新疆若羌县白干湖大型钨锡矿田构造—流体及成矿模式研究
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摘要
新疆白干湖钨锡矿田位于新疆维吾尔自治区若羌县境内,于2001年由吉林地质调查院发现,分布有柯可·卡尔德矿床、白干湖矿床、巴什·尔西矿床和阿瓦尔矿床,各矿床具相似的围岩和成矿岩体,矿床类型包括石英脉型、矽卡岩型、云英岩型,是一个一体多型的大型钨锡矿田,成矿受金水口群地层、各级断裂构造系统及加里东期二长花岗岩控制。
矿田构造可划分成矿前、成矿期和成矿后构造,晚期构造对早期有继承、置换、叠加和复合现象,都充填了构造-流体作用的产物—脉体。矿田构造亦有分级控制特点,白干湖超壳大断裂通过控制地层分布和岩浆活动控制着矿田产出位置和等间距线性分布;白干湖剪切作用形成的次级断裂、矿区花岗岩内外接触带构造及岩浆派生的水力-热致断裂、冷却收缩裂隙控制着矿体的产出,为容矿构造。构造-流体有多阶段脉动活动特点,在平面上呈现平行、雁行排列规律。
流体包裹体主要有气液两相、含子盐气液三相、单一液相(包括纯水和纯CO2型)、含CO2气液三相、同时含CO2和子盐气液四相等5种类型。成矿前构造热液形成的石英以前两种包裹体为主,有少量含CO2气液三相型,温度160~417℃,盐度6.16%-18.8wt%NaCl,受到成矿期热液作用叠加。成矿期石英温度125~370℃,盐度0.21%-15.17wt%NaCl,其中早阶段是钨锡的主成矿阶段,包含五种类型包裹体,温度239~370℃,盐度0.21%-15.17wt%NaCl,晚阶段主要为气液两相型,温度125~205℃,盐度6.6%-9.6wt%NaCl;成矿后石英包裹体主要为气液两相型,温度178-263℃,盐度6.3%9.08wt%NaCL激光拉曼探针分析表明成矿流体主要成分为H2O和CO2,气相含少量CH4和N2;氢、氧同位素研究结果显示三期流体分别主要为变质热液、岩浆热液和大气降水。该矿床系中高温、中低盐度的岩浆热液矿床,早期流体经历了不混溶作用,而混合作用可能贯穿整个成矿过程,这些是促使矿质沉淀的主要因素。
矿田内发育复式岩体,利用SIMS锆石U-Pb法对矿田东北部似斑状二长花岗岩和中粗粒钾长花岗岩测得年龄分别为421±4Ma和422±4Ma。矿区内云英岩化矿化花岗岩脉和钨锡矿石英脉两侧云母线白云母39Ar-40Ar坪年龄分别为411.7±2.6Ma和412.8±2.4Ma。这些资料表明区内岩浆一成矿作用事件是连续的,代表了该地区加里东期(晚志留世)大规模成岩成矿事件。
复式岩体具A型花岗岩的特征,成岩背景为晚造山拉伸环境,且岩体富含成矿元素,是白干湖钨锡多金属矿床的成矿母岩,也是白干湖钨锡多金属矿田成矿系统的中心。
成矿演化模式总结为同生沉积期→变质变形矿化期→热液成矿期→后生热液期→表生氧化期演化过程,而热液成矿期又分矽卡岩型云英岩型阶段、钨锡矿石英脉阶段、石英脉硫化物阶段。
Baigan Lake tungsten-tin ore field,located in Xinjiang province, contains four deposits,Kekekaerde,Baigan Lake deposit, Bashierxi and the Awar.All deposits mineralization show similar geology character as multiple type in single deposit area and related to stratigraphy, structure and magmatism.
We can defined structure as pre-ore-forming stage, ore-forming stage and post-ore-forming stage,the later of which always inherit,replace,superpose the former stucture.Ore-forimg stage took place in Caledonian. Different scale level can also be recognized as regional scale,ore-field scale and orebody scale. Regional scale Baigan lake fault play a role as controlling the distribution of stratum and intrusions,both are close with mineralization. The Secondary faults of Baigan lake fault and intrusive contact structure zone control Ore-hosting structure,including parallel and echelon shape.
Fluid inclusions in the three stage quartz can be divided into five types:G-L two phases, G-L-D three phases,CO2or water single phase,CO2-H2O three phases,and CO2-H2O-NaCl four phases. The first two are the main types in stage one quartz. Ore-forming satge quartz vein can be divided in two period and the first period was major W-Sn precipitating period and have all the five types of fluid inclusion.post-mineralization quartz contains mainly G-L two phases type. Ramman analysis results show that the liquid composition contains H2O and CO2while the gaseous composition contains minor CH4and N2as well. H-O isotopic composition of fluid inclusions in the three type veins indicate that ore-forming fluid is a mixture of magmatic water,atmospheric water and metamorphic water.Study on petrographic, microthermometry,and H-O isotopic analysis impy fluid immiscibility and fluid mixing, which may play a significant role for tungsten precipitation.
Composite body intrusive this deposit area.Moyite and adamellite emplaced in north-eastern area show as composite body which have similar contemporary and geochemical characteristic.Zircon U-Pb age obtained by SIMS technique are422±3Ma and421±4Ma respectively,indicating mid-late Silurian.40Ar/39Ar plateau age of muscovite from ore-forming alternative granite dike is411.7±2.6Ma while age muscovite from W-Sn quartz vein is412.8±2.4Ma,indicating that Magmatism and mineralization events is continuous.
Composite pluton has the characteristics of the A-type granites,diagenetic background stretch stress field of late orogenic environment. Pluton which is rich in ore-forming elements is not noly the parent rock of Baigan Lake tungsten-tin-polymetallic mineralization, but also white Baigan tungsten polymetallic ore field intothe center of the mine system.
Metallogenic model can be described as sedimentary-metamorphic deformed mineralized period-agmatism hydrothermal mineralization period-supergenesis period. Magmatism hydrothermal ore-forming period was futher divided into veinlets formative stage, stratiform tungsten-tin ore body formation stage and W-Sn quartz vein ore body formation stage.
