72.

[37]Nam J J, Gustafsson O, Kurt-Karakus P,et al. Relationships between organic matter, black carbon and persistent organic pollutants in European background soils: Implications for sources and environmental fate [J]. Environment Pollution,2008, 156: 809-817.

[38]DeBoer J, Wester P G, Klammer H J C,et al. Do flame retardants threaten ocean life? [J]. Nature,1998, 394: 28-29.

[39]Chiuchiolo A L, Dickhut R M, Cochran M A,et al. Persistent organic pollutants at the base of the Antarctic marine food web[J].Environmental Science & Technology,2004, 38 (13): 3 551-3 557.

[40]Dewit C A, Alaee M, Muir D C G. Levels and trends of brominated flame retardants in the Arctic[J].Chemosphere, 2006, 64: 209-233.

[41]Yogui G T,Sericano J L. Polybrominated Dephenyl Ether flame retardants in the US marine environment: A review[J].Environmental International,2009, 35 (3): 655-666.

[42]Unger M. Identification of Brominated Organic in Aquatic Biota and Exploration of Bromine Isotope Analysis for Source[D]. Stockholm: Stockholm University, 2010.

[43]Rosman K J R, Taylor P D P. Isotopic compositions of the elements 1997[J].Journal of Physical and Chemical Reference Data,1998, 27(6): 1 275-1 287.

[44]Broecker W S, Peng T H. Tracers in the Sea[M]. New York: Eldigio Press, 1982. 

[45]Brownlow A H. Geochemistry[M]. New Jersy: Prentice Hall, 1986. 

[46]Unson M D, Holland N D, Faulkner D J. A brominated secondary metabolite synthesized by the cyanobacterial symbiont of a marine sponge and accumulation of the crystalline metabolite in the sponge tissue[J].Marine Biology,1994, 119(1): 1-11.

[47]Blewett J P. Mass spectrograph analysis of bromine[J].Physical Review, 1936, 49: 900-903.

[48]Williams D, Yuster P. Isotopic constitution of tellurium, silicon, tungsten, molybdenum, and bromine[J].Physical Review,1946, 69: 556-567.

[49]Cameron A E, Lippert E L. Isotope composition of bromine in nature[J].Science,1955, 121: 136-137.

[50]Cameron A E, Herr W, Herzog W,et al. IsotopenAnreicherung beim Brom durch electrolytische berführung in geschmolzenem Bleibromid[J].Zeitschrift für Naturforschung,1956, 11a: 136-137.
[51]Catzanzaro E J, Murrphy T J, Garner E L,et al. Absolute isotopic abundance ratio and the atomic weight of bromine[J].Journal of Rearch of the National Bureau of Standards:U.S,1964, 68: 593-599.

[52]Willey J F, Taylor J W. Capacitive integration to produce high precision isotope ratio measurement on methyl chloride and bromide[J].Analytical Chemistry,1978, 50: 1 930-1 933.

[53]Xiao Y K, Liu W G, Qi H P, et al. A new method for the highprecision isotopic measurement of bromine by thermal ionization massspectrometry[J].International Journal of Mass Spectrometry and Ion Processes,1993, 123(2): 117-123.

[54]Eggenkamp H G M,Coleman M L. Rediscovery of classical methods and their application to the measurement of stable bromine isotopes in natural samples[J].Chemical Geology, 2000, 167(3/4): 393-402.

[55]Shouakar-Stash O, Frape S K, Drimmie R J. Determination of bromine stable isotopes using continuous flow isotope ratio mass spectrometry[J].Analytical Chemistry,2005, 77(13): 4 027-4 033.
[56]Shouakar-Stash O, Frape S K, Rostron B J, et al. Variations of the ⁸¹Br and ³⁷Cl stable isotope signature for preMississippian formation waters of the Williston Basin[J]. Geochimica et Cosmochimica Acta, 2006, 70 (18S): A589.

[57]ShouakarStash O, Frape S K, Rostron B J, et al. Natural distribution of ⁸¹Br in formation waters in sedimentary and crystalline environments[J]. Abstracts with Programs Geological Society of America, 2007, 39 (6): 115.

[58]Shouakar-Stash O, Frape S K, Hobbs M Y, et al. Origin and evolution of waters from Paleozoic formations, southern Ontario, Canada; additional evidence from ³⁷Cl and delta ⁸¹Br isotopic signatures[J]. Proceedings International Symposium on Water-Rock Interaction, 2007, 1(12): 537-541.

