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矿床地质 2011

西藏甲玛铜多金属矿床成矿流体来源及演化

周云,汪雄武,唐菊兴,秦志鹏,彭惠娟,李爱国,杨科,王华,李炯,张继超

Keywords: 地球化学,成矿流体,特征,来源,演化,甲玛,西藏

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Abstract:

对斑岩、矽卡岩及角岩矿物中石英的熔融包裹体和流体包裹体进行测温，得到甲玛铜多金属矿床斑岩体形成温度为634～887℃，斑岩体中流体开始出溶的压力为59.1MPa。从岩浆阶段、岩浆_热液阶段、矽卡岩阶段、矽卡岩退变质阶段到石英-硫化物阶段，温度范围为170～540℃，盐度集中在15%～50%范围内，密度为0.9233～1.0805g/cm3，成矿流体主要为NaCl-H2O体系。早期最低成矿压力为31.8MPa，最浅成矿深度为1.1778km。通过流体包裹体的离子成分、气相成分比值与图解、氢氧同位素数据分析，表明甲玛铜多金属矿床的成矿流体为岩浆来源，并有后期大气降水的混入。成矿流体的形成和演化经历了岩浆出溶、超临界流体的相分离、流体的减压沸腾作用及岩浆热液、挥发分与碳酸盐围岩接触带的充填/交代作用。岩浆-热液演化过程中的成矿元素，从最早的岩浆结晶分异阶段开始到岩浆期后热液阶段，都强烈地选择性进入挥发分气相中进行迁移。流体的减压沸腾、混合作用最终导致成矿元素的沉淀，甲玛矿床在成因上与斑岩-浅成低温热液成矿系统中的岩浆-热液成矿作用有关。

