藏南喜马拉雅造山带造山型马扎拉Au-Sb矿床和沙拉岗Sb矿床流体包裹体He-Ar同位素组成:对成矿流体来源的制约   总被引：2，自引：1，他引：1  

翟伟  郑思琦  孙晓明  韦慧晓  莫儒伟  张凌宇  周峰  易建洲 《岩石学报》2018,34(12):3525-3538

马扎拉Au-Sb矿床和沙拉岗Sb矿床是藏南金锑成矿带中典型的造山型矿床。马扎拉Au-Sb矿床中矿体以含金辉锑矿石英脉的形式产于下中侏罗统陆热组地层中,主要组成矿物有自然金、辉锑矿、石英和碳酸盐矿物;沙拉岗Sb矿床中矿体主要以辉锑矿石英脉的形式产于下白垩统多久组地层和辉长岩体中,主要组成矿物为辉锑矿、辰砂、锑华、石英和少量碳酸盐矿物。在两个矿床的矿脉石英和辉锑矿中均发现有三类原生和假次生包裹体:水溶液包裹体、CO2-水溶液包裹体和有机包裹体。流体包裹体显微测温结果显示:马扎拉Au-Sb矿床的成矿温度为160～280℃,沙拉岗Sb矿床的成矿温度为140～240℃。He-Ar同位素分析显示马扎拉Au-Sb矿辉锑矿石英脉矿石中辉锑矿和石英以及赋矿地层中沉积层状硫化物中黄铁矿的流体包裹体均具有低的3He/4He比值,分别为0. 01382～0. 05642Ra和0. 03353～0. 08744Ra,40Ar/36Ar比值具有比较大的变化范围,分别为346. 8～4770. 1和349. 4～2689. 1;沙拉岗Sb矿床中辉锑矿样品的3He/4He比值为0. 02385～0. 11488Ra,40Ar/36Ar比值变化小,为300. 6～537. 5。与藏南Au-Sb成矿带中造山型Au矿床成矿流体中含一定量的幔源挥发份相对比,马扎拉AuSb矿床和沙拉岗Sb矿床成矿流体中均无幔源流体的参与,马扎拉Au-Sb矿床成矿流体为壳源变质流体与改造型饱和大气水形成的混合流体;沙拉岗Sb矿床成矿流体以改造型饱和大气水为主,并有壳源变质流体的加入。  相似文献   

四川平武银厂金矿勘探复杂地层钻进技术          下载免费PDF全文

杨福全  龙海涛 《探矿工程》2018,45(6):36-39

四川平武银厂金矿区钻探施工中遇到漏失、缩径、岩心破碎、易孔斜和钻孔事故频发等施工难题,施工难度极大。本文结合地层特点,通过采用绳索取心液动锤、高密度低失水泥浆体系、跟管钻进等工艺技术措施,提高了钻进效率和施工质量,大幅度减少了孔内事故的发生,为顺利完成钻孔施工任务奠定了坚实的基础。  相似文献   

几内亚福雷卡里亚YML铁矿区的富铁矿床地质特征及找矿前景探讨          下载免费PDF全文

江胜国  李宏臣  付方建  王志刚  曹健 《地质找矿论丛》2018,33(1):142-148

YML铁矿区位于几内亚福雷卡里亚省,富铁矿以条带状赤铁矿和铁角砾岩矿为主。矿区内共发育7条矿体,条带状赤铁矿体6条,铁角砾岩矿体1条。条带状赤铁矿体赋存部位多为向形地段,次级紧密褶皱发育,沿走向和倾向有逐渐变薄和尖灭的趋势;铁角砾岩矿体覆盖于地表,以风化壳的形式出现。矿床类型属复合类型,即海底热液喷气沉积叠加后期构造变质型+风化淋滤型。该区具备铁矿形成和保存的地质条件,且已发现具一定储量、品位较高的条带状赤铁矿和大面积的铁角砾岩分布区,区内铁矿找矿远景较好。  相似文献   