[59]Shouakar-Stash O, Alexeev S V, Frape S K, et al. Geochemistry and stable isotopic signatures, including chlorine and bromine isotopes, of the deep groundwaters of the Siberian Platform, Russia[J].Applied Geochemistry,2007,22(3):589-605.

[60]Shouakar Stash O. Evaluation of Stable Chlorine and Bromine Isotopes in Sedimentary Formation Fluids[D]. Waterloo,Canada: University of Waterloo, 2008.

[61]Fan Qishun, Ma Haizhou, Tan Hongbing, et al. Characteristics and origin of brines in western Qaidam Basin [J]. Geochimica,2007,36(6): 601-611.[樊启顺, 马海洲, 谭红兵, 等. 柴达木盆地西部卤水特征及成因探讨[J]. 地球化学, 2007, 36(6): 601-611.]

[62]Ma Wandong, Ma Haizhou. Geochemical characteristics on brine and potash perspective in the western Tarim Basin[J].Acta Sedimentologica Sinica,2006,24(1): 96-106.[马万栋,马海州. 塔里木盆地西部卤水地球化学特征及成钾远景预测[J]. 沉积学报, 2006, 24(1): 96-106.]

[63]Lin Yaoting, Chen Shaolan. Exploration and development prospect of underground brine in Sichuan Basin[J]. Journal of Saltlake Research,2008, 16(1): 1-21.[林耀庭,陈绍兰. 四川盆地地下卤水勘探开发前景展望[J]. 盐湖研究, 2008, 16(1):1-21.]

[64]Zhang Cuiyun. Origin and evolution of underground brine in coastal plain of Laizhou Bay[C] ∥Bulletin of Institute of Hydrogeology and Engineering Geology CAGS.Beijing:Geological Publishing House,1993: 73-91.[张翠云. 莱州湾滨海平原地下卤水的形成及其演化[C] ∥中国地质科学院水文地质工程地质研究所所刊.北京：地质出版社, 1993: 73-91.]

[65]Sylva S P, Ball L, Nelson R K, et al. Compound-specific ⁸¹Br/ ⁷⁹Br analysis by capillary gas chromatography/multicollector inductively coupled plasma mass spectrometry[J]. Rapid Communications in Mass Spectrometry,2007, 21 (20): 3 301-3 305.

[66]Van Acker M R, Shahar A, Young E D, et al. GC/multiple collector ICPMS method for chlorine stable isotope analysis of chlorinated aliphatic hydrocarbons [J]. Analytical Chemistry,2006, 78(13): 4 663-4 667.

[67]Gelman F, Halicz L. High precision determination of bromine isotope ratio by GC-MC-ICPMS[J]. International Journal of Mass Spectrometry, 2010, 289(2/3): 167-169.

[68]Jensen S, Reutergardh L, Jansson B. Analytical methods for measuring organochlorines and methyl mercury by gas chromatography[C] ∥FAO/SIDA Manual of Methods in Aquatic Envioment Research. Part 9. Analysis of Metals and Organochlorines in Fish. FAO Fish Technology Paper 212:21-333,1983.

[69]Jensen S, Athanasiadou M, Bergman .A technique for separation of xenobiotics from large amounts of lipids [J]. Organohalogen Coumpounds,1992, 8: 79-80.

[70]Braitsch O. Entstehung und Stoffbestand der Salzlagerstätten[M]. Berlin: Springer-Verlag,1962. 

[71]Ericksen G E. Geology and Origin of the Chilean Nitrate Deposits[M].Washington: USGS Professional Paper, 1981: 1-37.

[72]ShouakarStash O, Frape S K, Rostron B J, et al. Variations of the ⁸¹ Br and ³⁷Cl stable isotope signature for Mississippian to Cambrian formation brines of the Williston Basin[J]. Abstracts with Programs-Geological Society of America,2006, 38(7): 465.

[73]Shouakar-Stash O, Alexeev S V, Frape S K, et al. Geochemistry and stable isotopic signatures, including chlorine and bromine isotopes, of the deep groundwaters of the Siberian Platform, Russia[J]. Applied Geochemistry,2007, 22(3): 589-605.

