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区域地下水演化的地球化学研究进展

滕彦国 左锐 王金生 林学钰

滕彦国, 左锐, 王金生, 林学钰. 区域地下水演化的地球化学研究进展[J]. 水科学进展, 2010, 21(1): 127-136.
引用本文: 滕彦国, 左锐, 王金生, 林学钰. 区域地下水演化的地球化学研究进展[J]. 水科学进展, 2010, 21(1): 127-136.
TENG Yan-guo, ZUO Rui, WANG Jin-sheng, LIN Xue-yu. Progress in geochemistry of regional groundwater evolution[J]. Advances in Water Science, 2010, 21(1): 127-136.
Citation: TENG Yan-guo, ZUO Rui, WANG Jin-sheng, LIN Xue-yu. Progress in geochemistry of regional groundwater evolution[J]. Advances in Water Science, 2010, 21(1): 127-136.

区域地下水演化的地球化学研究进展

基金项目: 国家自然科学基金资助项目(40773055);北京市优秀人才培养资助项目(20071D0503100294);国家水体污染控制与治理科技重大专项资助项目(2008ZX07027-007);教育部新世纪优秀人才支持计划
详细信息
    作者简介:

    滕彦国(1974- ),男,黑龙江巴彦人,教授,博士生导师,博士,主要从事地下水地球化学研究.E-mail:teng1974@163.com

  • 中图分类号: P641.3

Progress in geochemistry of regional groundwater evolution

Funds: The study is financially supported by the National Non-Profit Research Programme(No.200801033).
  • 摘要: 由于区域地质特征、水文地质条件、气候影响和人类活动的差异性,导致区域地下水演化的地球化学过程复杂、影响因素众多.在总结近年来国内外区域地下水化学演化研究大量成果的基础上,综述了地下水演化的地球化学系统分析方法,地下水演化研究的水文地球化学方法、同位素地球化学和元素地球化学方法和技术以及地下水演化的地球化学模拟方法和技术及常用软件.指出在今后的一段时期内,区域地下水自然演化与人类活动的复合作用、地下水与地表水的相互作用、微生物-水-岩相互作用将是区域地下水地球化学研究的热点领域,其中物理、化学、生物的耦合作用将是区域地下水演化的地球化学研究的重点领域.
  • [1] 章光新,邓伟,何岩,等.中国东北松嫩平原地下水水化学特征与演变规律[J].水科学进展,2006,17(1):20-28.(ZHANG Guang-xin,DENG Wei,HE Yan,et al.Hydrochemical characteristics and evolution laws of groundwater in Songnen Plain,Northeast China[J].Advances in Water Science,2006,17(1):20-28.(in Chinese))
    [2] KEBEDE S,TRAVI Y,ALEMAYEHU T,et al.Groundwater recharge,circulation and geochemical evolution in the source region of the Blue Nile River,Ethiopia[J].Applied Geochemistry,2005,20:1658-1676.
    [3] MAYOA A L,LOUCKSB M D.Solute and isotopic geochemistry and ground water flow in the central wasatch Range,Utah[J].Journal of Hydrology,1995,172(1/2/3/4):31-59.
    [4] HIDALGO M C,CRUZ-SANJULIAN J.Groundwater composition,hydrochemical evolution and mass transfer in a regional detrial aquifer(Baza Basin,Southern Spain)[J].Applied Geochemistry,2001,16(7/8):745-758.
    [5] 秦毅苏,朱延华,曹树林,等.黄河流域地下水资源合理开发利用[M].郑州:黄河水利出版社,1998:1-13.(QIN Yi-su,ZHU Yan-hua,CAO Shu-lin,et al.Rational development and utilization of groundwater resource in Yellow River basin[M].Zhengzhou:Yellow River Conservancy Press,1998:1-13.(in Chinese))
    [6] 许广明,张燕君.西北地区大型内陆盆地地下水系统演化特征分析[J].自然资源学报,2004,19(6):701-706.(XU Guang-ming,ZHANG Yan-jun.An analysis of the groundwater system evolution characteristics in large interior basins of Northwest China[J].Journal of Natural Resources,2004,19(6):701-706.(in Chinese))
    [7] PARNACHEV V P,BANKS D,BEREZOVSKY A Y,et al.Hydrochemical evolution of Na-SO4-Cl groundwater in a cold,semi-arid region of southern Siberia[J].Hydrogeology Journal,1999,7(6):546-560.
    [8] MUKHERJEE A,FRYAR A E,THOMAS W A.Geologic,geomorphic and hydrologic framework and evolution of the Bengal basin,India and 2Bangladesh[J].Journal of Asian Earth Sciences,2009,34:227-244.
    [9] AYENEW T,DEMLIE M,WOHNLICH S.Hydrogeological framework and occurrence of groundwater in the Ethiopian aquifers[J].Journal of African Earth Sciences,2008,52:97-113.
    [10] ZHANG J.Geochemistry of trace metals from Chinese river/estuary systems:An overview[J].Estuarine,Coastal and Shelf Science,1995,41,631-658.
    [11] HOUSTON J.Recharge to groundwater in the Turi Basin,northern Chile:an evaluation based on tritium and chloride mass balance techniques[J].Journal of Hydrology,2007,334:534-544.
    [12] 刘少玉,张光辉,张翠云,等.黑河流域水资源系统演变和人类活动影响[J].吉林大学学报:地球科学版,2008,38(5):806-812.(LIU Shao-yu,ZHANG Guang-hui,ZHANG Cui-yun,et al.Water resources system evolution and impact of human activities in Heihe River Basin[J].Journal of Jilin University:Earth Science Edition,2008,38(5):806-812.(in Chinese))
    [13] TOWNSEND M A,YOUNG D P.Assessment of nitrate-nitrogen distribution in Kansas groundwater,1990-1998[J].Natural Resources Research,2000,9(2):125-134.
    [14] BELOUSOVA A P,KRAINOV S R,RYZHENKO B N.Evolution of groundwater chemical composition under human activity in an oilfield[J].Environmental Geology,1999,38(1):34-46.
    [15] 郎赟超,刘丛强,赵志琦,等.贵阳市地表水地下水化学组成:喀斯特水文系统水-岩反应及污染特征[J].水科学进展,2005,16(6):827-832.(LANG Yun-chao,LIU Cong-qiang,ZHAO Zhi-qi,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,2005,16(6):827-832.(in Chinese))
