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ZHANG Jing CHEN Yanjing QI Jinping GE Jun State Key Laboratory of Geological Process Mineral Resources China University of Geosciences Beijing China Key Laboratory of Metallogenic Dynamics Guangzhou Institute of Geochemistry the Chinese Academy of Sciences Guangzhou China 《《地质学报》英文版》2009,83(2)
The Tongbai-East Qinling Mountains,an important part of the Central orogenic belt,is one of the most important metallogenic belts in China and contains lots of orogenic-type and VMS-type (Volcanogenic Massive Sulfide type)metallogenic systems.The Dahe and Shuidongling VMS-type Cu-Zn deposits,located in the Erlangping Group in Tongbai and East Qinling Mountains,respectively, show similar geological and geochemical features.The Huoshenmiao Formation in the East Qinling region and the Liushanyan Formation i... 相似文献
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桐柏山区的围山城金银成矿带包括破山特大型银矿、银洞坡大型金矿、银洞岭大型银多金属矿床及一些矿点,所有矿床赋存于上元古界歪头山组地层,并具有层控特征。矿石矿物的铅同位素组成为206Pb/204Pb=16.753~17.216,207Pb/204Pb=15.417~15.638,208Pb/204Pb=38.251~39.050;与歪头山组地层的铅同位素组成一致,而与桐柏地区的其他地层、岩体差别较大,表明成矿物质来自赋矿地层歪头山组。围山城成矿带应属于典型的层控造山型金银成矿系统,它形成于中生代扬子与华北板块的陆陆碰撞造山过程,碰撞造山期间的下插板片变质脱水诱发了矿带内流体成矿系统的发育,强烈的流体-岩石相互作用使歪头山组内的成矿物质被萃取、迁移、聚集到碳质绢云片岩层。 相似文献
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河南破山银矿床地质地球化学特征及成因研究 总被引:5,自引:0,他引:5
破山特大型银矿床位于桐柏围山城金银多金属矿带的西端。矿床赋存在新元卉界歪头山组上部的炭质绢云石英片岩中,矿体产出受地层和褶皱构造双重控制,多呈似层状、脉状和透镜状,矿石以蚀变岩型矿石为主。成矿流体属于中温、低盐度、低密度、富CO2的K^+-SO4^2-型流体,成矿早中阶段以变质流体为主,晚阶段逐渐演化为以大气水为主。成矿物质主要来自于歪头山组地层。热液绢云母和云煌岩脉的钾氩年龄分别为103.6Ma和134Ma,指示矿床形成于早白垩世,即秦岭一桐柏地区的构造环境从挤压向伸展转变的构造背景下。 相似文献
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河南银洞沟造山型银矿床碳硫铅同位素地球化学 总被引:19,自引:8,他引:11
河南内乡县银洞沟大型脉状银多金属矿床产于北秦岭造山带朱夏断裂北侧的二郎坪地体内,含矿围岩是二郎坪群火山岩-碎屑岩建造,矿体定位于断裂构造带内,产状受断裂构造控制,矿石组构、矿物组合、围岩蚀变类型和分带等地质特征均与典型造山型金矿一致,应属造山型银矿.矿床硫化物δ~(34)S介于+4.7~+8.1‰,高于有机物和岩浆岩.流体包裹体中CO_2的δ~(13)C介于-0.2~+0.9‰,与海相碳酸盐一致,高于其它所有地质体.矿石硫化(206)Pb/~(204)Pb=18.2026~18.4462,~(207)Pb/~(204)Pb=15.5835~15.7739,~(208)Pb/~(204)Pb=38.5478~39.0890,显示铀铅富集,钍铅微弱亏损.这些同位素地球化学特征均指示夹杂沉积硫酸盐的碳酸盐-碎屑岩沉积建造是最为理想的物源,对比研究东秦岭北坡相关地质单元,认为成矿物质和流体主要来自二郎坪群和秦岭群,尤其是雁岭沟组含碳酸盐岩地层对于成矿流体和物质的贡献不可替代.中生代华北与华南板块碰撞造山过程中,秦岭群沿朱夏断裂向北陆内俯冲到二郎坪地体之下,并通过俯冲变质脱水而为银洞沟矿床的形成提供了大量成矿物质和流体.朱夏断裂北侧依次出现银洞沟银矿、许瑶沟金矿、松垛隐伏花岗岩基、栾川斑岩钼矿带,构造-成岩-成矿空间格局与CMF模式(碰撞造山成岩成矿和流体作用模式)完全一致,证明了CMF模式的科学性和普适性和同位素示踪成矿物质和流体来源的有效性.银洞沟矿床的发现和研究结果证实了前人预测的朱夏断裂北侧"桑坪-米坪-许瑶沟铜金铅锌银等多金属矿化带"的客观存在,该带应作为银金多金属矿床勘查的重点区带. 相似文献