References

[1]	周云;汪雄武;唐菊兴;秦志鹏,彭惠娟,李爱国,杨科,王华,李炯,张继超,西藏甲玛铜多金属矿含矿斑岩石英斑晶单个熔融包裹体的成分研究,成都理工大学学报(自然科学版),2011(待刊).
[2]	姚鹏;郑明华;彭勇民;李金高粟登奎范文玉,西藏冈底斯岛弧带甲马铜多金属矿床成矿物质来源及成因研究,地质论评,2002(05).
[3]	刘斌;沈昆,流体包裹体热力学,北京:地质出版社,1999.
[4]	李光明,芮宗瑶,王高明,林方成刘波佘宏全丰成友屈文俊,西藏冈底斯成矿带甲马和知不拉铜多金属矿床的Re-Os同位素年龄及其意义,矿床地质,2005(05).
[5]	更多...
[6]	冯孝良;管仕平;牟传龙;侯增谦李胜荣,西藏甲马铜多金属矿床的岩浆热液交代成因:地质与地球化学证据,地质地球化学,2001(04).
[7]	杜光树;姚鹏;潘凤雏,喷流成因矽卡岩与成矿--以西藏甲马铜多金属矿床为例,成都:四川科学技术出版社,1998.
[8]	包志伟,成矿金属元素的气相运移研究进展,大地构造与成矿学,2007(01).
[9]	Zoltain Z;Halter W,LA-ICPMS analyses of silicate melt inclusions in co-precipitated minerals:Quantification,data analysis and mineral/melt partitioning,Geochimica et Cosmochimica Acta,2007.
[10]	Zhou Y;Wang X W;Tang J X;Qin Z P Peng H J Li A G Yang K Wang H Li J,Zhang J C,The composition of single silicate melt inclusions in the quartz phenocrysts in porphyries from Jiama polymetallic copper deposit,Tibet,Journal of Chengdu University of Technology(Science&Technology Edition),2011.
[11]	Zhou Y,Characteristic and evolution of ore-forming fluids from Jiama polymetallic copper deposit,Mozhugongka County,Tibet,成都:成都理工大学,2010.
[12]	Zheng W B;Chen Y C;Tang J X;Song X,Lin B,Gui X G,Ying L J,Research and applica tion of copper mineralization enrich ment regularity of Jiama polymetallic copper deposit in Tibet,Metal Mine,2010(02).
[13]	Tibor G;Zoltain Z,LA-ICP-MS study of apatite-and K feldspar-hosted primary carbonatite melt inclusions in clinopyroxenite xenoliths from lamprophyres,Hungary:Implications for significance of carbonatite melts in the Earth\'s mantle,Geochimica et Cosmochimica Acta,2008.
[14]	Tang J X;Wang D H;Wang W X;ZhongK H Zheng W B Ying L J,Qin Z P,Geological features and metaliogenic model of the Jiama copper-polymetallic deposit in Tibet,Acta Geoscientica Sinica,2010(04).
[15]	Tang J X;Chen Y C;Duo J,The main deposit type,metallogenic regularity and exploratory in Gandese copper belt,Tibet,Acta Mineralogica Sinica,2009(z1).
[16]	Student J J;Robert J B Silicate melt inclusion in porphyry copper deposits:Idetification and homogenization behavio [J] 2004 doi:10.2113/gscanmin.42.5.1583
[17]	Student J J;Bodnar R J,Melt inclusion microthermometry:petrologic constraints from the H2O-saturated haplogranite system,Petrology,1996.
[18]	Ryan G G;Heinrich C A;Memagh T P,PIXE microanalysis of fluid inclusions and its application to study ore metal segregation between magmatic brine and vapor,Nuclear Instruments and Methods in Physics Research B:Beam Interaction with Materials and Atoms,1993.
[19]	Roedder E Fluid inclusions as tool in mineral exploration [J] 1977(03) doi:10.2113/gsecongeo.72.3.474
[20]	Qu X M;Hou Z Q;Huang W,Is Gangdese porphyry copper belt the second "Yulong" copper belt,Mineral Deposits,2001(04).
[21]	Qin Z P;Wang X W;Tang J X,Zircon CL,U-Pb ages and Trace elements characteristic of potassic Adakite-like in Jiama polymetallic copper deposit,Tibet,Geochemistry,2011.
[22]	Potter R W,The volumetric properties of aqueous sodium chloride solutions from 0 to 500℃ at pressures up to 2000 bar based on a regressionof available data in the literature,US Geological Survey Bulletin,1978.
[23]	Pan F C;Deng J;Yao P;Wang Q F,Liu Y X,The eruptive origins of copper and multi-metal deposits in the skarn in Jiama,Tibet,Geoscience,2002(04).
[24]	Norman D I;Musgrave J A N2-Ar-He compositions in fluid inclusions,implicators of fluid source [J] 1994 doi:10.1016/0016-7037(94)90576-2
