贵阳地表水—地下水的硫和氯同位素组成特征及其污染物示踪意义

doi:10.11867/j.issn.1001-8166.2008.02.0151

喀斯特地表水和地下水的交换活跃，地下水系统容易受到地表污染物的污染。为了解喀斯特城市地表水—地下水系统污染特征和污染物质来源，对贵阳市地表水、地下水、雨水和城市排污污水的硫同位素和氯同位素组成变化进行了研究。贵阳市不同类型水体的δ³⁷Cl值在-4.07‰～+2.03‰之间变化，δ³⁴SO₄值变化为-20.4‰～+20.9‰。大气输入物质和城市排污污水的δ³⁷Cl、δ³⁴S及Cl^-/SO₄^2-比值与地表水和地下水的不同，稳定硫和氯同位素的结合研究为示踪地下水污染物来源提供了有效研究手段。贵阳市地下水中的Cl^-和SO^₄2-至少有4种来源，人为活动通过城市排污和大气输入向地下水系统大量输入了硫酸盐和氯离子。 

关键词: 喀斯特, 地表水—地下水, 氯同位素, 硫同位素, 污染

Due to active exchange between surface water and ground water in a karstic hydrological system, we carried out a study of δ³⁷Cl and δ³⁴S variations of chloride and sulfate ions in the karstic surface/ground water system of Guiyang city, southwestern China, with the main purpose to understand ground water environmental pollution and the sources of the contaminants. The surface, ground, rain and waste water show variable δ³⁷Cland δ³⁴S values, with δ³⁷Cl values varying between -4.07‰ and +2.03‰, and δ³⁴S values between -20.4‰ and +20.9‰。The studied atmospheric and anthropogenic inputs have specific range of δ³⁷Cl and δ³⁴S values, which can provide an effective isotopic method for tracing contaminants in a ground water system. We conclude that at least four sources exist to account for the variations of δ³⁷Cl and δ³⁴S values of chloride and sulfate ions in the ground water system, and that human activities have inputted a significant amount of sulfate and chloride ions, as well as other contaminants into the studied ground water system through atmospheric emission and municipal sewage.

Key words: Karst, Surface water/ground water, Cl isotope, S isotope, Contamination.

中图分类号:

P592
X142

[1] Liu Congqiang，Li Siliang，Lang Yunchao，et al. Using δ¹⁵N-and δ¹⁸O-Values to identify nitrate sources in karst ground water，Guiyang，Southwest China [J]. Environmetal Science & Technology，2006，40（22）: 6 928-6 933.

[2] Lang Yunchao，Liu Congqiang，Zhao Zhiqi，et al. Geochemistry of surface and ground water in Guiyang City，China: Water/rock interaction and pollution in a karst hydrological system [J]. Applied Geochemistry，2006，21: 887-903.

[3] Li Siliang，Liu Congqiang，Tao Faxiang，et al.δ¹³C_DICas a tracer to monitor pollution and ecological changes in ground water [J].Ground Water，2005，43（4）: 494-499.

[4] Lang Yunchao，Liu Congqiang，Han Guilin，et al. Characterization of water-rock interaction and pollution of karstic hydrological system: A study on water chemistry and Sr isotope of surface/ground water of the Guiyang area [J]. Quaternary Sciences，2005a，25（5）: 655-662.[郎赟超，刘丛强，韩贵琳，等.喀斯特水文系统水—岩反应及污染特征: 贵阳市区地表/地下水化学与锶同位素研究[J]. 第四纪研究，2005a，25（5）: 655-662.]

[5] Lang Yunchao，Liu Congqiang，Zhao Zhiqi，et al. Chemical compositions of surface and ground waters of Guiyang city: Discussion of water-rock interaction and contamination in karstic hydrological system [J]. Advances in Water Science，2005b，16（6）: 826-832.[郎赟超，刘丛强，赵志琦，等. 贵阳市地表/地下水化学组成: 喀斯特水文系统水—岩反应及污染特征[J]. 水科学进展，2005b，16（6）: 826-832.]