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湖北银洞沟矿床是中国为数不多的较为典型的大型银矿床。文中系统总结了该矿床的地质特征,初步提出了矿床的成因类型。研究结果表明:银洞沟矿床产于秦岭造山带东南部武当群变质火山岩中,矿体受韧性剪切带控制,矿石类型主要为石英脉型和少量蚀变岩型,围岩蚀变矿物组合主要为石英、铁白云石、白云母、钠长石、绿泥石、黄铁矿等,成矿流体特征为低盐度、低密度、富含CO2±CH4±N2的水溶液,矿床上部为低品位银金矿体,中部为高品位银金矿体和少量铅锌矿体,深部银品位降低,金品位增高,同时出现较厚大铅锌矿体。其地质特征与典型的造山型矿床一致,表明其为一造山型银矿床,矿床矿化分带符合造山型矿床成矿模式——地壳连续模型,因此应该充分重视寻找矿山深部金、铅、锌、铜、钼等接替资源。 相似文献
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河南桐柏围山城层控金银成矿带同位素地球化学 总被引:8,自引:2,他引:6
河南省桐柏山区的围山城金银成矿带包括破山特大型银矿、银洞坡大型金矿、银洞岭大型银多金属矿床及一些矿点,赋矿地层是新元古界歪头山组,矿体产状与地层产状一致,形态呈似层状、鞍状或透镜状,层控特征显著。氢-氧-碳同位素地球化学研究指示早、中阶段的成矿流体主要为变质水,晚阶段有大量大气降水加入成矿流体系统。碳-硫-铅同位素指示成矿物质来自于歪头山组地层;钾-氩同位素表明成矿作用(100~140Ma)发生在秦岭陆陆碰撞造山的高峰期之后碰撞挤压向伸展转变的背景下。综合考虑矿带的成矿流体来源、成矿物质来源以及矿床地质特征,认为围山城成矿带属典型的层控造山型金银成矿系统,形成于中生代扬子与华北板块的陆陆碰撞造山体制。 相似文献
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北秦岭构造带广泛发育与古生代洋壳俯冲和碰撞造山有关的岩浆活动以及与造山过程有关的变质作用,但古生代热液脉型矿床在北秦岭构造带少见报道。银洞沟银金多金属矿为北秦岭构造带东部的一处中型热液脉型矿床,本文通过对该矿床赋矿围岩和含矿石英脉中锆石开展LA- MC- ICP- MS U- Pb测年和锆石成因研究,确定了矿床的形成时代,并探讨了矿床的成矿动力学背景。结果表明赋矿围岩黑云母二长花岗岩的形成时代为431. 4±2. 1 Ma,含矿石英脉中锆石结晶年龄为419. 4±5. 9 Ma,石英脉中锆石的岩相学、锆石中矿物和流体包裹体及锆石微量元素研究表明419. 4 Ma代表矿床的形成时代。结合前人的研究结果,确定银洞沟银金多金属矿为形成于晚志留世的造山型矿床,成矿作用与碰撞期后~420 Ma的变质作用密切相关,成矿流体来源于地层的变质脱水,成矿物质主要来源于秦岭岩群和二郎坪群。 相似文献
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老洞坡银矿床位于围山城成矿带东延部,出露地层由下古生界大栗树组(Pz1d)和上古生界歪头山组(Pt3w)组成。老洞坡银矿体的发现显示歪头山组地层上、中、下三部均为含矿层,银矿体受朱庄背斜,歪头山组下部第五岩性段和构造控制。查明该矿床的原、次生地球化学异常特征,将老洞坡银矿床与破山、银洞坡银矿床的地质地球化学特征进行对比研究,在指导找矿上具实际意义。 相似文献
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LA-ICP-MS trace element analysis of pyrite from the Xiaoqinling gold district, China: Implications for ore genesis 总被引:7,自引:0,他引:7
Hai-Xiang Zhao Hartwig E. Frimmel Shao-Yong Jiang Bao-Zhang Dai 《Ore Geology Reviews》2011,43(1):142-153