矿田构造可划分成矿前、成矿期和成矿后构造,晚期构造对早期有继承、置换、叠加和复合现象,都充填了构造-流体作用的产物—脉体。矿田构造亦有分级控制特点,白干湖超壳大断裂通过控制地层分布和岩浆活动控制着矿田产出位置和等间距线性分布;白干湖剪切作用形成的次级断裂、矿区花岗岩内外接触带构造及岩浆派生的水力-热致断裂、冷却收缩裂隙控制着矿体的产出,为容矿构造。构造-流体有多阶段脉动活动特点,在平面上呈现平行、雁行排列规律。
流体包裹体主要有气液两相、含子盐气液三相、单一液相(包括纯水和纯CO2型)、含CO2气液三相、同时含CO2和子盐气液四相等5种类型。成矿前构造热液形成的石英以前两种包裹体为主,有少量含CO2气液三相型,温度160~417℃,盐度6.16%-18.8wt%NaCl,受到成矿期热液作用叠加。成矿期石英温度125~370℃,盐度0.21%-15.17wt%NaCl,其中早阶段是钨锡的主成矿阶段,包含五种类型包裹体,温度239~370℃,盐度0.21%-15.17wt%NaCl,晚阶段主要为气液两相型,温度125~205℃,盐度6.6%-9.6wt%NaCl;成矿后石英包裹体主要为气液两相型,温度178-263℃,盐度6.3%9.08wt%NaCL激光拉曼探针分析表明成矿流体主要成分为H2O和CO2,气相含少量CH4和N2;氢、氧同位素研究结果显示三期流体分别主要为变质热液、岩浆热液和大气降水。该矿床系中高温、中低盐度的岩浆热液矿床,早期流体经历了不混溶作用,而混合作用可能贯穿整个成矿过程,这些是促使矿质沉淀的主要因素。
矿田内发育复式岩体,利用SIMS锆石U-Pb法对矿田东北部似斑状二长花岗岩和中粗粒钾长花岗岩测得年龄分别为421±4Ma和422±4Ma。矿区内云英岩化矿化花岗岩脉和钨锡矿石英脉两侧云母线白云母39Ar-40Ar坪年龄分别为411.7±2.6Ma和412.8±2.4Ma。这些资料表明区内岩浆一成矿作用事件是连续的,代表了该地区加里东期(晚志留世)大规模成岩成矿事件。
复式岩体具A型花岗岩的特征,成岩背景为晚造山拉伸环境,且岩体富含成矿元素,是白干湖钨锡多金属矿床的成矿母岩,也是白干湖钨锡多金属矿田成矿系统的中心。
成矿演化模式总结为同生沉积期→变质变形矿化期→热液成矿期→后生热液期→表生氧化期演化过程,而热液成矿期又分矽卡岩型云英岩型阶段、钨锡矿石英脉阶段、石英脉硫化物阶段。
Baigan Lake tungsten-tin ore field,located in Xinjiang province, contains four deposits,Kekekaerde,Baigan Lake deposit, Bashierxi and the Awar.All deposits mineralization show similar geology character as multiple type in single deposit area and related to stratigraphy, structure and magmatism.
We can defined structure as pre-ore-forming stage, ore-forming stage and post-ore-forming stage,the later of which always inherit,replace,superpose the former stucture.Ore-forimg stage took place in Caledonian. Different scale level can also be recognized as regional scale,ore-field scale and orebody scale. Regional scale Baigan lake fault play a role as controlling the distribution of stratum and intrusions,both are close with mineralization. The Secondary faults of Baigan lake fault and intrusive contact structure zone control Ore-hosting structure,including parallel and echelon shape.
Fluid inclusions in the three stage quartz can be divided into five types:G-L two phases, G-L-D three phases,CO2or water single phase,CO2-H2O three phases,and CO2-H2O-NaCl four phases. The first two are the main types in stage one quartz. Ore-forming satge quartz vein can be divided in two period and the first period was major W-Sn precipitating period and have all the five types of fluid inclusion.post-mineralization quartz contains mainly G-L two phases type. Ramman analysis results show that the liquid composition contains H2O and CO2while the gaseous composition contains minor CH4and N2as well. H-O isotopic composition of fluid inclusions in the three type veins indicate that ore-forming fluid is a mixture of magmatic water,atmospheric water and metamorphic water.Study on petrographic, microthermometry,and H-O isotopic analysis impy fluid immiscibility and fluid mixing, which may play a significant role for tungsten precipitation.
Composite body intrusive this deposit area.Moyite and adamellite emplaced in north-eastern area show as composite body which have similar contemporary and geochemical characteristic.Zircon U-Pb age obtained by SIMS technique are422±3Ma and421±4Ma respectively,indicating mid-late Silurian.40Ar/39Ar plateau age of muscovite from ore-forming alternative granite dike is411.7±2.6Ma while age muscovite from W-Sn quartz vein is412.8±2.4Ma,indicating that Magmatism and mineralization events is continuous.
Composite pluton has the characteristics of the A-type granites,diagenetic background stretch stress field of late orogenic environment. Pluton which is rich in ore-forming elements is not noly the parent rock of Baigan Lake tungsten-tin-polymetallic mineralization, but also white Baigan tungsten polymetallic ore field intothe center of the mine system.
Metallogenic model can be described as sedimentary-metamorphic deformed mineralized period-agmatism hydrothermal mineralization period-supergenesis period. Magmatism hydrothermal ore-forming period was futher divided into veinlets formative stage, stratiform tungsten-tin ore body formation stage and W-Sn quartz vein ore body formation stage.
引文
Alfons Van den Kerkhof., Thiery R.2001. Carbonic inclusions[J]. Lithos,55(1-4):49-68.
Anglin C. D., Franklin J. M., Jonasson I. R., Bell K., Hoffman E.1987. Geochemistry of scheelites associated with Archean gold deposits:implications for their direct age determination[J].In current research, Part A:geological Survey of Canada Paper,87:591-596.
Baker T.2002. Emplacement depth and carbon dioxide-rich fluid inclusions in intrusion-related gold deposits[J]. Economic Geology,97(5):1111-1117.
Baker T.,Lang J. R.2001.Fluid inclusion characteristics of intrusion-related gold mineralization, Tombstone-Tungsten magmatic belt, Yukon Territory, Canada[J].Mineralium Deposita, 36(6):563-582.
Brown P. E.1989.FLINCOR; a microcomputer program for the reduction and investigation of fluid-inclusion data[J].American Mineralogist,74(11-12):1390-1393.
Burke E. A. J.2001. Raman microspectrometry of fluid inclusions[J].Lithos,55(1-4):139-158.
Clayton Rn.O'Neil J R,and Mayeda TK,1972.Oxygen isotope exchange between quartz and water,Journal of Geophysical Reseatch.77:3057-3067
Diamond L. W.2001.Review of the systematics of CO2-H2O fluid inclusions[J].Lithos,55(1-4):69-99.
Hall D. L.,Sterner S. M., Bodnar R. J.1988. Freezing point depression of NaCl-KCl-H2O solutions[J]. Economic Geology,83(1):197-202.
