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891.
澜沧老厂银多金属矿床火山岩地球化学特征及环境识别 总被引:4,自引:0,他引:4
本文通过对矿区火山岩的主元素、微量元素和稀土元素的地球化学特征分析,以及利用TiO2-K2O-P2O5、Th-Hf-Ta、Zr-Nb-Y三角图和不相容元素配分模式的环境识别图解,得出与前人不同的结论。认为澜沧老厂银多金属矿床火山岩为大陆板内碱性玄武岩系列,其产出的构造环境可能是东冈瓦纳大陆东北部边缘的碎片。 相似文献
892.
浅成热液金矿研究综述 总被引:9,自引:1,他引:9
厘定了浅成热液金矿的概念,阐述了其成矿地球动力学环境,矿床本质特征及矿床的分类,指出了浅成熟液金矿研究中存问题及今后的研究取向。 相似文献
893.
形成于古水热系统排泄区(减压区)的下庄花岗岩型铀矿床是地下热水与岩石相互作用的产物。矿物流体包裹体水文地球化学分析表明,成矿期铀成矿古热水溶液气体成分主要为CO2,水化学类型为HCO3-Ca.Na型,F-Ca型和HCO3.F-K型。地球化学模式和热力学计算证明,热水溶液中铀的存在形式为UO2(CO3)2^2-,UO2F3^-和UO2F4^2-。热水溶液深循环过程中CO2的加入可使溶液铀沉淀临界电位值(EhC,U)明显降低,从而保持水-铀比电位值(ΔEhW,U)为正值(ΔEhW,U=EhW-EhC,U)使铀在深部相对还原的条件下仍能稳定迁移。当富铀成矿热液进入减压排泄区时,由于溶液物理-化学条件的改变,发生CO2脱气作用和中和还原作用,导致ΔEhW,U小于零,使铀沉淀、富集,最终形成花岗岩型铀矿床。 相似文献
894.
块状硫化物矿石中硫化物的压溶和增生及成矿意义——以加拿大西部矿床为例 总被引:7,自引:0,他引:7
加拿大西部块状硫化物矿石普遍地发生过硫化物的压溶和增生。增生作用根据增生体的成分可以分为同质增生和异质增生,根据动力环境可以分为静态增生和动态增生。三晶嵌接结构可以是静态增生的产物。压溶和增生是块状硫化物矿床成岩和变质过程中的重要作用。脉石矿物的压溶可使原生矿石就地加富,硫化物的压溶可使成矿物质发生再活化。增生可促进矿质沉淀。富含硫化物的地层之所以能成为地球化学障而有利于后期热液叠加和层控矿床的形成,硫化物晶芽的增生是一种重要机制。 相似文献
895.
粤东嵩溪银锑矿床成矿构造及矿化富集规律浅析 总被引:2,自引:1,他引:2
论述了嵩溪银锑矿床的地质特征、矿脉形态特征及组构特征,通过分析得出矿床成矿断裂的产生有四个阶段,其中银、锑矿化主要与第二、三阶段有关。 相似文献
896.
897.
四川牦牛坪稀土矿床矿物流体包裹体研究 总被引:18,自引:0,他引:18
对矿物流体包裹体进行分析的结果表明,牦牛坪稀土矿床的矿物中存在4种类型包裹体:(1)液-所耵;(2)液-气-固相;(3)纯气相;(4)固相,矿物包裹体显微测温结果显示牦牛坪矿床成矿温度从423℃至122℃;成矿流体的盐度ω(NaCl)为11.46%-14.36%质量分数,包裹体的成分分析结果显示流体中富含CO2和其他挥发性组分,并富含大量的不同成分的矿物雏晶,根据矿床地质特征和矿物包裹体的研究结果,作者认为本矿床的成矿作用是由碳酸岩岩浆气液流体的沸腾、充填和交代过程而实现的。 相似文献
898.
Liu Hongbing Kong Xiangru Xiaobing Ma Wang Qianshen Yan Yongli Yan Yafen Yang Zhiqiang 《中国科学D辑(英文版)》2001,44(1):64-76
Chemical reactions of plagioclase, biotite and their single minerals, as well as a mineral mixture of (plagioclase+biotite+quartz),
with KCl and (KCl+KHCO3) solutions were carried out at 150–400°C and 50–80 MPa. Experiments show that alkaline fluid promotes plagioclase’s changing
into potash feldspar, while acid fluid helps plagioclase, potash feldspar and biotite alteration form chlorite and sericite.
After chemical reaction the acidity-alkalinity of solutions often changes reversely. It was observed that gold dissolved from
the tube wall and recrystallized on the surfaces of biotite and pyrite. Therefore the transportation and enrichment of gold
are related to the elementary effect of the fluid-mineral interfaces. Fe3+-Fe2+, as an oxidition-reduction agent, and volatile components Cl- and CO2 play important roles in the reaction process 相似文献
899.