The Xiaoqinling district, the second largest gold producing district in China, is located on the southern margin of the North China Craton. It consists of three ore belts, namely, the northern ore belt, the middle ore belt and the southern ore belt. Pyrite from the Dahu gold deposit in the northern ore belt and Wenyu and Yinxin gold deposits in the southern ore belt were investigated using a combination of ore microscopy and in-situ laser-ablation inductively-coupled plasma-mass spectrometry (LA-ICP-MS). A range of trace elements was analyzed, including Au, Te, Ag, Pb, Bi, Cu, Co, Ni, Zn, Mo, Hg, As and Si. The results show that there are no systematic differences between the trace element compositions of pyrite in the three deposits from different ore belts. In general, Au concentrations in pyrite are low (from < 0.01 ppm to 2.2 ppm) but Ni concentrations are rather high (up to 8425 ppm). A four-stage mineralization process is indicated by microscopic and field observations and this can be related to the systematic trace element differences between distinct generations of pyrite. Stage I precedes the main gold mineralization stage; pyrite of this stage has the lowest Au concentrations. Stages II and III contributed most of the gold to the ore-forming system. The corresponding pyrite yielded the highest concentrations of Au and Ni. Our microscopic observations suggest that pyrite in the main gold mineralization stage precipitated simultaneously with molybdenite that has been previously dated as Indosinian (~ 218 Ma by Re–Os molybdenite dating), indicating the Indosinian as the main gold mineralization stage. The Indosinian mineralization age and the geological and geochemical features of these gold deposits (e.g., low salinity, CO2-rich ore fluids; spatial association with large-scale compressional structures of the Qinling orogen; δ18O and δD data suggestive of mixing between metamorphic and meteoric waters; δ34S and Pb-isotopic data that point to a mixed crustal-mantle source) all point to typical orogenic-type gold deposits. High Ni concentrations (up to 8425 ppm) of pyrite possibly linked to deep-seated mafic/ultramafic metamorphic rocks provide further evidence on the orogenic gold deposit affinity, but against the model of a granitic derivation of the mineralizing fluid as previously suggested by some workers. Generally low Au concentration in pyrite is also consistent with those from worldwide orogenic gold deposits. Therefore, the gold mineralization in the Xiaoqinling district is described as orogenic type, and is probably related to Indosinian collision between the North China Craton and the Yangtze Craton. 相似文献
