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三江特提斯兰坪盆地构造-流体-成矿系统 总被引:6,自引:5,他引:1
西南三江中段兰坪地区经历了复杂的碰撞造山过程,导致成矿时间长、强度大、作用多样,复合叠加成矿突出;碰撞造山时空演化格架和成矿作用已有深入探索,而叠加成矿作用及其对碰撞造山过程的响应,构造控矿样式,及金属富集机理尚需研究。本文以碰撞造山过程与成矿系统研究为基础,选取金顶和金满等矿床为重点解剖对象,以盆地卤水和热液铅锌铜银成矿作用为主线,利用锆石LA-ICP-MS U-Pb和流体包裹体测试分析手段,解析兰坪盆地构造-流体-成矿系统。利用锆石U-Pb同位素定年获得兰坪盆地西侧片麻质花岗岩和二长花岗岩的上交点年龄和加权平均年龄为1067±20Ma和206±1Ma,分别代表了基底岩石前寒武时期变质事件的年龄,以及昌宁-孟连古特提斯洋后碰撞造山事件的年龄。在此基础上,构建了兰坪盆地的前寒武盆地基底形成、中二叠世-中三叠世前陆盆地、晚三叠世裂谷盆地、侏罗纪-白垩纪坳陷盆地、古新世-早渐新世前陆盆地和晚渐新世-中新世走滑拉分盆地等复杂的转化过程。三江特提斯兰坪盆地发育3个与碰撞造山盆地有关的Pb-ZnCu-Ag-Au-Sb-Hg成矿系统:(1)中低温热液脉型Cu-Ag多金属成矿系统,以金满-连城铜钼矿床为代表。成矿铜和铅锌矿化两期叠加,集中于早始新世(56~46Ma)和渐新世-中新世(32~21Ma)。成矿流体盐度变化于0.88%~20.51%NaC leqv之间,成矿温度较低,通常在210~270℃,显示以低温高盐度的盆地卤水为主的特征,可能受到来自富CO2的变质流体影响;(2)浅成低温热液Sb-Au-Hg-As多金属成矿系统,以笔架山锑矿床为代表。成矿时间集中于中-晚始新世。成矿流体盐度6.0%NaC leqv,成矿温度较低,通常在145~200℃,显示以大气降水为主的特征;(3)密西西比河谷型Pb-Zn多金属成矿系统,以金顶超大型铅锌矿床为代表。成矿时间集中于32~21Ma之间。成矿流体盐度变化于1.6%~18%NaC leqv之间,成矿温度较低,通常在80~190℃,显示以低温高盐度的盆地卤水为主的特征,可能有大气降水的贡献。文章最后解析了兰坪盆地构造-流体-成矿过程。研究对兰坪地区盆地卤水–岩浆热液型铅锌铜银成矿系统认识,为大陆碰撞过程及叠加成矿作用进一步研究提供理论支撑。 相似文献
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滇西兰坪盆地茅草坪脉状Cu矿床流体包裹体和稳定同位素地球化学研究 总被引:2,自引:2,他引:0
兰坪盆地西缘发育一条重要的脉状Cu矿带,矿床的成矿流体来源一直存在较大的争议。本次研究对该矿带南段新发现的茅草坪矿床进行流体包裹体和H-O-C-S同位素研究,结合前人发表的该矿带矿床的同位素数据,探讨矿床成矿流体特征和来源。茅草坪矿床早(A1脉)、晚(A2脉)两期含矿石英脉中的流体包裹体均为含CO2盐水包裹体,可细分为含石盐子晶、富液相(水溶液相)、富气相(CO2相)包裹体等不同类型。根据流体包裹体的共生特点,将其划分为3组包裹体组合:(1)第I组,出现在A1脉石英中,为富液相(I-W型)、富气相(I-C型)和含石盐子晶(I-S型)包裹体共生;(2)第Ⅱ组,同样出现在A1脉石英中,为富液相(Ⅱ-W型)和富气相(Ⅱ-C型)包裹体共生;(3)第Ⅲ组,出现在A2脉石英中,为富液相(Ⅲ-W型)和富气相(Ⅲ-C型)包裹体共生。测温结果显示:I-S型包裹体均一温度在293~370℃之间,流体盐度为30.06%~39.76%Na Cleqv;Ⅱ-W型包裹体均一温度在302~490℃之间,流体盐度为1.23%~18.63%Na Cleqv;Ⅲ-W型包裹体均一温度在263~400℃之间,流体盐度为1.20%~11.34%Na Cleqv。