    [16] GASCOYNE M.Hydrogeochemistry,groundwater ages and sources of salts in a granitic batholith on the Canadian Shield,southeastern Manitoba[J].Applied Geochemistry,2004,19,519-560.
    [17] CARTWRIGHT I,WEAVER T R.Hydrogeochemistry of the Goulburn Valley region of the Murray Basin,Australia:Implications for flow paths and resource vulnerability[J].Hydrogeology Journal,2005,13:752-770.
    [18] JAYAKUMAR R,SIRAZ L.Factor analysis in hydrogeochemistry of coastal aquifers-a preliminary study[J].Environmental Geology,1997,31:174-177.
    [19] CHIDAMBARAM S,KUMAR G S,PRASANNA M V,et al.A study on the hydrogeology and hydrogeochemistry of groundwater from different depths in a coastal aquifer:Annamalai Nagar,Tamilnadu,India[J].Environmental Geology,2009,57(1):59-73.
    [20] CARTWRIGHT I,WEAVER T R,FIFIELD L K.Cl/Br ratios and environmental isotopes as indicators of recharge variability and groundwater flow:An example from the southeast Murray Basin,Australia[J].Chemical Geology,2006,231:38-56.
    [21] ZIEGLER K,COLEMAN M L,HOWARTH R J.Paleohydrodynamics of fluids in the Brent Group(Oseberg Field,Norwegian North Sea) from chemical and isotopic compositions of formation waters[J].Applied Geochemistry,2001,16(6):609-632.
    [22] 朱兆洲,刘丛强,王中良,等.龙感湖稀土元素的地球化学特征[J].水科学进展,2006,17(6):785-789.(ZHU Zhao-zhou,LIU Cong-qiang,WANG Zhong-liang,et al.Geochemical character of rare earth element in Longgan Lake,East of China[J].Advances of Water Science,2006,17(6):785-789.(in Chinese))
    [23] JOHANNESSON K H,ZHOU X P,STETZENBACH K J,et al.Rare earth elements and groundwater mixing[J].EOS,1995,76:276.
    [24] JOHANNESSON K H,STETZENBACH K J,HODGE V F.Rare earth elements as geochemical tracer of regional groundwater mixing[J].Geochimica et Cosmochimica Acta,1997,61(17):3605-3618.
    [25] TWEED S O,WEAVER T R,CARTWRIGHT I,et al.Behavior of rare earth elements in groundwater during flow and mixing in fractured rock aquifers:An example from the Dandenong Ranges,southeast Australia[J].Chemical Geology,2006,234:291-307.
    [26] CLOUTIER V,LEFEBVRE R,THERRIEN R,et al.Multivariate statistical analysis of geochemical data as indicative of the hydrogeochemical evolution of groundwater in a sedimentary rock aquifer system[J].Journal of Hydrology,2008,353:294-313.
    [27] MARINI L,CANEPA M,CIPOLLI F,et al.Use of stream sediment chemistry to predict trace element chemistry of groundwater:A case study from the Bisagno valley(Genoa,Italy)[J].Journal of Hydrology,2001,241(3/4):194-220.
    [28] BATH A,RICHARDS H,METCALFE R,et al.Geochemical indicators of deep groundwater movements at Sellafield,UK[J].Journal of Geochemical Exploration,2006,90:24-44.
    [29] BOUCHAOU L,MICHELOT J L,VENGOSH A,et al.Application of multiple isotopic and geochemical tracers for investigation of recharge,salinization,and residence time of water in the Souss-Massa aquifer,southwest of Morocco[J].Journal of Hydrology,2008,352:267-287.
    [30] SOULSBY C,MALCOLM R,HELLIWELL R,et al.Isotope hydrology of the Allt a'Mharcaidh catchment,Cairngorms,Scotland:Implications for hydrological pathways and residence times[J].Hydrological Processes,2000,14(4):747-762.
    [31] ABBOTT M D,LINI A,BIERMAN P R.δ18O,D and 3H measurements constrain groundwater recharge patterns in an upland fractured bedrock aquifer,Vermont,USA[J].Journal of Hydrology,2000,228(1/2):101-112.
    [32] KAUFMANN R,LONG L,BENTLLEY H,et al.Natural chlorine isotope variations[J].Nature,1984,309(5966):338-340.
    [33] MACFARLANE P A,CLARK J F,DAVISSON M L,et al.Late-quaternary recharge determined from chloride in shallow groundwater in the central great plains[J].Quaternary Research,2000,53(2):167-174.
    [34] 刘丛强.流体-岩石反应体系中的硼同位素地球化学[J].地球化学,1996,25(1):93-100.(LIU Cong-qiang.Application of boron isotope geochemistry to water-rock interaction system[J].Earth Science,1996,25(1):93-100.(in Chinese))
    [35] BARTH S R.Stable isotope geochemistry of sediment-hosted groundwater from a Late Paleozoic-Early Mesozoic section in central Europe[J].Journal of Hydrology,2000,235(1/2):72-87.
    [36] LYONS W B,WELCH K A.Lithium in waters of a polar desert[J].Geochimica et Cosmochimica Acta,1997,61(20):4309-4319.
    [37] SCHUESSLER J A,SCHOENBERG R,SIGMARSSON O.Iron and lithium isotope systematics of the Hekla volcano,Iceland-Evidence for Fe isotope fractionation during magma differentiation[J].Chemical Geology,2009,258(1/2):78-91.