Heinrich C. A.2007. Fluid-fluid interactions in magmatic-hydrothermal ore formation[J].Reviews in mineralogy and geochemistry,65(1):363-387.
Heinrich C.A.,Driesner T., Stefansson A.,Seward T. M.2004. Magmatic vapor contraction and the transport of gold from the porphyry environment to epithermal ore deposits[J]. Geology, 32(9):761-764.
Lang J.R.,Baker T.2001.Intrusion-related gold systems:the present level of understanding[J]. Mineralium Deposita,36(6):477-489.
Leigeois J. P.1998. Perface:Some words on the post-collisional magmatism[J]. Lithos,45.
LI Xian-hua, LIU Yu, LI Qiu-li, GUO Chun-hua, CHAMBERLAIN K R.2009. Precise determination of Phanerozoic zircon Pb/Pb age by multicollector SIMS without external standardization[J]. Geochemistry Geophysics Geosystems,10:Q04010, doi:10.1029/2009GC002400.
Lowenstern J. B.2000. A review of the contrasting behavior of two magmatic volatiles:chlorine and carbon dioxide[J]. Journal of Geochemical Exploration,69:287-290.
Lowenstern J. B.2001.Carbon dioxide in magmas and implications for hydrothermal systems[J]. Mineralium Deposita,36(6):490-502.
Pearce J. A.,Harris N. B.W., Tindle A. G.1984.Trace element discrimination diagrams for the tectonic interpretation of granitic rocks[J].Journal of Petrology,25(4):956-983.
Peng B.,Frei R.2004. Nd-Sr-Pb isotopic constraints on metal and fluid sources in W-Sb-Au mineralization at Woxi and Liaojiaping (Western Hunan, China)[J].Mineralium Deposita,39(3):313-327.
Roedder.1984. Fluid inclusions[J]. Reviews in Mineralogy,(12):644.
Slama J., Kosler J., Condon D. J., Crowley J. L.,Gerdes A.,Hanchar J. M.,Horstwood M. S.A.,Morris G. A.,Nasdala L., Norberg N.2008. Plesovice zircon-a new natural reference material for U-Pb and Hf isotopic microanalysis[J].Chemical Geology,249(1):1-35.
Stacey J. S.,Kramers J. D.1975.Approximation of terrestrial lead isotope evolution by a two-stage model[J].Earth and Planetary Science Letters,26(2):207-221.
Symonds R. B., Rose W. I., Bluth G. J. S., Gerlach T. M.1994. Volcanic-gas studies; methods, results, and applications [J].Reviews in Mineralogy and Geochemistry,30(1):1-66.
Taylor H.P.1974. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition[J].Economic geology,69(6):843-883.
USGS (U.S.Geological Survey),1996-2007. Mineral Commodity Summaries 1996-2007 [EB/OL].United States Government Printing Office, Washington:1996-2007. (http://minerals. usgs.gov/minerals/pubs/mcs/)
Werner A. B.T., Sinclair W. D., Amey E.B.1998.International Strategic Mineral Issues Summary Report-Tungsten[M].Washington:US Geological Survey.
Wiedenbeck M.,Alle P., Corfu F., Griffin W. L.,Meier M.,Oberli F., Quadt A.,Roddick J. C, Spiegel W. 1995.Three natural zircon standards for U-Th-Pb, Lu-Hf, trace element and REE analyses[J]. Geostandards Newsletter,19(1):1-23.
Wilkinson J. J.2001. Fluid inclusions in hydrothermal ore deposits[J]. Lithos,55(1-4):229-272.
Williams-Jones A.E.,Heinrich C. A.2005.100th Anniversary special paper:vapor transport of metals and the formation of magmatic-hydrothermal ore deposits[J]. Economic Geology,100(7):1287-1312.
Yang K., Scott S.D.1996.Possible contribution of a metal-rich magmatic fluid to a sea-floor hydrothermal system[J].Nature,383(6599):420-423.
包亚范,刘延军,王鑫春.2008.东昆仑西段巴什尔希花岗岩与白干湖钨锡矿床的关系[J].吉林地质,(3).
蔡德坤.1983.滇东南老君山花岗岩类岩石的形成演化与锡、钨的矿化富集作用[J].云南地质,2(2):102-113.
曹晓峰,吕新彪,何谋春,牛宏,杜保峰,梅微.2009.共生黑钨矿与石英中流体包裹体红外显微对比研究——以瑶岗仙石英脉型钨矿床为例[J].矿床地质,(5):611-620.
陈能松,何蕾,孙敏,王国灿,张克信,孙敏.2002.东昆仑造山带早古生代变质峰期和逆冲构造变形年代的精确限定[J].科学通报,47(8):628-631.带矿床类型、时空分布及多金属成矿作用[J].西北地质,43(4):10-17.
陈培荣,章邦桐.1994.A型花岗岩类研究综述[J].华南地质与矿产,(4):9-14.
陈文,张彦,张岳桥,金贵善,王清利.2006.青藏高原东南缘晚新生代幕式抬升作用的Ar-Ar热年代学证据[J].岩石学报,22(4):867-872.
陈毓川,裴荣富,张宏良等.1989.南岭地区与中生代花岗岩类有关的有色及稀有金属.矿床地质.北京: 地质出版社
谌宏伟,罗照华,莫宣学,张雪亭,王瑾,王秉璋.2006.东昆仑喀雅克登塔格杂岩体的SHRI MP年龄及其地质意义[J].岩石矿物学杂志,25(1):25-32.
池国祥,卢焕章.1991.流体相分离的深度(压力)-温度场特征及其对热液矿床定位的意义[J].矿物学报,11(4):355-362.
陈祥.2007.赣南黄沙脉状钨矿床容矿断裂构造系统成因探讨.中国地质大学(北京)博士学位论文.110p
丰成友,佘宏全,张德全.2009.闽粤赣邻接区主要金属矿床成矿规律及找矿评价[M].北京:地质出版社.
高晓峰,校培喜,谢从瑞,范立勇,过磊,奚仁刚.2010.东昆仑阿牙克库木湖北巴什尔希花岗岩锆石LA-ICP-MSU-Pb定年及其地质意义[J].地质通报,29(7):1001-1008.
高永宝,李文渊.2011.东昆仑造山带祁漫塔格地区白干湖含钨锡矿花岗岩:岩石学、年代学、地球化学及岩石成因[J].地球化学,40(4):324-336.
官容生.1991.滇东南构造岩浆带花岗岩体的含矿性探讨[J].矿物岩石,11(1):92-101.
官容生.1993.滇东南地区各主要花岗岩体基本特征及相互关系[J].云南地质,12(4):373-382.