同一组内,包裹体气/液相比高度变化,表明包裹体捕获时的流体呈不均一态,此时包裹体均一温度中低值部分近似代表该组包裹体真实的捕获温度。因此,从I组到Ⅲ组,包裹体分别捕获于280~320℃(I组、Ⅱ组)和260~280℃(Ⅲ组),结合盐度数据,反应初始成矿流体发生沸腾作用,伴随石盐子晶析出,流体盐度下降,随后温度降低。茅草坪矿床成矿流体富CO2的特点与区域内其他脉状Cu矿床一致,但盐度明显偏高。矿床热液石英的δDV-SMOW值变化在-94.6‰~-56.2‰之间,计算的流体的δ18OV-SMOW值集中在+8.1‰~+9.6‰之间,与区域其他脉状Cu矿床相似,数据主要落在原生岩浆水区域的下方,表明流体来源于岩浆水,但经历了开放系统下的脱气作用,没有盆地流体或大气降水的贡献;热液碳酸盐方解石的δ13CV-PDF值为-8.3‰~-2.4‰,δ18OV-SMOW值为14.46‰~16.63‰,与区域其他脉状Cu矿床的C-O同位素组成相似,但C同位素组成明显低于区域脉状Pb-Zn矿床(碳主要来自盆地流体溶解的碳酸盐岩);黄铜矿的δ34SV-CDT值变化于-6.4‰~-3.9‰之间,处于区域其他脉状Cu矿床的S同位素组成范围内,但区别于区域砂岩型Cu矿床(硫来自硫酸盐的细菌还原作用)。因此,推测矿床的CO2和硫可能也来自脱气的岩浆。茅草坪脉状Cu矿床成矿流体的研究表明:兰坪盆地西缘脉状Cu矿床成矿流体可能来自富CO2、经历脱气的岩浆水,没有大气降水和盆地卤水的参与。 相似文献
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兰坪盆地西缘广泛发育大量沉积岩容矿脉状铜矿床,这些脉状铜矿床的成矿流体以普遍存在大量富CO2流体包裹体为特征,这在整个兰坪盆地是十分罕见的,显著区别于盆地流体成矿系统主导成矿的Pb-Zn矿床。为探明这种富CO2流体的来源,本文首次报道了盆地西缘2个代表性脉状铜矿床(连城、金满)主成矿阶段形成的黄铜矿、黄铁矿的He和Ar同位素组成的研究结果。结果表明,2个矿床不同样品流体包裹体中3He/4He比值变化较小,介于0.01~0.07 Ra之间,明显区别于幔源氦的3He/4He特征值(6~9 Ra),而与壳源氦的3He/4He特征值(0.01~0.05 Ra)极其一致;40Ar/36Ar比值变化较大,介于305~1142之间,明显高于大气中的40Ar/36Ar比值(295.5)。结合矿床地质、流体包裹体及H、O同位素地球化学特征,认为兰坪盆地西缘脉状铜矿床中富CO2的成矿流体以混有少量饱和大气水的地壳流体为主,没有明显的幔源流体参与。 相似文献
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滇西兰坪盆地西缘铜矿床矿物流体包裹体研究 总被引:5,自引:0,他引:5
滇西兰坪中新生代盆地西缘发育众多的铜多金属矿床,主要以脉状或透镜状赋存于由砂岩、粉砂岩和页岩组成的含盐红色碎屑岩建造中,或产于火山岩中。本文在前人工作基础上,对区域3个代表性矿床进行了系统的矿物流体包裹体地球化学研究,结果表明:区域铜矿床矿物流体包裹体类型简单,以气液两相包裹体和液相包裹体为主;均一温度不高,显示成矿为中低温度;流体包裹体成分显示为a^+(K^+)+Ca^2+Cl^-+SO^2-4型,表明成矿流体主要是以大气降水补给的热卤水;成矿流体气相组成主要为H2O和CO2,还原性烃类气体的存在并与氧化性气体的反相关关系显示其与盆地有机质的密切关系及在成矿过程中的重要性。结合成矿地质背景及矿物氢氧同位素的分析,认为该带中的矿床地幔物质参与成矿是次要的,成因上应为受深断裂控制的、大气降水补给的热卤水型矿床。 相似文献