内蒙古曹四夭钼矿区花岗斑岩地球化学特征及地质意义          下载免费PDF全文

邱慧远  崔邢涛  邱铁栋  栾文楼 《地质找矿论丛》2018,33(2):221-234

曹四夭钼矿床位于华北克拉通北缘凉城断隆东侧,其矿化与多期次侵位的花岗质杂岩体具有密切的时间和空间联系。杂岩体的岩石类型包括:少斑状花岗斑岩、多斑状花岗斑岩、中细粒花岗岩、二长花岗斑岩和正长花岗斑岩等;前人的锆石U-Pb法测年数据表明,矿区岩浆活动可以分为155 Ma、149~140 Ma、134~131 Ma三个期次。本次研究获得矿区少斑状花岗斑岩的锆石LA-ICP-MS U-Pb法测年加权平均年龄为167Ma±1.2Ma,反映矿区可能还存在较早期的岩浆活动(中-晚侏罗世),其可与155 Ma岩浆岩划分为矿区早期的岩浆活动。花岗斑岩体具有高酸度、高钾和高铝质含量特征,总体属于酸性富钾钙碱性系列;花岗斑岩体含铝指数(A/CNK)介于1.20~2.49之间,Tb、Nd、Ga和LREE(Eu除外)富集,Eu、Ti、Sr、P亏损,属于高度分异的A型花岗岩系列。曹四夭花岗斑岩体形成于中-晚侏罗世构造机制转化时期,可能与蒙古-鄂霍次克洋闭合后的后造山伸展有关,为晚侏罗世钼多金属矿化的母岩。  相似文献   

额济纳旗灰石山东北铌多金属矿床成矿规律及成因浅析          下载免费PDF全文

刘强  杨富林  袁晓鹏 《地质找矿论丛》2018,33(1):41-45

通过对灰石山东北铌多金属矿床地质特征综合分析表明,矿床的产出受地层和构造的双重制约。矿区的二叠系双堡塘组是矿源层,矿体具有明显的层位控制性;北东东向断裂构造提供了热液通道并进行了叠加改造;矿床成因类型属于沉积变质-热液叠加型。  相似文献   

四川省中厂铜矿矿床地质特征及成因讨论          下载免费PDF全文

张淑花 《地质找矿论丛》2018,33(1):46-53

四川省中厂铜矿位于扬子地台西南缘的康滇地轴中段,赋矿地层为中元古界下部的通安组,铜矿体赋存在通安组第二段和第三段中,铜矿体呈似层状,矿体围岩分别为白云石大理岩、石英变粒岩和含石英大理岩,地层中层间破碎带、滑动带和裂隙发育,并发生硅化、绢云母化、白云石化和褪色等热液蚀变,地层中碳质含量较高,矿床地质特征上判断,成矿经过沉积成岩期和构造-热液改造期,成矿物质为多期多来源,因此认为中厂铜矿床属于沉积-改造型铜矿床。  相似文献   

菲律宾迪纳加特岛30^#矿权区红土型镍矿床地质特征及成矿作用探讨          下载免费PDF全文

江胜国  王志刚  曹健 《地质找矿论丛》2018,33(2):299-305

30~#矿权区位于菲律宾迪纳加特岛北部,区内发育有红土型镍矿床。本次勘查圈定4处矿(化)体,其中以Ⅰ、Ⅱ、Ⅲ矿(化)体的矿化范围较大,厚度变化系数为45%~50%(相对稳定),经济价值较高。红土型镍矿体平面上呈地毯状展布于地表,厚度受地形控制,富镍矿体分布于矿权区东部的5、6、11、12小区;剖面上从地表向深部矿体为铁质红土层、松散红土层及高岭土化蛇纹石化橄榄岩层。30~#矿权区红土镍矿矿床的形成经历了从普通矿到富矿两个阶段,红土镍矿石属于酸性矿石。  相似文献   

湘中基底-盖层W-Au-Sb热液系统的金属分异机制综述          下载免费PDF全文

张勇  马东升  潘家永  伍洪  陈方楠 《地质找矿论丛》2018,33(3):319-334

湘中盆地锑矿床闻名于世,成矿元素在垂直空间上呈现出上锑(泥盆系)、中金锑(震旦系)、下金钨或金锑钨(板溪群),盆地中锑、边缘锑(金/钨)的成矿分布特征。通过系统的成矿地质条件、成矿元素地球化学研究,以及矿物流包裹体地球化学数据分析表明,湘中盆地及其基底的成矿元素分带是成矿流体性质和元素地球化学行为差异等因素相互耦合的结果。湘中地区基底-盖层成矿系统:构造-岩浆岩+盆地-流体作用,基底成矿元素在流体的作用下被萃取迁移到不同部位(基底→盖层不断演化);成矿元素锑的沉淀主要受流体的温度和pH值影响,金的沉淀主要受硫逸度或总硫溶度的控制,钨的沉淀主要受流体的盐度控制,且因物化条件的变化和元素地球化学行为的控制而呈现不同元素组合沉淀成矿。  相似文献   