韩宝福.2007.后碰撞花岗岩类的多样性及其构造环境判别的复杂性[J].地学前缘,14(3):64-72.
何知礼,杜加锋.1996.流体包裹体研究的某些进展与发展趋势[J].地学前缘,3(4):306-312.
胡受奚,季寿元.1962.南岭一钨矿田中钨锰铁矿-石英脉两旁围岩蚀变的研究[J].地质学报,42(2):236-254.
黄小娥,史维全.2007.我国钨矿地质勘查新进展[J].中国钨业.22(3):6-9
华仁民,张文兰,陈培荣,王汝成.2003.赣南大吉山与漂塘花岗岩及有关成矿作用特征对比[J].高校地质学报,9(4):609-619.
吉林省地质调查院.2010.新疆维吾尔自治区若羌县柯可咔尔德钨锡矿床2010年勘探报告[R].吉林:吉林省地质调查院.
江思宏,聂凤军.2006.甘肃北山红尖兵山钨矿床的(?)40Ar-(?)39Ar同位素年代学研究[J].矿床地质,25(1):89-94.
姜春发,王宗起,李锦轶.2000.中央造山带开合构造[M].北京:地质出版社.
姜炜忠,李志兴,时凤霞,赵在胜.2010.东昆仑黑山—白干湖地区Ⅲ级构造单元划分及矿产分布特征[J].吉林地质,29(2):14-15.
康永孚,李崇佑.1991.中国钨矿地质特征、类型及其分布[M].矿床地质,(10)1:19-26.
康永孚,苗树屏,李崇佑等.1994.中国钨矿床.见:中国矿床(中).北京:地质出版社,55-68.
黎敦朋,肖爱芳.2010.祁漫塔格西段白干湖钨锡矿区巴什尔希花岗岩序列及构造环境[J].西北地质,43(4):53-61.
李芳,吕新彪,刘艳荣.2006.红外显微镜在地质学的应用与前景[J].岩矿测试,25(4):355-359.
李光明,沈远超,等.2001.东昆仑祁漫塔格地区华力西期花岗岩地质地球化学特征[J].地质与勘探,37(1):73-78.
李洪茂,时友东,刘忠,王宝金,王泽利,邱希萍.2006.东昆仑山若羌地区白干湖钨锡矿床地质特征及成因[J].地质通报,25(1-2):277-281.
李荣社.2008.昆仑山及邻区地质[M].北京:地质出版社.
李荣社,计文化,赵振明,陈守建,孟勇,于浦生,潘小平.2007.昆仑早古生代造山带研究进展[J].地质通报,26(4):373-382.
李晓峰,毛景文,王义天,王登红.2003.惰性气体同位素和卤素示踪成矿流体来源[J].地质论评,49(5):513-521.
李振兴,许效松,潘桂棠.1995.泛华夏大陆群与东特提斯构造域演化[J].岩相古地理,15(4):1-13.
李振兴,尹福光.2002.东昆仑与西昆仑地质构造对比研究之刍议[J].地质通报,21(11):777-783.
林新多,张德会,章传玲.1986.湖南宜章瑶岗仙黑钨矿石英脉成矿流体性质的探讨[J].地球科学,(3):153-160.
林新多,章传玲,张德会.1987.初论湖南瑶岗仙含钨矿脉及矿化的垂直分带[J].地质论评,33(6):539-546.
刘斌,施名.1999.流体包裹体热力学[M].北京:地质出版社.
刘成东.2008.东昆仑造山带东段花岗岩岩浆混合作用[M].北京:地质出版社.
刘贵忠,李洪茂,王聚胜,张天民,宋成印.2007.新疆东昆仑白干湖钨锡矿田矿化体模型[J].新疆地质,25(2):169-173.
刘宁强.2010.江西大吉山钨矿地区成矿作用发生与发展初步分析[博士]:中国地质大学(北京).
刘琰,邓军,李潮峰,施光海,郑爱力.2007.四川雪宝顶白钨矿稀土地球化学与Sm-Nd同位素定年[J].科学通报,52(16):1923-1929.
刘英俊,马东升.1987.钨的地球化学[M].北京:科学出版社.
刘子峰,崔雅茹,魏微.2007.新疆东昆仑白干湖钨锡矿床地球化学特征[J].吉林地质,26(4):54-60.
柳志青.1980[M].北京:科学出版社.
卢焕章.2011.流体不混溶性和流体包裹体[J].岩石学报,27(5):1253-1261.
卢焕章,范宏瑞,倪培,欧光习,沈昆,张文淮.2004.流体包裹体[M].北京:科学与出版社.
卢焕章,施继锡,喻茨玫.1974.华南某矿区成岩成矿温度的研究[J].地球化学,(3):145-156.
卢焕章,施继锡,喻茨玫,许生蛟.1977.南岭地区各种类型钨矿床的气液包裹体特征和形成温度的研究[J].地球化学,(3):179-193.
罗照华,邓晋福.1999.青海省东昆仑地区晚古生代——早中生代火山活动与区域构造演化[J].现代地质,13(1):51-56.
吕贻峰.1994.国外花岗岩构造研究的某些新进展[J].地质科技情报,13(4):21-25.
马东升.1998.地壳中流体的大规模流动系统及其成矿意义[J].高校地质学报,4(3):250-261.
马东升.2009.钨的地球化学研究进展[J].高校地质学报,15(1):19-34.
马秀娟.大吉山钨矿包裹体地球化学研究-流体包裹体在矿床学和岩石学中的应用[M].北京:科技出版社,1988:65-108
毛景文,李晓峰,张荣华,王义天,英赫,张作衡.2005.深部流体成矿系统[M].北京:中国地质大学出版社.
聂凤军,江思宏,等.2002.北京密云沙厂环斑花岗岩杂岩体黑钨矿钐—钕同位素研究[J].地质论评,48(1):29-33.
潘桂棠,李兴振.1996.东特提斯多弧—盆系统演化模式[J].岩相古地理,16(2):52-65.
潘桂棠,肖庆辉,陆松年,邓晋福,冯益民,张克信,张智勇,王方国,邢光福,郝国杰and others.2009.中国大地构造单元划分[J].中国地质,26(1):1-4.
潘桂棠,徐强,等.2001.青藏高原多岛弧—盆系格局机制[J].矿物岩石,21(3):186-189.
彭建堂,胡瑞忠,赵军红,符亚洲,林源贤.2003.湘西沃溪Au-Sb-W矿床中白钨矿Sm-Nd和石英Ar-Ar定年[J].科学通报,48(18):1976-1981.