[6] Li Siliang，Liu Congqiang，Xiao Huayun，et al. Using δ¹⁵N to assess groundwater nitrogen pollution in Guiyang [J]. Geochimica，2005，34（3）: 257-262.[李思亮，刘丛强，肖化云，等. δ¹⁵N在贵阳地下水氮污染来源和转化过程中的辨识应用[J].地球化学，2005，34（3）: 257-262.]

[7] Li Siliang，Liu Congqiang，Tao Faxiang，et al. Chemical and stable carbon isotopic compositions of the ground waters of Guiyang city， China: Implications for biogeochemical cycle of carbon and contamination [J]. Geochimica，2004，33（2）: 165-170.[李思亮，刘丛强，陶发祥，等. 碳同位素和水化学在示踪贵阳地下水碳的生物地球化学循环及污染中的应用[J]. 地球化学，2004，33（2）: 165-170.]

[8] Dowuona G N，Mermut A R，Krouse H R. Stable isotope geochemistry of sulfate in relation to hydrogeology in souther Saskatchewan，Canada [J]. Applied Geochemistry，1993，8: 255-263.

[9] Barth S R. Geochemical and boron，oxygen and hydrogen isotopic constraints on the origin of salinity in groundwaters from the crystalline basement of the Alpine Foreland [J]. Applied Geochemistry，2000，15: 937-952.

[10] Dogramaci S S，Herczeg A L，Schiff S L，et al. Control on δ³⁴S and δ¹⁸O of dissolved sulfate in aquifers of the Murray Basin，Australia and their use as indicators of flow processes [J]. Applied Geochemistry，2001，16: 475-488.

[11] Kirste D，Caritat P de，Dann R. The application of the stable isotopes of sulfur and oxygen in groundwater sulfate to mineral exploration in the Broken Hill region of Australia [J]. Journal of Geochemical exploration，2003，（78-79）:81-84.

[12] Kaufmann R S，Long A，Bentley H，et al. Natural chlorine isotope variations [J].Nature，1984， 309: 338-340.

[13] Kaufmann R S，Frape S K，MaNutt R，et al. Chlorine stable isotope distribution of Michigan Basin formation waters [J]. Applied Geochemistry，1993，8: 403-407.

[14] Xiao Yingkai，Liu Weiguo，Zhou Y M，et al. Isotopic compositions of chlorine in brine and saline minerals [J]. Chinese Science Bulletin，1997，42（5）: 406-409.

[15] Jendrzejewski N，Eggenkamp H G M，Coleman M L. Characterisation of chlorinated hydrocarbons from chlorine and carbon isotopic compositions: Scope of application to environmental problems [J]. Applied Geochemistry，2001，16: 1 021-1 031.

[16] Sie P M J，Frape S K. Evaluation of the groundwaters from the Stripa mine using stable chlorine isotopes [J]. Chemical Geology，2002，182: 565-582.

[17] Numata M，Nakamura N，Koshikawa H，et al. Chlorine stable isotope measurements of chlorinated aliphatic hydrocarbons by thermal ionization mass spectrometry [J]. Analytica Chimica Acta，2002，455: 1-9.

[18] Edmunds W M，Guendouz A H，Mamou A，et al. Groundwater evolution in the Continental Intercalaire aquifer of southern Algeria and Tunisia: Trace element and isotopic indicators [J]. Applied Geochemistry，2003，18: 805-822.

[19] Shouakar-Stash O，Frape S K，Drimmie R J. Stable hydrogen，carbon and chlorine isotope measurements of selected chlorinated organic solvents [J]. Contaminant Hydrology，2003，60: 211-228.

[20] Wu J H，Satake H. Measurement of Chlorine Stable Isotope Ratios by Methyl Chloride-IRMS method [J]. Geochemica et Cosmochimica Acta，2003，67（18S）: A537.