The Upper Permian Sedimentary Facies and Its Role in the Dajing Cu-Sn Deposit, Linxi County, Inner Mongolia, China 总被引:3,自引:1,他引:3
Gongjiong QIN Yosuke KAWACHI Liqing ZHAO Yongzheng WANG Qiang OU 《Resource Geology》2001,51(4):293-305
Abstract: Exhaustive investigations were launched for confirming the upper Permian host rocks of the Dajing Cu-Sn Deposit, probing into the possibility that Dajing is a Sedex type deposit during cosedimentation, complementing the deficiency of previous researches and going further into substantiating the role of the upper Permian strata in the control of ore distribution. After more than two years work, we reclassified the sedimentary facies in the Dajing area and its periphery as shallow fresh water lake and delta. Indicative sedimentary structures, such as ripple marks, rain marks, and mud cracks combined with contemporary fossils, were revealed. Having measured the flow directions, performed chemical comparison, and analyzed various sediments from sourceland in the Dajing area by XRF, we consequently redivided the strata into four sedimentary members, among which P2 l1 and P2 l2 were concluded as significant ore-hosted strata. The upper Permian basin was a lateral rift basin. The water and sediments in the basin are much deeper and thicker in the north than those in the south.
The indicators of special sedimentary facies, such as gravity flow, brine pool and synchronogenic stratiform structure of the ore cannot be found in the Dajing area. There was no growth fault, assemblage of sulfide and sulfate, and no zonation as well.
On the basis of study in this area, taking into account the paleosedimentary environment as capriciously flowing shallow lake, which approximated the state of oxidation, we figured that the paleogeography made it prohibitively difficult to form stratiform sulfide deposits which are prone to form in deoxidized environment. It can be ruled out the possibility that the Dajing deposit is a syngenetic deposit during sedimentation. 相似文献
The indicators of special sedimentary facies, such as gravity flow, brine pool and synchronogenic stratiform structure of the ore cannot be found in the Dajing area. There was no growth fault, assemblage of sulfide and sulfate, and no zonation as well.
On the basis of study in this area, taking into account the paleosedimentary environment as capriciously flowing shallow lake, which approximated the state of oxidation, we figured that the paleogeography made it prohibitively difficult to form stratiform sulfide deposits which are prone to form in deoxidized environment. It can be ruled out the possibility that the Dajing deposit is a syngenetic deposit during sedimentation. 相似文献
900.
Abstract: The skarns and genesis were studied of the Huanggang Fe‐Sn deposit and the nearby Sumugou Zn‐Pb deposit in Inner Mongolia, China. In the Huanggang mine, Nos. 1 to 4 Fe ore bodies are arranged along a calcareous horizon from proximal to distal in this order to a granite intrusion named Luotuochangliang, while Sn ore body is situated near another granite intrusion named 204. According to the distance from the granitic intrusions, mineral assemblages in skarns are systematically changed. Garnet is the most predominant skarn mineral throughout the deposit. Hastingsitic amphiboles, however, predominate in the proximal skarns. Fluorite is common in the proximal skarns, while instead calcite is common in the distal skarns. Chlorite is characteristically present only in No. 3 ore body, and chlorite geothermometry gives near 300C for the mineralization of later stage. When garnet crystal shows zonal structure, isotropic andraditic garnet occupies the core, and is surrounded with anisotropic less‐andraditic garnet. The presence of white skarn along the boundary between main skarns and host sedimentary rocks confirms relatively reducing environment prevailing as a whole in the studied area. However, the compositional relation between coexisting garnet and clinopyroxene demonstrates that relatively oxidizing condition was achieved for garnet skarn and magnetite ore in the distal, Nos. 2 to 4 Fe ore bodies and Sumugou deposit, compared to that for garnet skarn in the proximal, No. 1 and Sn ore bodies. Preliminary study on the tin content of garnets in the studied area revealed a certain degree of contribution brought from granitic intrusives since the early stage of skarn formation, irrespective of proximal or distal. Oxygen isotope study on garnet, magnetite, quartz and skarn calcite, as well as hydrogen isotope study on hastingsitic amphibole, demonstrates mainly meteoric water origin for the skarn– and ore‐forming solutions. The occurrence of Sn, W, Mo and F minerals indicates that those elements were mainly supplied to the deposit later than the formation of skarns and iron ores, overlapping to them. These constraints allow to delineate the formation model of the deposit as follows (Fig. 10): At the time of late Jurassic to early Cretaceous, felsic activity occurred in this region as a part of Yanshanian magmatism, and formed granitic intrusions as well as thick volcanic piles on the surface. The circulation of meteoric water was provoked by the heat brought by the intrusions. By this circulation, much amount of iron was extracted from andesites of the Dashizhai Formation, and precipitated as skarns and magnetite ores along calcareous horizons near the bottom of the Huanggangliang Formation. Subsequently, volatile‐rich fluids with Sn, W and Mo were expelled from the solidifying granitic magmas, and precipitated these metals in the pre‐existing skarns and ores. 相似文献