青海省地质调查院.2003.青海省地质调查院1:25万布喀达坂峰幅(R)西宁:青海省地质调查院
陕西省地质调查院.2003.新疆维吾尔自治区1:25万阿牙克库木湖幅区域地质调查报告[R].西安:陕西省地质调查院.
申萍,沈远超,李光明,刘铁兵,曾庆栋.2004.新疆阔尔真阔腊金矿床成矿流体包裹体研究[J].岩石学报,20(4):969-976.
石洪召,林方成,张林奎.2009.钨矿床的时空分布及研究现状[J].沉积与特提斯地质,29(4):90-95.
时友东,尹占军,孙兴友.2004.新疆东昆仑白干湖钨锡矿床Ⅲ矿段地质特征[J].吉林地质,23(4):44-48.
谈迎等著.2010.CO2的气源和成藏及其预测[M].合肥:中国科学技术大学出版社.
王宝金,迟效国,刘忠,李宏茂,时友东,李桂芝,张天民.2007.新疆东昆仑白干湖钨地球化学块体的确立及意义[J].地质与勘探,43(5):82-87.
王登红,唐菊兴,应立娟,陈郑辉,许建祥,张家菁,李水如,曾载淋.2010.“五层楼+地下室”找矿模型的适用性及其对深部找矿的意义[J].吉林大学学报:地球科学版,40(4):733-738.
王巧云,胡瑞忠,彭建堂,毕献武,武丽艳,刘华,苏本勋.2007.湖南瑶岗仙钨矿床流体包裹体特征及其意义[J].岩石学报,23(9):2263-2273.
王旭东,倪培,蒋少涌,黄建宝,孙立强.2008.赣南漂塘钨矿流体包裹体研究[J].岩石学报,24(9):2163-2170.
王旭东,倪培,张伯声,王天刚.2010.江西盘古山石英脉型钨矿床流体包裹体研究[J].岩石矿物学杂志,29(5):539-550.
魏绍六,贾宝华,曾钦旺.2006.南岭地区钨矿成矿机理探讨[J].资源调查与环境,27(2):103-109.
吴福元,李献华,杨进辉,郑永飞.2007.花岗岩成因研究的若干问题[J].岩石学报,23(6):1217-1238.
吴锁平,王梅英,戚开静.2007.A型花岗岩研究现状及其述评[J].岩石矿物学杂志,26(1):57-66.
吴元保,郑永飞.2004.锆石成因矿物学研究及其对U-Pb年龄解释的制约[J].科学通报,49(16):1589-1604.
席斌斌,张德会,周利敏,张文淮,王成.2008.江西省全南县大吉山钨矿成矿流体演化特征[J].地质学报,82(7):956-966.
肖庆辉.国外花岗岩体构造研究.1988[M].北京:地质出版社
邢延安,陈殿义.2004.新疆白干湖钨锡矿床简介[J].吉林地质,23(3):64-66.
熊德信,孙晓明,石贵勇,王生伟,高剑锋,薛婷.2006.云南大坪金矿白钨矿微量元素、稀土元素和Sr-Nd同位素组成特征及其意义[J].岩石学报,22(3):733-741.
徐克勤.1957.湘南钨铁锰矿矿区中矽嘎岩型钙钨矿的发现,并论两类矿床在成因上的关系[J].地质学报,(1).
徐克勤,程海.1987.中国钨矿形成的大地构造背景[J].地质找矿论丛,2(3):1-7.
许建祥,曾载淋,王登红,陈郑辉,刘善宝,王成辉,应立娟.2008.赣南钨矿新类型及“五层楼+地下室”找矿模型[J].地质学报,82(7):880-887.
许荣华,BWH.N.,LL. C.1990.拉萨至格尔木的同位素地球化学[M]/中英青藏高原综合地质考察队.青藏高原地质演化.北京:科学出版社.
冶金部南岭钨矿专题组.1985.华南钨矿[M].北京:冶金工业出版社.
易顺华,李珍.1997.侵入接触构造的地质力学研究[J].地质力学学报,3(2):61-65.
袁万明,莫宣学.2000.东昆仑印支期区域构造背影的花岗岩记录[J].地质论评,46(2):203-211.
张德会.1997a.流体的沸腾和混合在热液成矿中的意义[J].地球科学进展,12(6):546-552.
张德会.1997b.成矿流体中金属沉淀机制研究综述[J].地质科技情报,16(3):53-58.
张德会,龚庆杰.2001.初论元素富集成矿的地球化学机理:—以岩浆热液矿床的形成为例[J].地质地球化学,29(3):8-14.
张德会.湖南瑶岗仙黑钨矿床地质特征及其形成机制:[硕士学位论文]。武汉:武汉地质学院,1984
张德全,丰成友,等.2001.柴北缘—东昆仑地区的造山型金矿床[J].矿床地质,20(2):137-146.
张建新,孟繁聪,万渝生,杨经绥,董国安.2003.柴达木盆地南缘金水口群的早古生代构造热事件:锆石U-Pb SHRIMP年龄证据[J].地质通报,22(6):397-404.
张旗,王焰,李承东,王元龙,金惟俊,贾秀勤琴.2006.花岗岩的Sr-Yb分类及其地质意义[J].岩石学报,22(9):2249-2269
张雪亭,杨生德,杨站君.2007.青海省板块构造研究—1:100万青海省大地构造图说明书[M].北京:地质出版社.
张彦,陈文,陈克龙,刘新宇.2006.成岩混层(I/S)Ar-Ar年龄谱型及^39Ar核反冲丢失机理研究——以浙江长兴地区P-T界线粘土岩为例[J].地质论评,52(4):556-561.
中国地质调查局.2002.地质调查进展与成果年报[R].北京:中国地质调查局.
周新民.2007.南岭地区晚中生代花岗岩成因与岩石圈动力学演化[M].北京:科学出版社.
朱焱龄,李崇佑,林运淮.1981.赣南钨矿地质[M].南昌:江西人民出版社.
Anglin C. D., Franklin J. M., Jonasson I. R., Bell K., Hoffman E.1987. Geochemistry of scheelites associated with Archean gold deposits:implications for their direct age determination[J].In current research, Part A:geological Survey of Canada Paper,87:591-596.
Baker T.2002. Emplacement depth and carbon dioxide-rich fluid inclusions in intrusion-related gold deposits[J]. Economic Geology,97(5):1111-1117.
Baker T.,Lang J. R.2001.Fluid inclusion characteristics of intrusion-related gold mineralization, Tombstone-Tungsten magmatic belt, Yukon Territory, Canada[J].Mineralium Deposita, 36(6):563-582.
