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新疆阿尔泰南缘泥盆纪多金属成矿带Sr-Nd-Pb同位素地球化学与构造背景探讨 总被引:17,自引:6,他引:17
新疆阿尔泰南缘晚古生代火山岩区分布着多个金属成矿带,其中以阿舍勒成矿带和可可塔勒成矿带最为著名,矿床地质研究表明,产于早-中泥盆统的多金属硫化物矿床大多具有VMS型矿床的特征。通过测定部分典型矿床的Sr-Nd-Pb同位素组成,发现从乔夏哈拉至可可塔勒矿区初始锶逐渐升高,由0.704407到0.714485;而εNd(t)由正值变为负值。反映成矿物质来源以幔源为主,过渡到壳源物质的混入逐渐增加。从Pb同位素特征来看,成矿带内的大多数矿床具有火山岛弧区成矿的特征,矿石铅同位素组成显示正常铅,但可可塔勒铅锌矿床矿石铅具有放射性成因铅的加入。结合成矿带内各主要块状硫化物矿床的地质和地球化学特征,本文认为阿舍勒铜锌矿可能产于与俯冲有关的弧内(弧间)盆地环境,可可塔勒铅锌矿、蒙库铁(铜)矿和铁木尔特铜铅锌矿产于弧后盆地环境。而乔夏哈拉铜铁矿Sr—Nd—Pb同位素组成显示其具有MORB特征,这与其“塞浦路斯型”块状硫化物矿床的特征相吻合。 相似文献
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新疆可可塔勒铅锌矿床同位素地球化学研究 总被引:5,自引:0,他引:5
同位素资料表明,可可塔勒铅锌矿床成矿时代为早泥盆世,与下泥盆统海相火山岩系年代一致;矿石铅主要来自于活动造山带,与弧盆系火山岩有关,属幔壳混合铅;矿石的硫源与赋矿围岩或后期脉状矿石的硫源存在明显的差异,前者属细菌成因硫和海水硫酸盐还原硫的混合,后者属深部火山硫或岩浆硫;主成矿期的成矿介质水主要是海水,可能有少量大气降水加入,后期矿化则以混合岩浆水为主。矿床形成属海底火山喷气-沉积迭加改造型矿床。 相似文献
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新疆阿尔泰山南缘产于泥盆纪火山-沉积盆地铅锌矿床地质特征--以可可塔勒铅锌矿为例 总被引:9,自引:1,他引:8
可可塔勒矿床位于新疆阿尔泰造山带南缘,产于泥盆纪火山-沉积盆地内铅锌矿(可可塔勒)体呈似层状、透镜状,矿石构造以条纹条带状、块状、斑杂状为主,矿物成分相对简单,矿体直接容矿围岩为火山-沉积岩.矿床属火山-沉积岩容矿的块状硫化物矿床.为介于典型的火山岩容矿的块状硫化物型矿床(VHMS)和典型沉积岩容矿的硫化物矿床(SEDEX型)之间的过渡类型(一种新类型块状硫化物矿床),其矿化特征与伊比利亚型矿床相类似. 相似文献
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新疆阿尔泰成矿带花岗岩发育,其中很多花岗岩与成矿作用有着密切的联系,特别是400Ma左右的岩浆活动是阿尔泰地区一次重要的岩浆成矿活动,阿尔泰许多金属矿床与这一时期的岩浆构造作用有关。本次研究的出露于可可塔勒铅锌矿区的黑云母花岗岩体,其锆石LA-ICPMSU-Pb年龄为(401.8士1.5)Ma,表明可可塔勒花岗岩是阿尔泰成矿带400Ma左右发生的一次重要岩浆构造作用的产物,该黑云母花岗岩体侵入于矿区下泥盆统康布铁堡组火山岩地层中,岩体与围岩接触带附近的围岩蚀变明显,该黑云母花岗岩的侵入以及其后期的岩浆热液活动可能对区内成矿物质的活化、迁移、富集、成矿具有一定的贡献。 相似文献
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新疆可可塔勒金与多金属矿带成矿演化 总被引:1,自引:0,他引:1
海西早期,西伯利亚板块南缘拉张沉降带NW向断裂控制着 麦兹、克朗火山沉积盆地及可可塔勒矿带海相火山喷流沉积型铁铅锌铜矿床。矿床形成顺序为蒙库铁矿、可可塔勒铅锌矿、铁木尔特铅锌矿和后期断裂作用形成的萨热阔布金矿。与铁矿床有关的黄铁矿硫同位素组成显示硫和矿质来自深部岩浆源,铅锌铜矿硫同位素分为两组,一组富轻硫,δ34S最低为-27.96‰(范围-27.961‰~-5.400‰),另一组δ34S均值接近于0‰(范围-3.360‰~+5.100‰),硫同位素及流体包裹体资料表明有两种成矿流体,一种为海水深循环热液;另一种为火山岩浆热液。断裂构造、盆地、火山活动和流体演化决定了矿带成矿系列演化。 相似文献
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可可塔勒铅锌矿床地质特征及其成因初探 总被引:3,自引:2,他引:3
通过可可塔勒铅锌矿床地质特征及地球化学特征的研究,探讨可可塔勒铅锌矿床的成因,为寻找矿化物型铅锌矿提供了依据。 相似文献
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阿尔泰山南缘的阿舍勒铜(锌)矿、可可塔勒铅锌矿、喀拉通克铜镍矿均为大型-特大型矿床.通过典型矿床成矿特征比较,认为本区主要的铜、镍、铅锌等有色金属矿床均形成于海西期,产于西伯利亚与哈萨克斯坦-准噶尔这两大板块之接合部位的陆缘裂谷带附近,块状硫化物矿床是其最基本的成矿形式,额尔齐斯深大断裂两侧是最有利的矿化富集空间.成矿物质来源都涉及到前泥盆系的古老岩石基底或更深的上地幔原始熔浆.其成矿模式有两种基本类型,一是早-中泥盆世海底火山喷流-沉积成矿作用模式,二是海西中晚期与上地幔拉斑玄武熔浆有关的熔融洋壳岩浆熔离分异成矿作用模式. 相似文献
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《地学前缘(英文版)》2023,14(1):101481