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在流体包裹体显微冷热台系统观测基础上,通过显微激光拉曼探针揭示出兰坪中—新生代盆地内金顶及外围矿床成矿主阶段原生流体包裹体含烃富CO_2,成分变化大。流体成分的耦合关系研究,并配合O、C同位素分析认为成矿流体中部分CO_2来自地幔,部分是沉积地层中碳酸盐岩和有机质分解成因,H_2O和烃主要起源于大气成因盆地卤水和地层有机质。地幔源CO_2对贱金属元素的搬运可能贡献突出,而烃类对金属元素的沉淀意义重大。成矿流体成分具有幔源(富CO_2和金属元素)和壳源(盆地流体富烃类和H_2O)两种流体混合的特征,暗示不同性质流体的混合可能是成矿作用基本方式。 相似文献
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六苴铜矿床是中国南方中、新生代红层盆地中典型的陆相砂岩型铜矿床,具有明显的"金属矿物分带"及"浅色和紫色砂岩过渡带控矿"两大特征。为探讨该矿床流体演化及成矿机制,本文以矿化类型及成矿期次划分为基础,进行了详细的流体包裹体特征、显微测温及成分分析研究。研究结果表明,六苴铜矿床成矿作用主要经历成岩期和改造期两个时期,改造期分早、晚两阶段。两期次的流体包裹体均以纯液相型和富液型盐水包裹体为主,流体均一温度具有先升高后降低的演化趋势,温度范围分别为:96~164℃、108~227℃、94~159℃;而盐度(w(NaCl))差别不大,改造期比成岩期略低,范围分别为2.7%~16.7%、2.1%~13.8%、1.2%~13.5%,总体属中低温-中低盐度盆地卤水。包裹体岩相学观察与激光拉曼气相成分测试表明,成岩期含少量烃类包裹体,而改造期含少量CO2包裹体。两期包裹体群体成分也有一定差异:挥发分具有从还原性富有机质的CH4端元向相对氧化的CO2端元演化的特点;离子成分由富SO42-(-Cl-)-Ca2+-K+型向富Cl--Na+型转变。成岩期流体演化形成了砂岩铜矿层状产出的浸染状或纹层状矿(化)体,改造期的构造流体在层状矿(化)体基础上进一步演化形成受构造控制的条带状、脉状富矿体(脉)。 相似文献
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滇西北兰坪盆地白秧坪多金属矿床流体包裹体研究 总被引:8,自引:4,他引:4
白秧坪多金属矿床位于滇西兰坪中-新生代沉积盆地中北部,是著名三江成矿带内新近发现的重要矿床之一。碳酸盐矿物染色法岩相学和矿相学研究表明白秧坪多金属矿床成矿期早阶段共生组合矿物为闪锌矿+方铅矿+白云石+石英±含Ag矿物±含Cu矿物,方解石主要为成矿期晚阶段产物。闪锌矿及与其共生脉石矿物(白云石、石英)中流体包裹体多呈米粒状、椭圆状、负晶形以及不规则状,以孤立产出的原生包裹体为主。流体包裹体显微测温以及激光拉曼探针分析表明,成矿流体为H2O-NaCl-CaCl2流体体系,盐度峰值范围为22.00%~25.00%NaCleqv,成矿温度多数集中在110.0~180.0℃之间,密度大于1.00g.cm-3。该矿床属于低温、高盐度、中等密度热液铅锌多金属矿床。矿床成矿压力介于28.02~70.64MPa之间,成矿深度范围在1.04~2.62km,形成深度较浅。成矿流体始终处于相对还原环境,金属离子和还原硫可能共存于同一流体系统,由于物理化学条件的改变发生沉淀而形成矿床。结合矿床产出背景、矿质来源、控矿构造等因素,白秧坪多金属矿床具有密西西比河谷型(MVT)成矿流体特点。 相似文献
