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从赋矿岩系岩石类型的多样性论羊拉铜矿的成因 总被引:17,自引:0,他引:17
通过野外调查和室内工作,将羊拉铜矿床按矿石的矿物成分和组构分出9种类型,包括矽卡岩型、大理岩型、砂板岩型、角岩型、凝灰质流纹岩型、玄武岩-辉绿岩型、花岗质碎裂岩-花岗斑岩型、安山岩型和绢英岩型。矽卡岩型矿石是构成矿体的最主要矿石类型,但在不同矿段可由碳酸盐岩(里农)和凝灰质火山岩(贝吾)两种原岩形成。矿体在赋矿岩系中有3种产出形态:顺层呈层状.似层状;沿花岗岩与沉积岩接触面呈透镜状;贯穿岩体和沉积岩呈大脉状。它们均与后期构造密切相关,矿体无确定的顶、底板岩石,围岩蚀变以矿体为中心呈环带状分布。研究表明,矿床相对赋矿岩系显示出明显的后成性,属于印支期花岗岩-花岗斑岩与古生代混杂岩通过强烈的接触交代作用形成的矽卡岩型铜矿床。 相似文献
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Cherts from the Yangla copper deposit, western Yunnan Province: geochemical characteristics and relationship with massive sulfide mineralization 总被引:4,自引:0,他引:4
Four layers of cherts were found for the first time in the Yangla copper deposit, western Yunnan Province. The cherts possessed
the following geochemical characteristics: 1 Low TiO2 and Al2O3 contents, but high ore-forming element (e.g. Cu, Au, Ag) contents; 2 low total REE contents and clear negative Eu anomalies
when normalized to chondrite similar to the REE contents and distribution patterns of associated massive sulfide ores; 3 silicon
isotopic compositions of cherts in the Yangla deposit being the same as cherts and geyserite of hot-water sedimentary origin;
4 lead and sulfur isotopic compositions of cherts in the Yangla deposit being similar to those of the massive sulfide ores
in the Yangla deposit; 5 Rb-Sr isochron age of cherts from the Yangla deposit being identical with that of host strata. Hence,
we conclude that the cherts in the Yangla deposit are of hot-water sedimentary origin, which have a close relationship with
the massive sulfide ores. The discovery of hydrothermal cherts from the Yangla copper deposit provides further evidence for
the hydrothermal exhalative origin of the massive sulfide deposits. 相似文献
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Li‐Juan Du Bo Li Zhi‐Long Huang Jun Chen Jia‐Xi Zhou Guo‐Fu Zou Zai‐Fei Yan 《Resource Geology》2020,70(1):28-49
The Yangla deposit is an intrusion‐related Cu deposit in the Jinshajiang tectonic belt (eastern Sanjiang region, SW China). Despite extensive studies that have been conducted on this deposit, the relationship between the granitic magma and Cu mineralization is still unclear, and hence, the genesis is debated. To answer this question, we conducted an integrated study of mineralogy, fluid inclusions (FIs), and hydrogen and oxygen (H‐O) isotopes. Three mineralization stages were identified based on the ore textures, alteration zonation, and crosscutting relationships: (i) pre‐ore prograde skarn (stage I), with the garnet and pyroxene dominated by andradite and diopside, respectively; (ii) syn‐ore retrograde alteration (stage II), which is subdivided into the early syn‐ore stage (stage IIa) marked by retrograde hydrated mineral assemblages and significant Fe‐Cu‐Mo‐Pb‐Zn sulfide mineralization, and the late syn‐ore stage (stage IIb) featured by quartz‐calcite veins; and (iii) late supergene mineralization (stage III), which is characterized by secondary azurite and malachite. These results of mineralogy, FIs, and H‐O isotopes indicate that: (i) Cu mineralization has a close temporal, spatial, and genetic relationship with skarn alteration; (ii) the ore fluids were magmatic dominated with late‐stage meteoric water incursion; and (iii) Type‐S (halite‐bearing) and Type‐V (vapor‐rich) FIs coexisted in garnet and clinopyroxene of stage I, indicating that fluid boiling might have occurred during this stage. From stage I to stage IIa, the FI type transformed from Type‐S + Type‐V + Type‐L (liquid‐rich) to Type‐V + Type‐L with the conduct of mineralization and was accompanied by the disappearance of Type‐S, and homogenization temperature and salinity also tended to decrease dramatically, which may be caused by the deposition of skarn minerals. At stage IIa, boiling of the ore fluids still continued due to the change from lithostatic to hydrostatic pressure, which triggered the precipitation of abundant quartz‐Cu‐Mo‐Fe sulfides. Furthermore, fluid mixing between a high‐temperature magmatic fluid and a low‐temperature meteoric water might cause a considerable drop in temperature and the deposition of Cu‐bearing quartz/calcite veins during stage IIb. Hence, we consider the Yangla deposit to be of a skarn type, genetically related to the Mesozoic magmatism in the Sanjiang region. 相似文献
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金沙江缝合带是特提斯东段重要的缝合带之一,羊拉地区的金沙江缝合带处在青藏高原东构造结东侧,是研究金沙江古洋盆的碰撞闭合过程等构造事件的重要窗口。在前人工作的基础上,通过野外系统观察取样,结合花岗岩侵入体的锆石SHRIMP U-Pb年龄测定结果,对金沙江古洋盆的碰撞闭合过程做初步研究。结果表明,从南部加仁岩体的通吉格花岗闪长岩(加仁岩体之一部分),经中部的路农—里农—江边岩体的花岗闪长岩,到北部的贝吾花岗闪长岩,岩体的侵位年龄分别为通吉格(246.1±3.5) Ma、路农花岗闪长岩(238.1±5.3) Ma、里农花岗闪长岩(239.0±5.7) Ma、江边岗闪长岩(227.9±5.1) Ma和贝吾花岗闪长岩(213.6±6.9) Ma,表明金沙江缝合带的碰撞关闭是从南向北逐渐闭合的,闭合的时限可达33 Ma,但闭合碰撞不是连续而是幕式的,碰撞闭合作用主要发生在约246 Ma、239 Ma、228 Ma、213 Ma 4个幕次。里农大沟还出现222 Ma的辉绿岩脉,与江边岩体时间上较为接近,似乎表明江边岩体侵入时期本区处于局部拉张的构造背景。 相似文献
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云南羊拉铜矿床位于金沙江构造带中部,是中-晚三叠世金沙江洋盆向西俯冲闭合碰撞造山过程中形成的一个大型铜矿床。矿体多呈层状、似层状顺层产出,但明显受层间破碎带和滑脱带控制。从流体包裹体研究入手,讨论了该矿床成矿流体的特征、演化以及流体不混溶(沸腾)作用与成矿的关系。流体包裹体研究表明,干夕卡岩阶段(Ⅰ)、湿夕卡岩磁铁矿阶段(Ⅱ)、石英硫化物阶段(Ⅲ)以及方解石硫化物阶段(Ⅳ)中发育多种类型的包裹体,主要为气液水两相包裹体和含子矿物多相包裹体,纯液相水包裹体次之,少见纯气相有机质包裹体。其中,含子矿物多相包裹体发育于Ⅰ阶段石榴石、Ⅱ阶段绿帘石,尤其是Ⅲ阶段石英中。Ⅰ、Ⅱ阶段成矿流体具有高温、高盐度特征,均一温度分别为413~593 ℃和336~498 ℃,盐度分别为19.1%~49.7% NaCleq和15.7%~53.3% NaCleq;Ⅲ阶段成矿流体均一温度为148~398 ℃,并具有低盐度(2.1%~9.6% NaCleq)与高盐度(35.5%~65.3% NaCleq)共存的特征;Ⅳ阶段成矿流体具有低温(132~179 ℃)、低盐度(3.4%~10.4% NaCleq)特征。根据流体包裹体的微观特征并结合矿区的宏观地质特征,认为流体不混溶(沸腾)是导致本矿区金属沉淀成矿的主要机制。 相似文献
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本文以云南德钦羊拉铜矿床为例, 借助Surpac矿业软件建立了矿床地质数据库, 并运用地质统计学的方法, 通过分析羊拉5号矿体铜品位分布规律, 计算出了厚度、倾向、走向3个方向的实验变异函数, 并进行了理论变异函数的曲线拟合, 确立了矿床的数学模型。在此基础上运用克立格法和距离平方反比法分别进行了储量计算, 再结合传统的块段法计算出的储量, 将三者进行对比分析, 探讨了三种方法的影响因素及其产生误差的根本原因, 最后认为运用克立格法计算储量具有先进性和使用性。文章还分析了铜矿体的品位-吨位曲线图, 为矿山合理确定经济品位和吨位提供了可靠的理论依据。 相似文献
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Xi‐An Yang Jia‐Jun Liu Da‐Peng Li De‐Gao Zhai Long‐Bo Yang Si‐Yu Han Huan Wang 《Resource Geology》2013,63(2):224-238
The Yangla copper deposit (Cu reserves: 1.2 Mt) in the Jinshajiang–Lancangjiang–Nujiang region in China is spatially associated with the Linong granitoid. Zircon U–Pb dating shows the granitoid formed at 234.1 ± 1.2 to 235.6 ± 1.2 Ma, and the KT2 ore body of the deposit yields a molybdenite Re–Os model age of 230.9 ± 3.2 Ma. The ages of mineralization and crystallization of the granitoid are identical within the measurement uncertainties, suggesting the Yangla deposit is genitically related to the Indosinian Linong granitoid. 相似文献
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