Brown P. E.1989.FLINCOR; a microcomputer program for the reduction and investigation of fluid-inclusion data[J].American Mineralogist,74(11-12):1390-1393.
Burke E. A. J.2001. Raman microspectrometry of fluid inclusions[J].Lithos,55(1-4):139-158.
Clayton Rn.O'Neil J R,and Mayeda TK,1972.Oxygen isotope exchange between quartz and water,Journal of Geophysical Reseatch.77:3057-3067
Diamond L. W.2001.Review of the systematics of CO2-H2O fluid inclusions[J].Lithos,55(1-4):69-99.
Hall D. L.,Sterner S. M., Bodnar R. J.1988. Freezing point depression of NaCl-KCl-H2O solutions[J]. Economic Geology,83(1):197-202.
Heinrich C. A.2007. Fluid-fluid interactions in magmatic-hydrothermal ore formation[J].Reviews in mineralogy and geochemistry,65(1):363-387.
Heinrich C.A.,Driesner T., Stefansson A.,Seward T. M.2004. Magmatic vapor contraction and the transport of gold from the porphyry environment to epithermal ore deposits[J]. Geology, 32(9):761-764.
Lang J.R.,Baker T.2001.Intrusion-related gold systems:the present level of understanding[J]. Mineralium Deposita,36(6):477-489.
Leigeois J. P.1998. Perface:Some words on the post-collisional magmatism[J]. Lithos,45.
LI Xian-hua, LIU Yu, LI Qiu-li, GUO Chun-hua, CHAMBERLAIN K R.2009. Precise determination of Phanerozoic zircon Pb/Pb age by multicollector SIMS without external standardization[J]. Geochemistry Geophysics Geosystems,10:Q04010, doi:10.1029/2009GC002400.
Lowenstern J. B.2000. A review of the contrasting behavior of two magmatic volatiles:chlorine and carbon dioxide[J]. Journal of Geochemical Exploration,69:287-290.
Lowenstern J. B.2001.Carbon dioxide in magmas and implications for hydrothermal systems[J]. Mineralium Deposita,36(6):490-502.
Pearce J. A.,Harris N. B.W., Tindle A. G.1984.Trace element discrimination diagrams for the tectonic interpretation of granitic rocks[J].Journal of Petrology,25(4):956-983.
Peng B.,Frei R.2004. Nd-Sr-Pb isotopic constraints on metal and fluid sources in W-Sb-Au mineralization at Woxi and Liaojiaping (Western Hunan, China)[J].Mineralium Deposita,39(3):313-327.
Roedder.1984. Fluid inclusions[J]. Reviews in Mineralogy,(12):644.
Slama J., Kosler J., Condon D. J., Crowley J. L.,Gerdes A.,Hanchar J. M.,Horstwood M. S.A.,Morris G. A.,Nasdala L., Norberg N.2008. Plesovice zircon-a new natural reference material for U-Pb and Hf isotopic microanalysis[J].Chemical Geology,249(1):1-35.
Stacey J. S.,Kramers J. D.1975.Approximation of terrestrial lead isotope evolution by a two-stage model[J].Earth and Planetary Science Letters,26(2):207-221.
Symonds R. B., Rose W. I., Bluth G. J. S., Gerlach T. M.1994. Volcanic-gas studies; methods, results, and applications [J].Reviews in Mineralogy and Geochemistry,30(1):1-66.
Taylor H.P.1974. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition[J].Economic geology,69(6):843-883.
USGS (U.S.Geological Survey),1996-2007. Mineral Commodity Summaries 1996-2007 [EB/OL].United States Government Printing Office, Washington:1996-2007. (http://minerals. usgs.gov/minerals/pubs/mcs/)
Werner A. B.T., Sinclair W. D., Amey E.B.1998.International Strategic Mineral Issues Summary Report-Tungsten[M].Washington:US Geological Survey.
Wiedenbeck M.,Alle P., Corfu F., Griffin W. L.,Meier M.,Oberli F., Quadt A.,Roddick J. C, Spiegel W. 1995.Three natural zircon standards for U-Th-Pb, Lu-Hf, trace element and REE analyses[J]. Geostandards Newsletter,19(1):1-23.
Wilkinson J. J.2001. Fluid inclusions in hydrothermal ore deposits[J]. Lithos,55(1-4):229-272.
Williams-Jones A.E.,Heinrich C. A.2005.100th Anniversary special paper:vapor transport of metals and the formation of magmatic-hydrothermal ore deposits[J]. Economic Geology,100(7):1287-1312.
Yang K., Scott S.D.1996.Possible contribution of a metal-rich magmatic fluid to a sea-floor hydrothermal system[J].Nature,383(6599):420-423.
包亚范,刘延军,王鑫春.2008.东昆仑西段巴什尔希花岗岩与白干湖钨锡矿床的关系[J].吉林地质,(3).
蔡德坤.1983.滇东南老君山花岗岩类岩石的形成演化与锡、钨的矿化富集作用[J].云南地质,2(2):102-113.
曹晓峰,吕新彪,何谋春,牛宏,杜保峰,梅微.2009.共生黑钨矿与石英中流体包裹体红外显微对比研究——以瑶岗仙石英脉型钨矿床为例[J].矿床地质,(5):611-620.
陈能松,何蕾,孙敏,王国灿,张克信,孙敏.2002.东昆仑造山带早古生代变质峰期和逆冲构造变形年代的精确限定[J].科学通报,47(8):628-631.带矿床类型、时空分布及多金属成矿作用[J].西北地质,43(4):10-17.
陈培荣,章邦桐.1994.A型花岗岩类研究综述[J].华南地质与矿产,(4):9-14.
陈文,张彦,张岳桥,金贵善,王清利.2006.青藏高原东南缘晚新生代幕式抬升作用的Ar-Ar热年代学证据[J].岩石学报,22(4):867-872.
陈毓川,裴荣富,张宏良等.1989.南岭地区与中生代花岗岩类有关的有色及稀有金属.矿床地质.北京: 地质出版社
谌宏伟,罗照华,莫宣学,张雪亭,王瑾,王秉璋.2006.东昆仑喀雅克登塔格杂岩体的SHRI MP年龄及其地质意义[J].岩石矿物学杂志,25(1):25-32.
池国祥,卢焕章.1991.流体相分离的深度(压力)-温度场特征及其对热液矿床定位的意义[J].矿物学报,11(4):355-362.
陈祥.2007.赣南黄沙脉状钨矿床容矿断裂构造系统成因探讨.中国地质大学(北京)博士学位论文.110p
丰成友,佘宏全,张德全.2009.闽粤赣邻接区主要金属矿床成矿规律及找矿评价[M].北京:地质出版社.