    [38] J(φ)RGENSEN N O,ANDERSEN M S,ENGESGAARD P.Investigation of a dynamic seawater intrusion event using strontium isotopes(87Sr/86Sr)[J].Journal of Hydrology,2008,348:257-269.
    [39] GOSSELINA D C,HARVEYA F E,FROST C,et al.Strontium isotope geochemistry of groundwater in the central part of the Dakota(Great Plains) aquifer,USA[J].Applied Geochemistry,2004,19:359-377.
    [40] 李晓峰,毛景文,王义天,等.惰性气体同位素和卤素示踪成矿流体来源[J].地质评论,2003,49(5) 513-521.(LI Xiao-feng,MAO Jing-wen,WANG Yi-tian,et al.Evidence of noble gas isotopes and halogen for the origin of ore-forming fluids[J].Geological Review,2003,49(5):513-521.(in Chinese))
    [41] KULONGOSKI J T,HILTON D R,CRESSWELL R G,et al.Helium-4 characteristics of groundwaters from central Australia:Comparative chronology with chlorine-36 and carbon-14 dating techniques[J].Journal of Hydrology,2008,348:176-194.
    [42] BALLENTINE C J,LOLLAR B S.Regional groundwater focusing of nitrogen and noble gases into the Hugoton-Panhandle giant gas field,USA[J].Geochimica et Cosmochimica Acta,2002,66(14):2483-2497.
    [43] MA L,CASTRO M C,HALL C M.Atmospheric noble gas signatures in deep Michigan Basin brines as indicators of a past thermal event[J].Earth and Planetary Science Letters,2009,277:137-147.
    [44] EDMUNDS W M,MA J,AESCHBACH-HERTIG W,et al.Groundwater recharge history and hydrogeochemical evolution in the Minqin Basin,North West China[J].Applied Geochemistry,2006,21:2148-2170.
    [45] LEE E S,KROTHE N C.A four-component mixing model for water in a karst terrain in south-central Indiana,USA:Using solute concentration and stable isotopes as tracers[J].Chemical Geology,2001,179:129-143.
    [46] SAMPER J,LU C,MONTENEGRO L.Reactive transport model of interactions of corrosion products and bentonite[J].Physics and Chemistry of the Earth,2008,33:306-316.
    [47] BROWNING L,MURPHY W M,MANEPALLYA C,et al.Reactive transport model for the ambient unsaturated hydrogeochemical system at Yucca Mountain,Nevada[J].Computers & Geosciences,2003,29:247-263.
    [48] ULIANA M M,SHARP J J M.Tracing regional flow paths to major springs in Trans-Pecos Texas using geochemical data and geochemical models[J].Chemical Geology,2001,179:53-72.
    [49] ZHANG G,SAMPER J,MONTENEGRO L.Coupled thermo-hydro-bio-geochemical reactive transport model of CERBERUS heating and radiation experiment in Boom clay[J].Applied Geochemistry,2008,23:932-949.
    [50] MAHLKNECHT J,STEINICH B,NavaRro I.Groundwater chemistry and mass transfers in the Independence aquifer,central Mexico,by using multivariate statistics and mass-balance models[J].Environmental Geology,2004,45:781-795.
    [51] DAI Z,SAMPER J.Inverse modeling of water flow and multicomponent reactive transport in coastal aquifer systems[J].Journal of Hydrology,2006,327:447-461.
    [52] JIN L,WILLIAMS E L,SZRAMEK K J,et al.Silicate and carbonate mineral weathering in soil profiles developed on Pleistocene glacial drift(Michigan,USA):Mass balances based on soil water geochemistry[J].Geochimica et Cosmochimica Acta,2008,72:1027-1042.
    [53] 钱天伟,李书绅,武贵宾.地下水多组分反应溶质迁移模型的研究进展[J].水科学进展,2002,13(1):116-121.(QIAN Tian-wei,LI Shu-shen,WU Gui-bin.Advances in study on transport models of multicomponent reacting solutes in groundwater[J].Advances in Water Science,2002,13(1):116-121.(in Chinese))
    [54] JACQUES D,ŠIMŬNEK J,MALLANTS D,et al.Modelling coupled water flow,solute transport and geochemical reactions affecting heavy metal migration in a podzol soil[J].Geoderma,2008,145:449-461.
    [55] MOLINERO J,RAPOSO J R,GALŇDEZ J M,et al.Coupled hydrogeological and reactive transport modeling of the Simpevarp area,Sweden[J].Applied Geochemistry,2008,23:1957-1981.
    [56] SAMPER J,ZHENG L,MONTENEGRO L,et al.Coupled thermo-hydro-chemical models of compacted bentonite after FEBEX in situ test[J].Applied Geochemistry,2008,23:1186-1201.
    [57] ZHENG L,SAMPER J,MONTENEGRO L,et al.Multiphase flow and multicomponent reactive transport model of the ventilation experiment in Opalinus clay[J].Physics and Chemistry of the Earth,2008,33:186-195.
    [58] YEH G,SIEGEL M D,LI M.Numerical modeling of coupled variably saturated fluid folw and reactive transport with fast and slow chemical reactions[J].Journal of Contaminant Hydrology,2001,47(2/3/4):379-390.
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出版历程
  • 收稿日期:  2009-01-10
  • 刊出日期:  2010-01-25