[25]	Mavrogenes J A;Berry A J;Newville M,Copper speciation in vapor 2 phase fluid inclusions from the Mole Granite,Australia,American Mineralogist,2002.
[26]	Matthew J S;James S B;Luca F;John M H,Scott R M,Robert J B,Partitioning behavior of trace elements between dacitic melt and plagioclase,orthopyroxene,and clinopyroxene based on laser ablation ICPMS analysis of silicate melt inclusions,Geochimica et Cosmochimica Acta,2009.
[27]	Liu B;Shen K,Fluid inclusion thermodynamics,北京:地质出版社,1999.
[28]	Li G M;Rui Z Y;Wang M G;Lin F C Liu B She H Q Feng C Y,Qu W J,Molybdenite Re-Os dating of Jiama and Zhibula polymetallic copper deposits in Gan gdese metallogenic belt of Tibet and its significance,Mineral Deposits,2005(05).
[29]	Landtwing, MR ；Pettke, T ；Halter, WE ；Heinrich, CA ；Redmond, PB ；Einaudi, MT ；Kunze, K,Copper deposition during quartz dissolution by cooling magmatic-hydrothermal fluids: The Bingham porphyry,Earth and Planetary Science Letters？,2005, 235(1-2).
[30]	Heinrich C A;Guenther D;Audetat A;Ulrich T,Frischknecht R Metal fractionation between magmatic brine and vapor,determined by microanalysis of fluid inclusions [J] 1999(8) doi:10.1130/0091-7613(1999)027<0755:MFBMBA>2.3.CO;2
[31]	Heinrich C A;Ryan C G,Mineral paragenesis and regional zonation of granite-related Sn-As-Cu-Pb-Zn deposits:A chemical model for the Mole Granite district (Australia) based on PIXE fluid inclusion analyses,Balkema Rotterdam,1992.
[32]	Hedenquist J W;Lowenstern J B The role of magmas in the formation of hydrothermal of deposits [J] 1994 doi:10.1038/370519a0
[33]	Werner E. Halter ；Nicolas Bain ；Katja Becker ；Christoph A. Heinrich ；Marianne Landtwing ；Albrecht VonQuadt ；Alan H. Clark ；Anne M. Sasso ；Thomas Bissig ；Richard M. Tosdal,From andesitic volcanism to the formation of a porphyry Cu-Au mineralizing magma chamber: the Farallon Negro Volcanic Complex, northwestern Argentina,Journal of Volcanology and Geothermal Research？,2004, 136(1/2).
[34]	Halter W E;Webster J D The magmatic to hydrothermal transition and its bearing on ore-forming systems [J] 2004 doi:10.1016/j.chemgeo.2004.06.001
[35]	Halter W E;Pettke Thomas;Heinrich C A Major to trace element analysis of melt inclusions by laser-ablation ICP-MS:methods of quantification [J] 2002 doi:10.1016/S0009-2541(01)00372-2
[36]	Hall D L;Sterner S M;Bodnar R J,Freezing point depression of NaCl-KCl-H2O solution,Economic Geology,1988.
[37]	Feng X L;Guan S P;Zhao C L;Hou Z Q,Li S R,Geological characteristics and genesis of the Jiama copper-polymetalic deposit in Tibet,Geology and Geochemistry,2001(04).
[38]	Du G S;Yao P;Pan F C,Summarine exhalative sedimentary skarn and mineralization,成都:四川科学技术出版社,1998.
[39]	Davide B,FIB,TEM and LA-ICPMS investigations on melt inclusions in Martian meteorites-Analytical capabilities and geochemical insights,Talanta,2006.
[40]	Bodnar I,Fluid evolution in porphyry copper deposits,1998.
[41]	Bodnar I;Cline J,F1uid inclusion petrology of porphyry cop per deposits revisited:Re-interpretation of obselved characteristics basedon recent experimental and theoretical data,Plinius,1991.
[42]	Bischoff J L,Densities of liquids and vapors in boiling NaCl-H2O solutions:A PVTX summary from 300℃ to 500℃,American Journal of Science,1991.
[43]	Bao Z W,Vapor-transport of ore metals:A review,Geotec tonica et Metallogenia,2007(01).