高晓峰,校培喜,谢从瑞,范立勇,过磊,奚仁刚.2010.东昆仑阿牙克库木湖北巴什尔希花岗岩锆石LA-ICP-MSU-Pb定年及其地质意义[J].地质通报,29(7):1001-1008.
高永宝,李文渊.2011.东昆仑造山带祁漫塔格地区白干湖含钨锡矿花岗岩:岩石学、年代学、地球化学及岩石成因[J].地球化学,40(4):324-336.
官容生.1991.滇东南构造岩浆带花岗岩体的含矿性探讨[J].矿物岩石,11(1):92-101.
官容生.1993.滇东南地区各主要花岗岩体基本特征及相互关系[J].云南地质,12(4):373-382.
韩宝福.2007.后碰撞花岗岩类的多样性及其构造环境判别的复杂性[J].地学前缘,14(3):64-72.
何知礼,杜加锋.1996.流体包裹体研究的某些进展与发展趋势[J].地学前缘,3(4):306-312.
胡受奚,季寿元.1962.南岭一钨矿田中钨锰铁矿-石英脉两旁围岩蚀变的研究[J].地质学报,42(2):236-254.
黄小娥,史维全.2007.我国钨矿地质勘查新进展[J].中国钨业.22(3):6-9
华仁民,张文兰,陈培荣,王汝成.2003.赣南大吉山与漂塘花岗岩及有关成矿作用特征对比[J].高校地质学报,9(4):609-619.
吉林省地质调查院.2010.新疆维吾尔自治区若羌县柯可咔尔德钨锡矿床2010年勘探报告[R].吉林:吉林省地质调查院.
江思宏,聂凤军.2006.甘肃北山红尖兵山钨矿床的(?)40Ar-(?)39Ar同位素年代学研究[J].矿床地质,25(1):89-94.
姜春发,王宗起,李锦轶.2000.中央造山带开合构造[M].北京:地质出版社.
姜炜忠,李志兴,时凤霞,赵在胜.2010.东昆仑黑山—白干湖地区Ⅲ级构造单元划分及矿产分布特征[J].吉林地质,29(2):14-15.
康永孚,李崇佑.1991.中国钨矿地质特征、类型及其分布[M].矿床地质,(10)1:19-26.
康永孚,苗树屏,李崇佑等.1994.中国钨矿床.见:中国矿床(中).北京:地质出版社,55-68.
黎敦朋,肖爱芳.2010.祁漫塔格西段白干湖钨锡矿区巴什尔希花岗岩序列及构造环境[J].西北地质,43(4):53-61.
李芳,吕新彪,刘艳荣.2006.红外显微镜在地质学的应用与前景[J].岩矿测试,25(4):355-359.
李光明,沈远超,等.2001.东昆仑祁漫塔格地区华力西期花岗岩地质地球化学特征[J].地质与勘探,37(1):73-78.
李洪茂,时友东,刘忠,王宝金,王泽利,邱希萍.2006.东昆仑山若羌地区白干湖钨锡矿床地质特征及成因[J].地质通报,25(1-2):277-281.
李荣社.2008.昆仑山及邻区地质[M].北京:地质出版社.
李荣社,计文化,赵振明,陈守建,孟勇,于浦生,潘小平.2007.昆仑早古生代造山带研究进展[J].地质通报,26(4):373-382.
李晓峰,毛景文,王义天,王登红.2003.惰性气体同位素和卤素示踪成矿流体来源[J].地质论评,49(5):513-521.
李振兴,许效松,潘桂棠.1995.泛华夏大陆群与东特提斯构造域演化[J].岩相古地理,15(4):1-13.
李振兴,尹福光.2002.东昆仑与西昆仑地质构造对比研究之刍议[J].地质通报,21(11):777-783.
林新多,张德会,章传玲.1986.湖南宜章瑶岗仙黑钨矿石英脉成矿流体性质的探讨[J].地球科学,(3):153-160.
林新多,章传玲,张德会.1987.初论湖南瑶岗仙含钨矿脉及矿化的垂直分带[J].地质论评,33(6):539-546.
刘斌,施名.1999.流体包裹体热力学[M].北京:地质出版社.
刘成东.2008.东昆仑造山带东段花岗岩岩浆混合作用[M].北京:地质出版社.
刘贵忠,李洪茂,王聚胜,张天民,宋成印.2007.新疆东昆仑白干湖钨锡矿田矿化体模型[J].新疆地质,25(2):169-173.
刘宁强.2010.江西大吉山钨矿地区成矿作用发生与发展初步分析[博士]:中国地质大学(北京).
刘琰,邓军,李潮峰,施光海,郑爱力.2007.四川雪宝顶白钨矿稀土地球化学与Sm-Nd同位素定年[J].科学通报,52(16):1923-1929.
刘英俊,马东升.1987.钨的地球化学[M].北京:科学出版社.
刘子峰,崔雅茹,魏微.2007.新疆东昆仑白干湖钨锡矿床地球化学特征[J].吉林地质,26(4):54-60.
柳志青.1980[M].北京:科学出版社.
卢焕章.2011.流体不混溶性和流体包裹体[J].岩石学报,27(5):1253-1261.
卢焕章,范宏瑞,倪培,欧光习,沈昆,张文淮.2004.流体包裹体[M].北京:科学与出版社.
卢焕章,施继锡,喻茨玫.1974.华南某矿区成岩成矿温度的研究[J].地球化学,(3):145-156.
卢焕章,施继锡,喻茨玫,许生蛟.1977.南岭地区各种类型钨矿床的气液包裹体特征和形成温度的研究[J].地球化学,(3):179-193.
罗照华,邓晋福.1999.青海省东昆仑地区晚古生代——早中生代火山活动与区域构造演化[J].现代地质,13(1):51-56.
吕贻峰.1994.国外花岗岩构造研究的某些新进展[J].地质科技情报,13(4):21-25.
马东升.1998.地壳中流体的大规模流动系统及其成矿意义[J].高校地质学报,4(3):250-261.
马东升.2009.钨的地球化学研究进展[J].高校地质学报,15(1):19-34.
马秀娟.大吉山钨矿包裹体地球化学研究-流体包裹体在矿床学和岩石学中的应用[M].北京:科技出版社,1988:65-108
毛景文,李晓峰,张荣华,王义天,英赫,张作衡.2005.深部流体成矿系统[M].北京:中国地质大学出版社.
聂凤军,江思宏,等.2002.北京密云沙厂环斑花岗岩杂岩体黑钨矿钐—钕同位素研究[J].地质论评,48(1):29-33.