Metallogeny of the Baiyangping Lead‐Zinc Polymetallic Ore Concentration Area,Northern Lanping Basin of Yunnan Province,China     

WANG Xiaohu  SONG Yucai  ZHANG Hongrui  LIU Yingchao  PAN Xiaofei  GUO Tao 《《地质学报》英文版》2018,92(4):1486-1507

The Lanping Basin in the Nujiang‐Lancangjiang‐Jinshajiang (the Sanjiang) area of northeastern margin of the Tibetan Plateau is an important part of eastern Tethyan metallogenic domain. This basin hosts a number of large unique sediment‐hosted Pb‐Zn polymetallic deposits or ore districts, such as the Baiyangping ore concentration area which is one of the representative ore district. The Baiyangping ore concentration area can be divided into the east and west ore belts, which were formed in a folded tectogene of the India‐Asia continental collisional setting and was controlled by a large reverse fault. Field observations reveal that the Mesozoic and Cenozoic sedimentary strata were outcropped in the mining area, and that the orebodies are obviously controlled by faults and hosted in sandstone and carbonate rocks. However, the ore‐forming elements in the east ore belt are mainly Pb‐Zn‐Sr‐Ag, while Pb‐Zn‐Ag‐Cu‐Co elements are dominant in the west ore belt. Comparative analysis of the C‐O‐Sr‐S‐Pb isotopic compositions suggest that both ore belts had a homogeneous carbon source, and the carbon in hydrothermal calcite is derived from the dissolution of carbonate rock strata; the ore‐forming fluids were originated from formation water and precipitate water, which belonged to basin brine fluid system; sulfur was from organic thermal chemical sulfate reduction and biological sulfate reduction; the metal mineralization material was from sedimentary strata and basement, but the difference of the material source of the basement and the strata and the superimposed mineralization of the west ore belt resulted in the difference of metallogenic elements between the eastern and western metallogenic belts. The Pb‐Zn mineralization age of both ore belts was contemporary and formed in the same metallogenetic event. Both thrust formed at the same time and occurred at the Early Oligocene, which is consistent with the age constrained by field geological relationship.  相似文献   

Ore-forming Fluid and Mineral Source of the Hongshi Copper Deposit in the Kalatage Area, East Tianshan, Xinjiang, NW China   总被引：1，自引：0，他引：1  

YU Mingjie  WANG Jingbin  MAO Qigui  FANG Tonghui  ZHANG Rui 《《地质学报》英文版》2018,92(5):1769-1783

The Hongshi copper deposit is located in the middle of the Kalatage ore district in the northern segment of the Dananhu-Tousuquan island-arc belt in East Tianshan, Xinjiang, NW China. This study analyses the fluid inclusions and H, O, and S stable isotopic compositions of the deposit. The fluid-inclusion data indicate that aqueous fluid inclusions were trapped in chalcopyrite-bearing quartz veins in the gangue minerals. The homogenization temperatures range from 108°C to 299°C, and the salinities range from 0.5% to 11.8%, indicating medium to low temperatures and salinities. The trapping pressures range from 34.5 MPa to 56.8 MPa. The δ18OH2O values and δD values of the fluid range from ?6.94‰ to ?5.33‰ and from ?95.31‰ to ?48.20‰, respectively. The H and O isotopic data indicate that the ore-forming fluid derived from a mix of magmatic water and meteoric water and that meteoric water played a significant role. The S isotopic composition of pyrite ranges from 1.9‰ to 5.2‰, with an average value of 3.1‰, and the S isotopic composition of chalcopyrite ranges from ?0.9‰ to 4‰, with an average value of 1.36‰, implying that the S in the ore-forming materials was derived from the mantle. The introduction of meteoric water decreased the temperature, volatile content, and pressure, resulting in immiscibility. These factors may have been the major causes of the mineralization of the Hongshi copper deposit. Based on all the geologic and fluid characteristics, we conclude that the Hongshi copper deposit is an epithermal deposit.  相似文献