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滇西北兰坪盆地西缘发育大量沉积岩容矿脉状铜多金属矿床,矿体的分布受逆冲推覆系统控制,金满是其中储量最大、品位最高的铜矿床。成矿过程可分为3个阶段:成矿前(不含矿化石英-铁白云石脉)、主成矿阶段(含铜硫化物石英脉)、晚成矿阶段(少硫化物方解石+石英脉)。流体包裹体岩相学和显微测温结果表明:成矿前和主成矿期石英中流体包裹体特征变化不大,成矿前和主成矿期石英中均存在3种类型的包裹体,以水溶液包裹体为主,含CO_2水溶液包裹体次之,富CO_2包裹体较少出现。含CO_2水溶液包裹体测温结果也差别不大,均一温度都集中在240320℃,盐度(w(NaCl))集中在1%4%。水溶液包裹体均一温度变化也不大,集中在160 230℃,明显低于含CO_2水溶液包裹体;盐度却存在较大的变化,主成矿期盐度变化范围明显较大,且峰值高于成矿前。晚成矿阶段则仅出现水溶液包裹体,均一温度和盐度都明显降低,均一温度集中在120185℃,盐度集中在1.4%9.3%。结合其他证据,笔者认为金满铜矿床包含两种不同性质的流体:深源流体,以中高温、中低盐度、富含CO_2为特征;盆地卤水,以中低温、中高盐度、贫CO_2为特征。成矿过程中未发生明显的沸腾和相分离作用,深源流体和盆地卤水的混合可能是导致Cu等成矿元素沉淀的重要机制。 相似文献
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金顶铅锌矿床流体包裹体地球化学特征 总被引:28,自引:1,他引:28
金顶超大型铅锌矿床主要工业矿体形成于热卤水成矿期。本文通过对流体包裹体的温度、压力、盐度、密度、成分、氢氧同位素及流体性质等地球化学研究表明,金顶矿床具有浅成中-低温、中-低盐度矿化的特点,成矿流体源于沉积盆地热卤水和古大气降水的混合,部分源于深部,从热卤水矿化的早期到晚期,随着古大气降水的加入,流体的T,p,S,δ^18O,δD,fo2,fco2,fs2均具降低趋势,而PH,Eh值略有增大。 相似文献
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The Jinding Zn–Pb deposit occurs in Cretaceous and Paleocene siliciclastic rocks (mainly sandstones) in the Meso-Cenozoic Lanping basin, western Yunnan, China. With a reserve of approximately 200 Mt of ore containing 6.1% Zn and 1.3% Pb, Jinding is the largest sandstone-hosted Zn–Pb deposit in the world. Most previous studies assumed that the mineralizing fluids were derived from within the basin (including meteoric recharge), and the fluid flow was driven by topographic relief under a hydrostatic regime. In contrast, we propose that the mineralizing system was strongly overpressured based on observations of hydraulic fractures and fluid inclusion data. Numerical modeling results indicate that the overpressures could not have been produced by normal sediment compaction. Thrust faulting and input of mantle-derived fluids are likely responsible for the building-up of the high overpressures. The special hydrodynamic regime and potential contribution of mantle-derived fluids to the mineralizing system distinguish Jinding from other known sedimentary basin-related Pb–Zn deposits. 相似文献