[21] Wu J H，Satake H. Purificaton of CH₃Cl from CH₃I using cold trap with sealed 2，2，4-trimethylpentanefor δ³⁷Cl measurement [J]. Analytica Chimica Acta，2006，555: 41-46.

[22] Zhao Yonggui，Cai Zuhuang. A Study of Karstic Ground Water System，Taiyuan，Shanxi，China [M]. Beijing: Science Press，1990:1-229.[赵永贵，蔡祖煌. 岩溶地下水系统的研究——以太原地区为例[M]. 北京: 科学出版社，1990: 1-229.]

[23] Macpherson G L. Hydrogeology of thin limestones-the Konza Prairie LTER Site [J]. Journal of Hydrology，1996，186: 191-228.

[24] Montoroi J P，Grünberger O，Nasri S. Groundwater geochemistry of a small reservoir catchment in Central Tunisia [J]. Applied Geochemistry，2002，17: 1 047-1 060.

[25] Han Guilin，Liu Congqiang. Water geochemistry controlled by carbonate dissolution: A study of the river waters draining karst-dominated terrain，Guizhou Province，China [J]. Chemistry Geology，2004，204: 1-21.

[26] Han Zhijun，Jin Zhansheng. Hydrology of Guizhou Province，China [M]. Beijing: Seismological Press，1996: 1-508.[韩至钧，金占省. 贵州省水文地质志[M]. 北京: 地震出版社，1996:1-508.]

[27] Ni Jianyu，Hong Yetang. Sulfur isotopic composition of late Permian coal from Guizhou province [J]. Geology-geochemistry，1999，27（2）:63-69.[倪建宇，洪业汤. 贵州晚二叠世煤中硫同位素的组成特征[J].地质地球化学，1999，27（2）:63-69.]

[28] Zheng Yongfei，Chen Jiangfeng. Stable Isotope Geochemistry [M]. Beijing: Science Press，2000: 1-316.[ 郑永飞，陈江峰. 稳定同位素地球化学[M]. 北京: 科学出版社，2000: 1-316.]

[29] Zhang Guoping，Liu Congqiang，Yang Yuangen，et al. Characterization of heavy metals and sulphur isotope in water and sediments of a mine-tailing area rich in carbonate [J]. Water Air and Soil Pollution，2004，155: 51-62.

[30] Hoefs J. Stable Isotope Geochemistry（ 5th edition） [M]. Berlin: Springer，2004: 1-340. 

[31] Sun Aide，Xiao Yingkai，Wang Qingzhong，et al. The separation and stable isotopic measurement of chlorine in low-concentration liquid sample [J]. Chinese Journal of Analytical Chemistry，2004，10（32）: 1 362-1 364.[孙爱德，肖应凯，王庆忠，等. 水样中低含量氯的分离与同位素质谱法测定[J]. 分析化学，2004，10（32）: 1 362-1 364.]

[32] Négrel P，Roy S. Chemistry of rainwater in the Massif Central （France）: A strontium isotope and major element study [J]. Applied Geochemistry，1998，13: 941-952.

[33] Li X D，Masuda H，Kusakabe M，et al. Sulfur and nitrogen pollution of ground water and those origins in the Sichuan Basin，China [C]∥52nd Annual Meeting of the Geochemical Society of Japan. Okinawa，2005.

[34] Liu Guangshen，Hong Yetang，Piao Hechun，et al. The sulfur isotopic compositional characteristics of atmospheric particulates from near the ground in the urban and suburban areas of guiyang city [J].Acta Mineralogical Sinica，1996，16（4）: 353-357.[ 刘广深，洪业汤，朴河春，等. 贵阳城郊近地面大气颗粒物的硫同位素组成特征[J]. 矿物学报，1996，16（4）: 353-357.

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摘要

δ 37Cl and δ 34S variations of Cl- and SO42- in Groundwater and Surface Water of Guiyang Area, China

δ ³⁷Cl and δ ³⁴S variations of Cl^- and SO₄^2- in Groundwater and Surface Water of Guiyang Area, China