[74]Frape S K, ShouakarStash O, Paces T, et al. Geochemical and isotopic characteristics of the waters from crystalline and sedimentary structures of the Bohemian Massif[C] ∥Bullen T D, Wang Y, eds. Water Rock Interaction. Kunming, China: Taylor ＆ Francis,2007: 727-733.

[75]Cheng Huaide, Ma Haizhou, Tan Hongbing, et al. Geochemical characteristics of bromide in potassium deposits: Review and research perspectives[J]. Bulletin of Mineralogy, Petrology and Geochemistry,2008, 27(4): 399-408.[程怀德, 马海州, 谭红兵, 等. 钾盐矿床中Br的地球化学特征及研究进展[J]. 矿物岩石地球化学通报, 2008, 27(4): 399-408.]

[76]Gilfedder B S, Petri M,Biester H. Iodine and bromine speciation in snow and the effect of orographically induced precipitation[J]. Atmospheric Chemistry and Physics,2007, 7(10): 2 661-2 669.

[77]Wurl O, Lam P K S,Obbard J P. Occurrence and distribution of PolyBrominated Diphenyl Ethers (PBDEs) in the dissolved and suspended phases of the sea-surface microlayer and seawater in Hong Kong, China[J]. Chemosphere,2006, 65(9): 1 660-1 666.

[78]Leung A O, Luksemburg W J, Wong A S, et al. Spatial distribution of Polybrominated Dephenyl Ethers and polychlorinated dibenzo-p-dioxins and dibenzofurans in soil and combusted residue at Guiyu, an electronic waste recycling in southeast China[J]. Environmental Science & Technology, 2007, 41: 2 730-2 737.

[79]Zhou Bing, Qiu Yanling. Polybrominated Dephenyl Ethers and its environmental behavior[J].Environmental Science & Technology,2008, 31 (5): 57-61.[周冰,仇雁翎. 多溴联苯醚及其环境行为[J]. 环境科学与技术, 2008, 31(5): 57-61.]

[80]Wania F. Assessing the potential of persistent organic chemicals for long-range transport and accumulation in polar regions[J]. Environmental Science & Technology,2003, 37(7): 1 344-1 351.

[81]Palm A, Cousins I T, Mackay D, et al. Assessing the environmental fate of chemicals of emerging concern: A case study of the polybrominated diphenyl ethers[J]. Environmental Pollution,2002, 117(2): 195-213.

[82]Meng Fanping, Li Zhuona. Research progress on the behavior of PolyBrominated Diphenyl Ethers (PBDEs) in marine environment[J].Periodical of Ocean University of China,2009, 39(2): 285-289.[孟范平,李卓娜. 多溴联苯醚(PBDEs)在海洋环境中的行为研究进展[J].中国海洋大学学报:自然科学版, 2009,32(2): 285-289.]

[83]Ueno D, Kajiwara N, Tanaka H, et al. Global pollution monitoring of Polybrominated Dephenyl Ethers using skipjack tuna as a bioindicator[J]. Environmental Science & Technology,2004, 38 (8): 2 312-2 316.

[84]Kajiwara N, Kamikawa S, Ramu K, et al. Geographical distribution of PolyBrominated Diphenyl Ethers (PBDEs) and organochlorines in small cetaceans from Asian waters[J]. Chemosphere, 2006, 64 (2): 287-295.

[85]Haglund P S, Zook D R, Buser H R, et al. Identification and quantification of Polybrominated Dephenyl Ethers and methoxyPolybrominated Dephenyl Ethers in Baltic biota[J]. Environmental Science & Technology, 1997, 31 (11): 3 281-3 287.

[86]Choi J W,Fujimaki T S, Kitamura K, et al. Polybrominated dibenzo-p-dioxins, dibenzofurans, and Diphenyl Ethers in Japanese human adipose tissue[J]. Environmental Science & Technology,2003, 37(5): 817-821.

[87]Meironyté Guvenius D, Bergman Å,Norén K. Polybrominated Dephenyl Ethers in Swedish Human Liver and Adipose Tissue[J]. Archives of Environmental Contamination and Toxicology, 2001, 40(4): 564-570.

[88]Betts K S. Rapidly rising PBDE levels in North America[J]. Environmental Science & Technology,2002, 36 (3): 50-52.

[89]Tang Zhenwu, Yue Yong, Xu Qigong. Pollutions and risks of Polybrominated Dephenyl Ethers in aquatic environment[J]. Advances in Earth Science,2009, 24(2): 204-210.[唐阵武, 岳勇,许其功. 水体中多溴联苯醚污染及其生态风险[J]. 地球科学进展, 2009, 24(2): 204-210.]