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维拉斯托铅锌矿床发育在大兴安岭南段西坡成矿带内。矿区出露的岩浆岩主要为石英闪长岩、花岗闪长岩以及碱性花岗岩等;矿体严格受断裂构造控制,属典型的热液脉型矿床。矿床的热液期可划分为3个阶段:Ⅰ石英-毒砂-黄铁矿阶段、Ⅱ多金属硫化物-石英阶段和Ⅲ石英-碳酸盐阶段。流体包裹体研究表明,维拉斯托矿床矿石主要发育气液两相、富CH_4以及含CH_4-CO_2的包裹体。Ⅰ阶段3种类型包裹体均发育,Ⅱ阶段以气液两相和含CH_4-CO_2的包裹体为主,Ⅲ阶段仅发育气液两相包裹体。Ⅰ阶段包裹体均一温度范围为243.1℃~398.5℃,盐度为4.8%~12%NaCleqv;Ⅱ阶段均一温度为190.0℃~331.1℃,盐度为3.5%~9.1%NaCleqv;Ⅲ阶段均一温度范围为180.0℃~240.0℃,盐度范围为3.7%~6.7%NaCleqv,显示成矿流体具有中温、低盐度和低密度的特点;激光拉曼光谱分析包裹体气相成分主要为CO_2、CH_4和H_2O。氢、氧同位素分析结果表明成矿流体具有岩浆水和大气降水的混合特征;硫同位素结果显示成矿物质具有深源的特点。综合分析认为,矿床的形成与燕山期中酸性岩浆活动密切相关,深部岩浆在上升过程中与下渗的大气降水发生混合,导致矿物质在近东西向的"S"型压扭性断裂中沉淀并富集成矿。 相似文献
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根据山后金矿床的矿物组合和矿物生成顺序,将成矿阶段划分为4个阶段:黄铁矿-石英(钾化)阶段、石英—黄铁矿(绢英岩化)阶段、金-石英-多金属硫化物阶段和石英-碳酸盐阶段。对区内主成矿阶段的石英中流体包裹体进行岩相学、显微测温及氢氧同位素进行分析。结果表明:矿石中的包裹体主要有含CO2三相包裹体、气液两相包裹体和CO2包裹体三种类型,矿石中的包裹体普遍富含CO2。成矿过程中,流体经历了CO2-H2O—Na Cl体系的不混溶作用。成矿流体具有低盐度(4.0~9.0 wt%Na Cl.eqv)和低密度(0.70~0.89 g/cm3)的特点。主成矿温度为260℃~300℃,成矿压力为83~100 MPa,对应成矿深度为7.45~8.25 km。流体包裹体氢氧同位素分析结果介于地幔初生水和岩浆水之间,部分向大气降水线方向漂移,表明山后金矿成矿流体以幔源流体为主,并有大气降水和其他流体的加入,初步确定山后金矿床是受断裂构造控制的中温热液脉型金矿床。 相似文献
14.
云南金顶超大型铅锌矿床沥青Re-Os法测年及地质意义 总被引:6,自引:3,他引:3
油气藏与金属矿床在世界许多沉积盆地内共存,油气成藏与金属成矿的动力学关系备受关注。云南兰坪金顶产有中国目前最大铅锌矿床,也是世界上唯一陆相沉积岩容矿、且形成于新生代的超大型铅锌矿床。矿床中常见沥青、重油等有机质,它们的形成早于或晚于铅锌硫化物成矿存在明显分歧,限制了对油气成藏与铅锌成矿关系的认识。本文针对金顶超大型矿区以古新统云龙组含砾砂岩和砂砾岩为主岩铅锌矿石中沥青,开展了Re-Os法同位素测年,获得68±5Ma的等时线年龄(MSWD=9.2,n=6),指示金顶古油气成藏形成于古新世,先于铅锌硫化物大规模成矿;烃类物质具有通过热化学还原硫酸盐提供铅锌成矿所需硫化氢的客观条件;油气成藏与铅锌成矿在云南金顶矿区很可能是一个先后发生的连续地质过程,成藏为成矿奠基,成矿伴随着油气藏的破坏。 相似文献
15.