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鄂西北地区指湖北省武当山及其西北部等地,位于青峰断裂北侧,是秦岭成矿带的重要组成部分,以产银、金等多金属而闻名,蕴含了银洞沟、许家坡、佘家院、六斗等大中型银金(铅锌)或金(锑)矿床。根据区内矿床分布特征及控制因素,以十堰—鲍峡断裂为界将其划分为北带与南带。北带多以金、金锑矿床为主,沿郧阳—郧西断裂两侧分布,矿床多产在上覆陡山沱组地层和古生界地层中;南带主要有银洞沟银金矿床、许家坡金银矿床,矿床集中产于新元古界武当山群。区内矿床均受NW向韧性韧脆性剪切带及其次级断裂控制。碳氢氧同位素组成显示区内银金、金矿床成矿流体以变质热液为主,后期混入了大气降水,而金锑矿床可能为大气降水主导。硫同位素组成显示成矿流体的区域活动性和地层硫源特征。根据成矿元素的富集特征,下伏武当山群Cu、Pb、Zn、Au、Ag元素富集,在上覆陡山沱组、灯影组及古生界地层中依次出现Ag-Au、Au-Ag、Au、Au-Sb矿床,而在研究区西部的陕西境内泥盆纪地层有大量的Au-Sb、Hg-Sb矿。区内成矿元素的垂向分布特征符合地壳连续模式,矿床形成与地层本身具有较高丰度有密切联系,并在构造控制下就位。结合矿床地质、成矿流体及成矿时代,认为鄂西北地区银金、金、金锑矿床是形成于三叠纪古特提斯洋缝合过程中洋陆增生体制下的造山型矿床。 相似文献
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河南省桐柏银洞岭银矿床地质地球化学特征 总被引:6,自引:0,他引:6
银洞岭银矿床属变质碎屑岩型银(金)矿床, 其成矿元素含量变化与歪头山岩组地层层序、岩石类型密切相关, 歪头山岩组下部变粒岩、云母石英片岩Ag含量相对较高, 成为银矿体的直接赋矿围岩;蚀变作用导致成矿元素显著带入, 而对稀土元素的迁移影响不大;成矿热液的运移以渗流作用为主、渗透作用为辅;通过对银洞岭银矿床地质地球化学评价标志的建立, 为该类型矿床的普查评价起到借鉴作用。 相似文献
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秦岭造山带黑色岩系划分为南、北、中三个带,北带分布于北秦岭,以秦岭杂岩为基底的岛弧火山岩与花岗岩带到二郎坪弧后边缘海盆带,形成于活动大陆边缘类似的沟、弧、盆构造体系,产出沉积-变质-构造-热液改造型镍-钼小型矿床.中带分布于南秦岭北部,环绕岛链古隆起形成深水-半深水滞留断陷局限盆地,发育与热水沉积有关的黑色岩系,赋存沉积轻微改造型超大型钒矿床和沉积-构造-热液改造型大型金-钒矿床.南带分布于南秦岭南部,扬子板块北缘早古生代沉积区局部拉张环境发育裂谷式断陷盆地,发育巨厚的硅质-泥质-重晶石互层岩系,形成沉积改造中型含钼-钒矿床和热水沉积大型毒重石-重晶石矿床等.解剖了秦岭黑色岩系容矿的典型矿床特征与成矿作用,划分了矿床成因类型,建立了黑色岩系容矿的金属矿床成矿系列. 相似文献
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南秦岭山阳-柞水矿集区构造-岩浆-成矿作用 总被引:9,自引:2,他引:7
山阳-柞水矿集区是南秦岭成矿带主要矿集区之一。从新元古代到晚侏罗世-早白垩世,山阳-柞水地区经历了洋壳俯冲和陆陆碰撞的构造演化,在演化的不同阶段形成了不同矿化类型、矿化组合的Cu、PbZn、Ag、Fe、Mo、Au矿床。新元古代时期,由于洋壳的俯冲作用,山阳-柞水地区形成了与基性岩有关的钛磁铁矿;泥盆纪-二叠纪时期,古秦岭洋消减形成山阳-柞水弧前盆地的同时,也形成一系列沉积型Fe、Ag、PbZn矿床;三叠纪时期,华北、扬子板块全面碰撞并形成了与碰撞作用密切相关的晚三叠世斑岩型Mo矿和造山型Au矿;晚侏罗世-早白垩世时期,则形成了碰撞后伸展环境下的矽卡岩-斑岩型CuMo-Au矿床。山阳-柞水矿集区内的各种时代和类型的矿床是秦岭造山带不同阶段的构造-岩浆活动的产物,对真实、客观的理解秦岭地区的构造演化具有重要意义。 相似文献
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东秦岭(河南段)二郎坪群铜多金属成矿环境及成矿效应 总被引:6,自引:0,他引:6
二郎坪群位于北秦岭造山带中,在二郎坪群这套火山—沉积岩系中,含有在河南省占有重要地位的铜多金属矿。文章通过对二郎坪群的沉积建造特征、变基性火山岩的形成环境和岩浆来源特征的研究,认为二郎坪群形成于弧后盆地环境,其盆地规模和岩浆来源在盆地东西方向上存在差异,而铜多金属矿床成矿作用与二郎坪群的形成环境和变基性火山岩岩浆来源有着紧密的内在联系。二郎坪群弧后盆地在海底喷流作用下形成了不同成矿元素组合的铜-锌型和铅-锌型两种矿床类型。 相似文献
17.