The elemental accumulation and recycling in the metamorphosed Keketale VMS-type Pb-Zn deposit of the Altai Mountains are presented in this study. Based on detailed fieldwork and microscopic observation, the formation of the deposit involved syngenetic massive sulfide mineralization and epigenetic superimposed mineralization. Different generations of iron sulfides (i.e., pyrite and pyrrhotite) with contrasting textural, elemental, and sulfur isotopic features were generated in primary mineralization (including hydrothermal iron sulfides, colloform pyrite) and secondary modification (including annealed iron sulfides, oriented iron sulfides, and vein-pyrite). It is revealed that the spatial variation in textures and elements of hydrothermal iron sulfides depends on the inhomogeneous fluid compositions and varied environment in VMS hydrothermal system. Both leached sulfur from the footwall volcanic rocks and reduced sulfur by the TSR process are regarded as important sulfur sources. Furthermore, large sulfur isotopic fractionation and negative δ34S values were mainly caused by varied oxygen fugacity, and to a lesser extent, temperature fluctuation. The epigenetic polymetallic veins that contain sulfides and sulfosalts (e.g., jordanite-geocronite, bournonite-seligmannite, boulangerite) were considered as the products of metamorphic fluid scavenged the metal-rich strata. All things considered, it is indicated that two episodes of fluid with distinct origins were essential for the formation of the deposit. The predominant evolved seawater along with subordinate magmatic fluid mobilized metals from volcanic rocks and precipitated massive sulfides near the seafloor are vital for primary mineralization. The metamorphic fluid remobilized metals (i.e., FMEs: fluid mobile elements, e.g., Pb, As, Sb) from neighboring volcanic and pyroclastic rocks and destabilized them within the fractured zone are responsible for secondary mineralization, which enhances the economic value of the deposit. Accordingly, metal-rich Devonian strata had been successively swept by different origins of fluid, leading to progressively elemental enrichment and the formation of a large deposit. Furthermore, the current study enlightens that FME-bearing veins with economic benefits can be discovered near the metamorphosed VMS deposits. 相似文献
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