山西中条山铜矿峪铜矿流体演化特征 总被引:1,自引:0,他引:1
铜矿峪铜矿大地构造位置位于华北克拉通中部造山带南部,主容矿围岩为花岗闪长斑岩、二长花岗岩及变质基性火山岩。对不同阶段石英流体包裹体进行了包裹体岩相学、显微测温学和激光拉曼显微探针研究。结果表明,成矿流体包裹体可分为气液两相包裹体、含多子晶包裹体、含石盐子晶包裹体、含CO2 包裹体及纯CO2 包裹体。其中早阶段以富含多子晶包裹体( 均一温度为436. 2 ℃ ~ > 550 ℃,盐度( w ( NaCl) ) 为49. 34% ~ > 62%) 和含石盐子晶包裹体( 均一温度为345. 6 ℃ ~ > 550 ℃,盐度( w ( NaCl) ) 为29. 72% ~ > 62%) 为主。主成矿阶段主要由含石盐子晶包裹体( 均一温度为169. 1 ℃ ~ 324. 9 ℃,盐度( w ( NaCl) ) 为30. 47% ~ 39. 75%) 、气液两相包裹体( 均一温度介于159. 9 ℃ ~ 242. 9 ℃,盐度( w ( NaCl) ) 为1. 56% ~ 22. 31%) 组成并发现少量含CO2 包裹体 ( 均一温度为259. 7 ℃ ~ 320. 5 ℃,盐度( w ( NaCl) ) 为8. 93% ~ 13. 16%) 和纯CO2 包裹体( CO2 均一温度为24. 3 ℃ ~ 27. 22 ℃) 。晚成矿阶段仅发育气液两相包裹体( 均一温度为126. 9 ℃ ~ 212. 3 ℃,盐度( w ( NaCl) ) 为1. 56% ~ 7. 44 %) 。激光拉曼光谱分析包裹体气相成分主要为H2O、CO2、 HF 组成,晚期为CO2、N2。包裹体中普遍存在CO2。早阶段流体应为高温高盐高氧逸度NaCl - H2O - CO2 体系。主成矿阶段含气液两相包裹体与富CO2 相包裹体共存,表明流体发生了不混溶或沸腾现象。成矿晚阶段低温低盐度气液两相包裹体可能来源于大气降水。分析认为,铜矿峪铜矿成因类型属斑岩型。 相似文献
16.
《Resource Geology》2018,68(3):258-274
The Dabaoshan deposit in Northern Guangdong Province, South China, is a Cu–Mo–W–Pb–Zn polymetallic deposit, located in the southern part of the Qin–Hang porphyry–skarn Cu–Mo ore belt. The deposit mainly comprises porphyry Mo and stratiform skarn Cu ore deposits. The genesis of the Cu ore deposit has been ascribed to a typical skarn ore deposit formed by the metasomatism of Devonian carbonate rock layers or to a volcanic rock‐hosted massive sulfide deposit formed by marine exhalation. In this paper, we report on the homogenization temperatures and salinities of fluid inclusions and C, H, O, S, and Pb isotopic compositions of fluids and minerals in this deposit. Homogenization temperatures and salinities of fluid inclusions in garnet, diopside, quartz, and calcite provide information on the skarnification, mineralization, and postmineralization stages. The data show that ore‐forming fluids experienced a continuous transition from high temperatures and salinities to low temperatures and salinities over the entire period of mineralization. C, H, and O isotopic compositions indicate that ore‐forming fluids were derived mainly from magmatic water. O isotopic compositions indicate that ore‐forming fluids mingled with atmospheric water during the last stage of mineralization. Sulfur in the ore came mainly from deep magmatic sources. Pb isotopic compositions in the orebody show that almost all the lead in the ore was derived from magma with a crustal source. Combined geological, geophysical, and geochemical data were achieved before we proposed that the Dabaoshan porphyry–skarn Cu–Mo–W–Pb–Zn deposit, as one member of the Qin–Hang porphyry–skarn Cu–Mo ore belt, formed during the Jurassic subduction of the paleo‐Pacific plate beneath the Eurasian continent at quite low angle. NE‐ and EW‐trending structures controlled the emplacement of magmatic rocks in the South China region. In the mining area, the Xiangguanping Fault and its branches were the main conduits for magmatic crystallization and mineralization. The many subfaults, folds, and interlayer fracture zones on both sides of the main fault provided the requisite space for the ore and, together, were the controlling structures of the orebody. 相似文献
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18.
