青海东昆仑阿斯哈金矿床含金黄铁矿微量元素地球化学特征及其地质意义  被引量：5

作　　者：岳维好 周家喜 YUE WeiHao;ZHOU JiaXi(College of Information Engineering,Kunming University,Kunming 650214,Yunnan,China;Key Laboratory of Data Governance and Intelligent Decision in Universities of Yunnan Province,Kunming 650214,Yunnan,China;School of Earth Sciences,Yunnan University,Kunming 650500,Yunnan,China;Key Laboratory of Critical Minerals Metallogeny in Universities of Yunnan Province,Kunming 650500,Yunnan,China)

机构地区：[1]昆明学院信息工程学院,云南昆明650214 [2]云南省高校数据治理与智能决策重点实验室,云南昆明650214 [3]云南大学地球科学学院,云南昆明650500 [4]云南省高校关键矿产成矿学重点实验室,云南昆明650500

出　　处：《矿床地质》2022年第1期106-120,共15页Mineral Deposits

基　　金：云南省地方本科高校基础研究联合专项资金项目(编号:202101BA070001-077);云南省教育厅科学研究基金项目(编号:2021J0706);昆明学院引进人才科研启动项目(编号:YJL2003)联合资助。

摘　　要：阿斯哈金矿床是青海东昆仑造山带东段金矿床的典型代表。金矿体主要赋存于闪长岩和花岗闪长岩体的构造破碎带内,受NNE向和NNW向-NW向断裂构造控制。与金矿化密切相关的蚀变类型为黄铁矿化、硅化、绢云母化和黄铜矿化。矿石矿物主要为黄铁矿,其次是黄铜矿、方铅矿、毒砂、自然金和银金矿。据矿脉穿插关系、矿石矿物共生组合和结构构造特征,将成矿期划分为3个阶段:石英-黄铁矿-毒砂阶段(Ⅰ)、石英-多金属硫化物阶段(Ⅱ)、和石英-碳酸盐阶段(Ⅲ),其中Ⅱ阶段为主成矿阶段。前人研究表明黄铁矿的微量(含稀土)元素含量可以反映成矿流体与成矿物质来源的特征,本次采用电感耦合等离子质谱仪(ICP-MS)技术对阿斯哈金矿主成矿期的主要载金矿物黄铁矿进行研究。ICP-MS测试结果显示:黄铁矿相对富集少量高场强元素(如Y、U、Zr、Hf)外,其他元素均有不同程度的亏损,其Hf/Sm、Th/La和Nb/La比值(除个别样品外)普遍<1,表明矿床成矿流体可能是以富Cl的成矿热液为主。黄铁矿Co/Ni比值(1.39~6.61,平均为2.57)显示矿床为热液成因。黄铁矿Y/Ho比值(26.10~35.76,平均为30.57)与现代海水及海底热液明显不同,略较赋矿围岩闪长岩和花岗斑岩的Y/Ho比值(26.97~29.25,平均为28.12)范围宽,暗示除赋矿围岩外,可能还有其它源区。阿斯哈金矿床含金黄铁矿稀土元素总量较低(ΣREE=4.83×10^(-6)~64.30×10^(-6),平均为19.60×10^(-6)),LREE/HREE比值平均为6.62,(La/Yb)_(N)值平均为8.11,为轻稀土元素富集型,其配分与赋矿围岩闪长岩和花岗斑岩相似,而与矿区地层金水口群变质岩不同,暗示该矿床成矿物质来自赋矿围岩。Eu负异常明显(δEu=0.49~0.92,平均为0.68),Ce异常不显著(δCe=0.73~1.00,平均为1.02),与赋矿围岩相似,进一步表明该矿床与中酸性围岩的内在成因关系。综合研究认为,阿斯哈金矿床属于与中酸性岩浆作�The Asiha gold deposit is a typical representative of the gold deposit in the eastern section of the East Kunlun orogenic belt from Qinghai Province. The orebodies mainly occur in the structural fracture zone of diorite and granodiorite, and are controlled by NNE-trending and NNW-NW-trending fault structures. Alteration types closely related to gold mineralization includes pyritization, silicification, sericitization and chalcopyrite. The ore minerals are mainly pyrite, followed by chalcopyrite, galena, arsenopyrite, native gold and electrum. According to the interspersed relationship of ore veins, mineral association and structural characteristics, the mineralization stages are divided into the quartz-pyrite-arsenopyrite stage(Ⅰ), the quartz-polysulfide stage(Ⅱ) and the quartz-carbonate stage(Ⅲ). The stage Ⅱ is the main ore-forming stage. Previous studies had verified that characteristics of oreforming fluid can be reflected by trace elements(including REE) patterns contained in pyrite minerals. Trace element compositions of pyrites from the Asiha gold deposit was measured by ICP-MS in our study. ICP-MS test result shows that all elements in the pyrites have different extent depleted except the high field-strength element(HFSE) such as Y, U, Zr, Hf and its Hf/Sm, Th/La and Nb/La values of pyrite are all less than 1 except for individual samples, indicating the ore-forming fluid may be dominated by Cl-enriched. The Co/Ni ratios of pyrite(1.39~6.61, average 2.57) indicates that the deposit is hydrothermal origin. The Y/Ho ratios of pyrite(26.10~35.76, average 30.57) are significantly different from modern seawater and seafloor hydrothermal fluids. It is slightly wider than the Y/Ho ratios of host rock(26.97~29.25, average 28.12), suggesting that the ore-forming fluid might come from other source areas besides the host rocks. The total REE(ΣREE) of gold-bearing pyrite is relatively lower(ΣREE=4.83×10^(-6)~64.30×10^(-6), average 19.60×10^(-6)). The LREE/HREE ratio(6.62) and the(La/Yb)_(N) ratio(8.11)ind

关 键 词：地球化学 微量元素 稀土元素 黄铁矿 成矿物质来源 阿斯哈金矿床 青海东昆仑 

分 类 号：P618.51[天文地球—矿床学] P595[天文地球—地质学]