潘桂棠,李兴振.1996.东特提斯多弧—盆系统演化模式[J].岩相古地理,16(2):52-65.
潘桂棠,肖庆辉,陆松年,邓晋福,冯益民,张克信,张智勇,王方国,邢光福,郝国杰and others.2009.中国大地构造单元划分[J].中国地质,26(1):1-4.
潘桂棠,徐强,等.2001.青藏高原多岛弧—盆系格局机制[J].矿物岩石,21(3):186-189.
彭建堂,胡瑞忠,赵军红,符亚洲,林源贤.2003.湘西沃溪Au-Sb-W矿床中白钨矿Sm-Nd和石英Ar-Ar定年[J].科学通报,48(18):1976-1981.
青海省地质调查院.2003.青海省地质调查院1:25万布喀达坂峰幅(R)西宁:青海省地质调查院
陕西省地质调查院.2003.新疆维吾尔自治区1:25万阿牙克库木湖幅区域地质调查报告[R].西安:陕西省地质调查院.
申萍,沈远超,李光明,刘铁兵,曾庆栋.2004.新疆阔尔真阔腊金矿床成矿流体包裹体研究[J].岩石学报,20(4):969-976.
石洪召,林方成,张林奎.2009.钨矿床的时空分布及研究现状[J].沉积与特提斯地质,29(4):90-95.
时友东,尹占军,孙兴友.2004.新疆东昆仑白干湖钨锡矿床Ⅲ矿段地质特征[J].吉林地质,23(4):44-48.
谈迎等著.2010.CO2的气源和成藏及其预测[M].合肥:中国科学技术大学出版社.
王宝金,迟效国,刘忠,李宏茂,时友东,李桂芝,张天民.2007.新疆东昆仑白干湖钨地球化学块体的确立及意义[J].地质与勘探,43(5):82-87.
王登红,唐菊兴,应立娟,陈郑辉,许建祥,张家菁,李水如,曾载淋.2010.“五层楼+地下室”找矿模型的适用性及其对深部找矿的意义[J].吉林大学学报:地球科学版,40(4):733-738.
王巧云,胡瑞忠,彭建堂,毕献武,武丽艳,刘华,苏本勋.2007.湖南瑶岗仙钨矿床流体包裹体特征及其意义[J].岩石学报,23(9):2263-2273.
王旭东,倪培,蒋少涌,黄建宝,孙立强.2008.赣南漂塘钨矿流体包裹体研究[J].岩石学报,24(9):2163-2170.
王旭东,倪培,张伯声,王天刚.2010.江西盘古山石英脉型钨矿床流体包裹体研究[J].岩石矿物学杂志,29(5):539-550.
魏绍六,贾宝华,曾钦旺.2006.南岭地区钨矿成矿机理探讨[J].资源调查与环境,27(2):103-109.
吴福元,李献华,杨进辉,郑永飞.2007.花岗岩成因研究的若干问题[J].岩石学报,23(6):1217-1238.
吴锁平,王梅英,戚开静.2007.A型花岗岩研究现状及其述评[J].岩石矿物学杂志,26(1):57-66.
吴元保,郑永飞.2004.锆石成因矿物学研究及其对U-Pb年龄解释的制约[J].科学通报,49(16):1589-1604.
席斌斌,张德会,周利敏,张文淮,王成.2008.江西省全南县大吉山钨矿成矿流体演化特征[J].地质学报,82(7):956-966.
肖庆辉.国外花岗岩体构造研究.1988[M].北京:地质出版社
邢延安,陈殿义.2004.新疆白干湖钨锡矿床简介[J].吉林地质,23(3):64-66.
熊德信,孙晓明,石贵勇,王生伟,高剑锋,薛婷.2006.云南大坪金矿白钨矿微量元素、稀土元素和Sr-Nd同位素组成特征及其意义[J].岩石学报,22(3):733-741.
徐克勤.1957.湘南钨铁锰矿矿区中矽嘎岩型钙钨矿的发现,并论两类矿床在成因上的关系[J].地质学报,(1).
徐克勤,程海.1987.中国钨矿形成的大地构造背景[J].地质找矿论丛,2(3):1-7.
许建祥,曾载淋,王登红,陈郑辉,刘善宝,王成辉,应立娟.2008.赣南钨矿新类型及“五层楼+地下室”找矿模型[J].地质学报,82(7):880-887.
许荣华,BWH.N.,LL. C.1990.拉萨至格尔木的同位素地球化学[M]/中英青藏高原综合地质考察队.青藏高原地质演化.北京:科学出版社.
冶金部南岭钨矿专题组.1985.华南钨矿[M].北京:冶金工业出版社.
易顺华,李珍.1997.侵入接触构造的地质力学研究[J].地质力学学报,3(2):61-65.
袁万明,莫宣学.2000.东昆仑印支期区域构造背影的花岗岩记录[J].地质论评,46(2):203-211.
张德会.1997a.流体的沸腾和混合在热液成矿中的意义[J].地球科学进展,12(6):546-552.
张德会.1997b.成矿流体中金属沉淀机制研究综述[J].地质科技情报,16(3):53-58.
张德会,龚庆杰.2001.初论元素富集成矿的地球化学机理:—以岩浆热液矿床的形成为例[J].地质地球化学,29(3):8-14.
张德会.湖南瑶岗仙黑钨矿床地质特征及其形成机制:[硕士学位论文]。武汉:武汉地质学院,1984
张德全,丰成友,等.2001.柴北缘—东昆仑地区的造山型金矿床[J].矿床地质,20(2):137-146.
张建新,孟繁聪,万渝生,杨经绥,董国安.2003.柴达木盆地南缘金水口群的早古生代构造热事件:锆石U-Pb SHRIMP年龄证据[J].地质通报,22(6):397-404.
张旗,王焰,李承东,王元龙,金惟俊,贾秀勤琴.2006.花岗岩的Sr-Yb分类及其地质意义[J].岩石学报,22(9):2249-2269
张雪亭,杨生德,杨站君.2007.青海省板块构造研究—1:100万青海省大地构造图说明书[M].北京:地质出版社.
张彦,陈文,陈克龙,刘新宇.2006.成岩混层(I/S)Ar-Ar年龄谱型及^39Ar核反冲丢失机理研究——以浙江长兴地区P-T界线粘土岩为例[J].地质论评,52(4):556-561.
中国地质调查局.2002.地质调查进展与成果年报[R].北京:中国地质调查局.
周新民.2007.南岭地区晚中生代花岗岩成因与岩石圈动力学演化[M].北京:科学出版社.
朱焱龄,李崇佑,林运淮.1981.赣南钨矿地质[M].南昌:江西人民出版社.
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