[90]Palm A, Cousins I T, Mackay D, et al. Assessing the environmental fate of chemicals of emerging concern: A case study of the Polybrominated Dephenyl Ethers[J]. Environmental Pollution,2002, 117: 195-213.

[91]Darnerud P O, Wong J, Bergman A, et al. Common viral infection affects PentaBrominated Diphenyl Ether (PBDE) distribution and metabolic and hormonal activities in mice[J]. Toxicology,2005, 210(2/3): 159-167.

[92]Ohta S, Ishizuka D, Nishimura H,et al. Comparison of polybrominated diphenyl ethers in fish, vegetables, and meats and levels in human milk of nursing women in Japan[J]. Chemosphere,2002, 46(5):689-696.

[93]Hassanin A, Johnston A E, Thomas G O, et al. Time trends of atmospheric PBDEs inferred from archived UK herbage[J]. Environmental Science & Technology, 2005, 39 (8): 2 436-2 441.

[94]Zhang Xian, Gao Yajie, Yan Changzhou. Advance in research on the transport and transformation of polybrominated diphenyl ethers in environment[J]. Ecology and Environmental Sciences,2009, 18(2): 761-770. [张娴，高亚杰，颜昌宙. 多溴联苯醚在环境中迁移转化的研究进展[J] 生态环境学报, 2009,18(2): 761-770.]

[95]Zwank L, Berg M, Elsner M, et al. New evaluation scheme for two-dimensional isotope analysis to decipher biodegradation processes: Application to groundwater contamination by MTBE[J].Environmental Science & Technology,2005, 39(4): 1 018-1 029.

[96]Li Xianguo, Peng Xuewei, Zhang Qinghong. Application of compound-specific isotope analysis in organic pollutants research[J]. Periodical of Ocean University of China, 2009, 39(6): 1 251-1 256.[李先国, 彭学伟, 张庆红. 单体同位素分析在有机污染物研究中的应用[J]. 中国海洋大学学报, 2009, 39(6): 1 251-1 256.]

[97]O′Malley V P, Abrajano T A, Hellou J. Stable carbon isotopic apportionment of individual polycyclic aromatic hydrocarbons in St. John′s Harbour, Newfoundland[J]. Environmental Science & Technology1996, 30 (2): 634-639.

[98]Okuda T, Kumata H, Naraoka H, et al. Vertical distributions and ¹³C isotopic compositions of PAHs in Chidorigafuchi Moat sediment, Japan[J]. Organic Geochemistry, 2002, 33(7): 843-848.

[99]Okuda T, Kumata H, Naraoka H, et al. Origin of atmospheric Polycyclic Aromatic Hydrocarbons (PAHs) in Chinese cities solved by compoundspecific stable carbon isotopic analyses[J]. Organic Geochemistry, 2002,33 (12): 1 737-1 745.

[100]Zhang Lin, Zhang Yongtao, Liu Jun, et al. Status of compound-specific isotope analysis in contaminated groundwater studies[J]. Geological Science and Technology Information,2009,28(5): 125-130.[张琳, 张永涛, 刘君, 等. 有机单体同位素分析技术在地下水污染中的研究现状[J].地质科技情报, 2009,28(5): 125-130.]

[101]Morasch B, Richnow H H, Schink B, et al. Stable hydrogen and carbon isotope fractionation during microbial toluene degradation: Mechanistic and environmental aspects[J]. Applied and Environmental Microbiology,2001, 67(10): 4 842-4 849.

[102]Mancini S A, Ulrich A C, Lacrampe-Couloume G, et al. Carbon and hydrogen isotopic fractionation during anaerobic biodegradation of benzene[J]. Applied and Environmental Microbiology,2003, 69(1): 191-198.

[1]	夏群科,陈道公,支霞臣. 名义上无水的地幔矿物中结构水的研究进展[J]. 地球科学进展, 1999, 14(5): 452-457.

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An Overview of Analytical Methods of Bromine Stable Isotope ( 81Br) of BOCs and Its Significance to Biogeochemical Cycle

An Overview of Analytical Methods of Bromine Stable Isotope ( ⁸¹Br) of BOCs and Its Significance to Biogeochemical Cycle