Ore Geology, Fluid Geochemistry and Genesis of the Shanggong Gold Deposit, Eastern Qinling Orogen, China 总被引:27,自引:0,他引:27
Abstract. The Shanggong Au deposit in the Xiong'er Terrane, East Qinling, has reserves of about 30 t Au, making it one of the largest orogenic‐type Au deposits hosted in volcanic rocks in China. The deposit is hosted in the andesitic assemblage of the Xiong'er Group of 1.85?1.4 Ga. Three stages of hydrothermal ore‐forming processes are recognized, Early (E), Middle (M) and Late (L), characterised by quartz‐pyrite, polymetallic sulfides and carbonate‐quartz, respectively. Homogenization temperatures of fluid inclusions are between 380‐320d?C for the E‐stage, 300‐220d?C for the M‐stage and 200‐120d?C for the L‐stage. The composition of fluid inclusions changed from CO2‐rich in the E‐stage to CO2‐poor L‐stage. The M‐stage fluid has the highest contents of cations and anions (e.g., SO42‐, Cl1, K+), the highest (K+Na)/(Mg+Ca) and lowest CO2/H2O ratios, which probably resulted from CO2 phase separation. This, together with the alkaline and reducing conditions, as indicated by highest pH and lowest Eh values, is most conducive to the deposition of polymetallic sulfides and native elements such as Au, Ag and Te. H‐O isotope systematics indicate that ore fluids evolved from deep‐sourced through to shallow‐sourced, with the M‐stage being a mixing phase of these two fluid‐systems. Nineteen δ18OW values, from 4.2 to 13.4 %o, averaging 8.1 %o, suggest that the E‐stage fluids derived from metamorphic devolatilization of sedimentary rocks at depth. Comparison of the H‐O isotope systematics between the Shanggong deposit and the main lithologies in the Xiong'er Terrane, shows that neither these nor the underlying lower crust and mantle, or combinations thereof, could be considered as the source of ore fluids and metals for the Shanggong Au deposit. Instead, a source which meets the isotopic constraints, is a carbonaceous carbonate‐sandstone‐shale‐chert (CSC) sequence, which is present in the Guandaokou and Luanchuan Groups in the south of the Xiong'er Terrane. This conclusion is supported by thirteen high δ18O values of the Meso‐Neoproterozoic strata south of the Machaoying fault, and the high δ18OW values calculated for their possibly metamorphic fluids. It can be also supported by previous observation that the Guandaokou and Luanchuan Groups were underthrust beneath the Xiong'er Terrane, during the Mesozoic collision between the Yangtze and Sinokorean continents. Available isotope ages, together with geological field data, constrain the timing of the Au metallogenesis between 250?110 Ma. This metallogenesis and associated granitic magmatism, can be related to the Yangtze‐Sinokorean continental collision that resulted in the formation of the Qinling Orogen. This collision event progressed from early compression (Triassic to Early Jurassic), through middle compression‐to‐extension transition (Late Jurassic to Early Cretaceous), to late extension (Cretaceous). These three stages in the evolution of the Qinling Orogen form the basis of an ore genesis model that combines collisional orogeny, metallogeny and fluid flow (CMF model). These three evolutionary stages correspond to the three‐stages of ore‐forming fluids of the Shanggong Au deposit. We conclude that the formation of the Shanggong Au deposit is a result of the Mesozoic northward intracontinental A‐type subduction along the Machaoying fault during Yangtze‐Sinokorean continental collision, which led to the metamorphic devolatilization of the CSC sequence, thereby providing both fluids and metals. 相似文献
18.
滇西大坪金矿床地质特征及成因初探 总被引:19,自引:18,他引:1
大坪金矿床被视为哀牢山造山带南段最典型的造山型金矿,但其诸多地质特征明显不同于国外典型造山型金矿床,而呈现出与浅成低温热液型金矿床的一致性.区域上,脉型金铜铅银矿床的产出与中酸性侵入岩及中基性火山岩密切相关.大坪金矿床形成于主要赋矿的桃家寨闪长岩侵位之后约800Ma的新生代构造-岩浆热事件中,金矿床是区域尺度伸展和转换拉伸应力体制的产物;成矿作用过程中,研究区构造动力体制发生了转换,主成矿期容矿断裂带显示为张剪性正断层性质.矿脉多(55条)、薄(0.2~0.8m)、长(200 ~ 1500m)、陡(56°~ 85°)、延深大(约700m),且近平行成带产出;矿体中Au品位高(超过10×10-6),Au/Ag低(o.1 ~o.5),且伴生Pb、Cu、Ag.矿石的充填型结构构造和矿物共生组合指示矿脉形成温度低、深度浅;矿化-蚀变样式以及蛋白石和氧化矿的出现表明成矿体系处于开放的氧化环境,成矿后保存良好.大坪金矿床这种特殊的地质特征可能与其复杂的区域构造背景及成矿演化过程密切相关,金矿床虽然具有造山型金矿的基本特征,但在成矿作用晚期,矿床浅部叠加了浅成低温热液型金铜铅银成矿作用.即大坪金矿床属于深部造山型+浅部低温热液型矿床套叠组合,成矿体系保存完整,现发现的均为浅部矿体,深部找矿潜力巨大. 相似文献
19.