区域地下水演化的地球化学研究进展

    基金项目:  国家自然科学基金资助项目(40773055);北京市优秀人才培养资助项目(20071D0503100294);国家水体污染控制与治理科技重大专项资助项目(2008ZX07027-007);教育部新世纪优秀人才支持计划
    作者简介:

    滕彦国(1974- ),男,黑龙江巴彦人,教授,博士生导师,博士,主要从事地下水地球化学研究.E-mail:teng1974@163.com

  • 中图分类号: P641.3

摘要: 由于区域地质特征、水文地质条件、气候影响和人类活动的差异性,导致区域地下水演化的地球化学过程复杂、影响因素众多.在总结近年来国内外区域地下水化学演化研究大量成果的基础上,综述了地下水演化的地球化学系统分析方法,地下水演化研究的水文地球化学方法、同位素地球化学和元素地球化学方法和技术以及地下水演化的地球化学模拟方法和技术及常用软件.指出在今后的一段时期内,区域地下水自然演化与人类活动的复合作用、地下水与地表水的相互作用、微生物-水-岩相互作用将是区域地下水地球化学研究的热点领域,其中物理、化学、生物的耦合作用将是区域地下水演化的地球化学研究的重点领域.

English Abstract

滕彦国, 左锐, 王金生, 林学钰. 区域地下水演化的地球化学研究进展[J]. 水科学进展, 2010, 21(1): 127-136.
引用本文: 滕彦国, 左锐, 王金生, 林学钰. 区域地下水演化的地球化学研究进展[J]. 水科学进展, 2010, 21(1): 127-136.
TENG Yan-guo, ZUO Rui, WANG Jin-sheng, LIN Xue-yu. Progress in geochemistry of regional groundwater evolution[J]. Advances in Water Science, 2010, 21(1): 127-136.
Citation: TENG Yan-guo, ZUO Rui, WANG Jin-sheng, LIN Xue-yu. Progress in geochemistry of regional groundwater evolution[J]. Advances in Water Science, 2010, 21(1): 127-136.
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