Geologic, fluid inclusion and isotopic characteristics of the Jinding Zn–Pb deposit, western Yunnan, South China: A review 总被引:1,自引:1,他引:0
Chunji Xue Rong Zeng Shuwen Liu Guoxiang Chi Hairuo Qing Yuchuan Chen Jianmin Yang Denghong Wang 《Ore Geology Reviews》2007,31(1-4):337-359
With a reserve of 200 Mt ore grading 6.08% Zn and 1.29% Pb (i.e., a metal reserve of 15 Mt) hosted in Cretaceous and Tertiary terrestrial rocks, the Jinding deposit is the largest Zn–Pb deposit in China, and also the youngest sediment-hosted super giant Zn–Pb deposit in the world. The deposit mainly occurs in the Jinding dome structure as tabular orebodies within breccia-bearing sandstones of the Palaeocene Yunlong Formation (autochthonous) and in the overlying sandstones of the Early Cretaceous Jingxing Formation (allochthonous). The deposit is not stratiform and no exhalative sedimentary rocks have been observed. The occurrence of the orebodies, presence of hangingwall alteration, and replacement and open-space filling textures all indicate an epigenetic origin. Formation of the Jinding Zn–Pb deposit is related to a period of major continental crust movement during the collision of the Indian and Eurasian Plates. The westward thrusts and dome structure were successively developed in the Palaeocene sedimentary rocks in the ore district, and Zn–Pb mineralisation appears to have taken place in the early stage of the doming processes.The study of fluid inclusions in sphalerite and associated gangue minerals (quartz, celestine, calcite and gypsum) shows that homogenisation temperatures ranged from 54 to 309 °C and cluster around 110 to 150 °C, with salinities of 1.6 to 18.0 wt.% NaCl equiv. Inert gas isotope studies from inclusions in ore- and gangue-minerals reveal 2.0 to 15.6% mantle He, 53% mantle Ne and a considerable amount of mantle Xe in the ore-forming fluids. The Pb-isotope composition of ores shows that the metal is mainly of mantle origin, mixed with a lesser amount of crustal lead. The widely variable and negative δ34S values of Jinding sulphides suggest that thermo-chemical or bacterial sulphate reduction produced reduced sulphur for deposition of the Zn–Pb sulphides. The mixing of a mantle-sourced fluid enriched in metals and CO2 with reduced sulphide-bearing saline formation water in a structural–lithologic trap may have been the key mechanism for the formation of the Jinding deposit.The Jinding deposit differs from known major types of sediment-hosted Zn–Pb deposits in the world, including sandstone-type (SST), Mississippi Valley type (MVT) and sedimentary-exhalative (SEDEX). Although the fine-grained ore texture and high Zn/Pb ratios are similar to those in SEDEX deposits, the Jinding deposit lacks any exhalative sedimentary rocks. Like MVT deposits, Jinding is characterised by simple mineralogy, epigenetic features and involvement of basinal brines in mineralisation, but its host rocks are mainly sandstones and breccia-bearing sandstones. The Jinding deposit is also different from SST deposits with its high Zn/Pb ratios, among other characteristics. Most importantly, the Jinding deposit was formed in an intracontinental terrestrial basin with an active tectonic history in relation to plate collision, and mantle-sourced fluids and metals played a major role in ore formation, which is not the case for SEDEX, MVT, and SST. We propose that Jinding represents a new type of sediment-hosted Zn–Pb deposit, named the ‘Jinding type’. 相似文献