豫西银家沟硫铁多金属矿床Re-Os和40Ar-39Ar年龄及其地质意义 总被引:4,自引:1,他引:3
河南省银家沟硫铁多金属矿床位于华北克拉通南缘的华熊地块内,是东秦岭地区最大的硫铁多金属矿床,以其硫铁矿储量大及共、伴生元素复杂区别于东秦岭其他以钼为主的矿床.矿化在空间上呈规律性的带状分布,从岩体内向外,依次出现斑岩型钼矿体→斑岩型硫铁矿体→矽卡岩型铁矿体、钼矿体→矽卡岩型硫铁、铜、锌、金矿体→脉型铅、锌、银矿体.选取5件接触带矽卡岩型钼矿体中的辉钼矿样品进行Re-Os同位素定年,获得(142.9±2.1) Ma~(143.7±2.3) Ma的模式年龄,加权平均值为(143.4±0.9) Ma(MSWD=0.071),等时线年龄为(140.0±18.0) Ma(2σ,MSWD=0.095),将(143.4±0.9) Ma认作辉钼矿的结晶年龄,表明银家沟矿床矽卡岩型矿体形成于约143 Ma前;选取1件硅化、绢云母化、黄铁矿化、辉钼矿化钾长花岗斑岩中的绢云母样品定年,获得40Ar-39Ar坪年龄为(143.6±1.4) Ma,相应的39 Ar/36 Ar-40 Ar/39Ar等时线年龄为(143.0±2.0) Ma(MSWD=0.13),将(143.0±2.0)Ma认作绢云母的Ar封闭年龄,表明银家沟矿床斑岩型矿化亦发生在约143Ma前.本次辉钼矿Re-Os和绢云母40Ar-39A定年结果表明,银家沟矽卡岩型和斑岩型矿体均形成于早白垩世初期.银家沟矿床辉钼矿的ω(Re)在38.5×10-6~43.2×10-6之间,成矿物质主要来自由火成物质组成的宽坪群和二郎坪群,成矿与矿区内的钾长花岗斑岩有关.结合前人对东秦岭造山带中生代期间地球动力学背景的研究成果,笔者认为银家沟矿床形成于EW向构造体制向NNE向构造体制大转换阶段,即形成于挤压体制向伸展体制转换的背景. 相似文献
20.
The Bianbianshan deposit, the unique gold-polymetal (Au-Ag-Cu-Pb-Zn) veined deposit of the polymetal metallogenic belt of the southern segment of Da Hinggan Mountains mineral province, is located at the southern part of the Hercynian fold belt of the south segment of Da Hinggan Mountains mineral province, NE China. Ores at the Bianbianshan deposit occur within Cretaceous andesite and rhyolite in the form of gold-bearing quartz veins and veinlet groups containing native gold, electrum, pyrite, chalcopyrite, galena and sphalerite. The deposit is hosted by structurally controlled faults associated with intense hydrothermal alteration. The typical alteration assemblage is sericite + chlorite + calcite + quartz, with an inner pyrite - sericite - quartz zone and an outer seicite - chlorite - calcite - epidote zone between orebodies and wall rocks. δ34 S values of 17 sulfides from ores changing from –1.67 to +0.49‰ with average of –0.49‰, are similar to δ34 S values of magmatic or igneous sulfide sulfur. 206Pb/204Pb, 207Pb/204Pb and 208Pb/ 204Pb data of sulfide from ores range within 17.66–17.75, 15.50–15.60, and 37.64–38.00, respectively. These sulfur and lead isotope compositions imply that ore-forming materials might mainly originate from deep sources. H and O isotope study of quartz from ore-bearing veins indicate a mixed source of deep-seated magmatic water and shallower meteoric water. The ore formations resulted from a combination of hydrothermal fluid mixing and a structural setting favoring gold-polymetal deposition. Fluid mixing was possibly the key factor resulting in Au-Ag-Cu-Pb-Zn deposition in the deposit. The metallogenesis of the Bianbianshan deposit may have a relationship with the Cretaceous volcanic-subvolcanic magmatic activity, and formed during the late stage of the crust thinning of North China. 相似文献