[44]	Baker T;Achterberg E V;Ryan C G;Lang J R,Composition and evolution of ore fluids in a magmatic-hydrothermal skarn deposit,Geology,2004(02).
[45]	周云,西藏墨竹工卡县甲玛铜多金属矿成矿流体特征及演化,成都:成都理工大学,2010.
[46]	郑文宝;陈毓川;唐菊兴;宋鑫林彬桂晓根应立娟,西藏甲玛铜多金属矿床铜矿化富集规律研究及应用,金属矿山,2010(02).
[47]	应立娟;唐菊兴;王登红;畅哲生屈文俊郑文宝,西藏甲玛铜多金属矿床矽卡岩中辉钼矿铼-锇同位素定年及其成矿意义,岩矿测试,2009(3).
[48]	姚鹏;顾雪祥;李金高;范文玉,甲马铜多金属矿床层控矽卡岩流体包裹体特征及其成因意义,成都理工大学学报,2006(03).
[49]	姚鹏;李金高;顾雪祥;郑明华陈建坤,从REE和硅同位素特征探讨西藏甲马矿床层状矽卡岩成因,岩石矿物学杂志,2006(04).
[50]	杨志明;侯增谦,初论碰撞造山环境斑岩铜矿成矿模型,矿床地质,2009(05).
[51]	杨志明,侯增谦,宋玉财,李振清夏代详潘凤雏,西藏驱龙超大型斑岩铜矿床:地质、蚀变与成矿,矿床地质,2008(03).
[52]	杨志明;侯增谦;李振清;宋玉财谢玉玲,西藏驱龙斑岩铜钼矿床中UST石英的发现:初始岩浆流体的直接记录,矿床地质,2008(02).
[53]	杨志明;谢玉玲;李光明;徐九华,西藏冈底斯斑岩铜矿带成矿流体的扫描电镜(能谱)约束--以驱龙和厅宫矿床为例,矿床地质,2006(02).
[54]	杨志明,谢玉玲,李光明,徐九华王葆华,西藏冈底斯斑岩铜矿带厅宫铜矿床流体包裹体研究,矿床地质,2005(06).
[55]	唐菊兴;王登红;汪雄武;郑文宝黎枫佶,西藏甲玛铜多金属矿矿床地质特征及其矿床模型,地球学报,2010(04).
[56]	唐菊兴;陈毓川;多吉,西藏冈底斯成矿带东段主要矿床类型、成矿规律和找矿评价,矿物学报,2009(z1).
[57]	唐菊兴;王登红;钟康惠;郑文宝应力娟秦志鹏,西藏自治区墨竹工卡县甲玛铜多金属矿区0-16-40-80,0-15线矿段铜多金属矿勘探报告,拉萨:西藏自治区国土资源厅,2009.
[58]	佘宏全;丰成友;张德全;李光明刘波李进文,西藏冈底斯铜矿带甲马矽卡岩型铜多金属矿床与驱龙斑岩型铜矿流体包裹体特征对比研究,岩石学报,2006(03).
[59]	秦志鹏;汪雄武;唐菊兴,西藏甲玛铜多金属矿床钾质似埃达克岩锆石阴极发光、U-Pb年龄及其微量元素特征,地球化学,2011(待刊).
[60]	潘凤雏;邓军;姚鹏;王庆飞刘玉祥,西藏甲马铜多金属矿床矽卡岩的喷流成因,现代地质,2002(04).
[61]	Zartman R E;Doe B R,Plumbotectonics-the model,Tectonophysics,1981(1-2).
[62]	Ying L J;Tang J X;Wang D H;Chang Z S,Zheng W B,ReOs isotopic dating of molybdenite in skarn from the Jiama copper polymetallic deposit of Tibet and its metallogenic significance,Rock and Mineral Analysis,2009(03).
[63]	Yao P;Gu X X;Li J G;Fan W Y,Characteristics and origin signification of ore-forming fluid from the Jiama stratabound skarn deposit located in Gandise volcanic\'magmatic arc,Tibet,China,Journal of Chengdu University of Technology(Science&Technology Edition),2006(03).
[64]	Yao P;Li J G;Gu X X;Zheng M H,Chen J K,A discussion on the genesis of the stratabound skarn in the Jiama copper and polymetailic deposit of Tibet on the basis of REE and silicon isotope geochemistry,Acta Petrologica et Mineralogica,2006(04).
[65]	Yao P;Zheng M H;Peng Y M;Li J G Su D K,Fan W Y,Sources of ore forming materials and the Genesis of the Jiama copper and polymetallic deposit in Gandise island-arc belt Xizang,Geological Review,2002(05).
[66]	Yang Z M;Hou Z Q;Song Y C;Li Z Q Xia D X,Pan F C,Qulong superlarge porphyry Cu deposit in Tibet:Geology,alteration and mineralization,Mineral Deposits,2008(3).
[67]	Yang Z M;Hou Z Q;Li Z Q;Song Y C,Xie Y L,Direct record of primary fluid exsolved from magma:Evidence from unidirectional solidification texture (UST) in quartz found in Qulong porphyry copper deposit,Tibet,Mineral Deposits,2008(02).
[68]	Yang Z M;Hou Z Q,Porphyry Cu deposits in collisional orogen setting:A preliminary genetic model,Mineral Deposits,2009(05).
[69]	Yang Z M;Xie Y L;Li G M;Xu J H,SEM/EDS constraints on nature of ore-forming fluids in Gangdese porphyry copper belt:Case studies of Qulong and Tinggong deposits,Mineral Deposits,2006(2).
[70]	Yang Z M;Xie Y L;Li G M;Xu J Hand Wang B H,Study of fluid inclusions from Tinggong porphyry copper deposit in Gangdese belt,Tibet,Mineral Deposits,2005(06).
[71]	Wilkinson J J,Fluid inclusions in hydrothermal ore deposits,Lithos,2004.
[72]	She H Q;Feng C Y;Zhang D Q;Li G M Liu Band Li J W,Study on the fluid inclusions from Jiama skarn copper polymetallic deposit and Qulong porphyry copper deposit in Gangdese copper belt,Tibet,Acta Petrologica Sinica,2006(3).

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