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1.
系统论述了铜厂斑岩铜矿床伴生金,银的赋存状态及分布规律,丰富了成矿理论,对矿产资源的综合利用、提高金、银回收率,以及深部资源预测,外围找矿均具很高的应用价值。 相似文献
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通过1:50万区域地球化学勘查,初步查明了新疆西昆仑叶尔羌河上游地区元素在时间和空间上的分布规律;圈出了一批地球化学异常,发现了铜、银、金、镍、铅、锌、汞、锂、钨、钼成矿带7条;对主要异常经过三级查证,新发现铜、银、金、铅、锌矿化带6条;研究表明区内蕴藏着丰富的铜、镍、金、银、钼多金属矿产资源;为西昆仑地区基础地质研究和矿产资源评价提供了丰富的地球化学资料。 相似文献
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湖南柿竹园铅锌矿床伴生金,银的赋存状态研究 总被引:1,自引:0,他引:1
该矿床的金、银主要呈独立矿物存在,主要金矿物为金银矿和含金自然银,银矿物主要有11种.根据金、银的赋存状态,对该区伴生金、银的综合利用作了初步评价. 相似文献
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本讨论了在改革开放深入发展中,冶金地质队伍跨出国门,跻身于国际市场的自然条件和社会环境,首选了东南亚(还涉及了印度、巴基斯坦、巴布亚新几内亚)国家作为研究对象。对这些国家的黑色金属和金、银、铜等矿产资源及其勘查、开发的政策环境,作了概略的介绍。 相似文献
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本文提出了自然金-银类质同象系列矿物的晶胞参数与金、银原子数百分比成二次函数关系,推导出了表示二者之间函数关系的方程式。利用该方程式,可以用金原子数百分比计算出晶胞参数,反之亦然。并且从金、银二者的电负性出发,对a值的变化作了解释。 相似文献
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巍巍小秦岭,藏金埋银地。在豫西小秦岭金矿区,驻守着这么一支队伍——他们默默无闻,甘于吃苦,乐于奉献,用忠诚捍卫着“矿产资源,国家所有”的法律尊严,用血汗维护了矿业秩序的长久稳定,被人们誉为“小秦岭矿产资源保护神”。这就是灵宝市地矿局所属的9个基层矿管所。 相似文献
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乌兹别克斯坦的矿产资源与投资前景—随中国科学家代表团访问乌兹别克斯坦考察报告之一 总被引:3,自引:0,他引:3
介绍了乌兹别克斯坦共和国的地质构造背景,已探明的和潜在的矿产资源,投资环境及可供我国利用的矿产资源。乌兹别克斯坦共和国是我国的近邻,其金,铀,钾盐,银,铜是乌兹别克斯坦的优势和矿产资源,尤其是金和铀的储量与产量在世界上占有重要的地位,应当在我国矿产资源的全球战略中占据它应有的位置。 相似文献
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《地质科技情报》2021,(1)
苏门答腊岛位于印度尼西亚西缘,是环太平洋成矿带的重要组成部分,拥有丰富的铜、金、铅、锌等金属矿产资源,对其资源总量进行评价可以为国家"一带一路"战略决策提供基础数据。在对该区进行野外调查和1∶100万低密度地球化学调查的基础上,分析了小比例尺尺度下浅成低温热液型金(银)矿床的地质特征、关键控矿因素和找矿标志,构建了该类金(银)矿床的预测模型;认为该区NW向苏门答腊大断裂及其次级断裂与新生代岛弧岩浆岩具有密切的时空耦合关系,该断裂系统和新生代岩浆岩共同控制浅成低温热液型金(银)矿床的产出;已知金(银)矿床点和1∶100万低密度地球化学异常可以作为快速圈定研究区有利找矿地段的标志;并据此圈定成矿远景区5个,其中A级成矿远景区3处,B级成矿远景区2处;然后,利用通用密度模型预测了不同概率下的各远景区未知矿床数,并运用蒙特卡罗模拟预测了苏门答腊岛浅成低温热液型金(银)矿产在不同概率下的金(银)资源量。 相似文献
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系统阐述了新桥矿伴生金银的赋存状态和分布规律 ,对综合利用矿产资源 ,提高金银的回收率 ,以及深部资源预测、外围找矿均具有一定的指导意义 相似文献
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斑岩型铜钼矿床除主要成矿元素Cu,Mo外,还往往共(伴)生Re,Co,Au,Ag等重要元素,综合回收利用共(伴)生金属具有重大资源及环境效益。通过研究斑岩型铜钼矿床中共(伴)生元素Re,Co,Au,Ag的品位、储量、赋存状态及分布规律,认为Co主要以类质同象形式赋存于黄铁矿中,其分布与黄铁矿密切相关,通常浓集于绢英岩化带外侧;Au,Ag主要以自然金、银与金银系列矿物的形式产出,Au,Ag在不同硫化物中的含量、颗粒粒度以及赋存形式差异很大,Au在各蚀变带均有可能富集,但主要浓集区域是钾化带与石英-绢云母化带;Ag在早期主要以Cu-Ag-Au的形式富集于绢英岩化带,晚期以Pb-Zn-Ag形式赋存于青磐岩化带;Re的分布与绢云母化带的辉钼矿密切相关。 相似文献
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选择胶东玲珑金矿典型矿体47号脉为研究对象,应用基岩地球化学方法,测试微量元素含量,研究微量元素与金的相关关系、计算微量元素的浓集系数并确定其轴向分带,探讨微量元素对深部金成矿的指示意义,期待能对玲珑金矿深部找矿提供一些参考.初步认识如下:矿区金矿体的最佳指示元素依次为Au、Ag、Bi、As、Cu、Co、Mo、Sb;金矿体的轴向分带序列从上到下依次为As、Pb、Ag、Cu、Hg、Sb、Mo、Ni、Th、V、U、Mn、Zn、Bi、Co、Au;矿体中Au、Bi、Ag、As富集系数大,Cu、Co富集系数中等,而Zn在矿体中相对亏损.研究结果表明,在深部47号矿体仍有较好的成矿前景. 相似文献
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G. A. Palyanova Yu. L. Mikhlin N. S. Karmanov K. A. Kokh Yu. V. Seryotkin 《Doklady Earth Sciences》2017,474(2):636-640
The forms of Au and Ag occurrence in the crystallization products of melts in the Fe–S–Ag–Au system depending on the proportions of Fe/S and Ag/Au have been studied at (Fe + S)/(Ag + Au) = 0.1. It is shown that the S-rich systems with S/Fe = 2 contain Au–Ag sulfides and Au–Ag alloys. The systems depleted in S with S/Fe = 1 contain only Au–Ag alloys. The results of XPS provide evidence for the sulfide and metallic components of Au and Ag among the crystallization products of melts in the system studied at S/Fe = 2 and a metallic component with S/Fe = 1. According to the data of electron microprobe analysis, the content of “invisible” forms of noble metals in pyrite and pyrrhotite is < 0.024 wt % for Au and <0.030 wt % for Ag; the contents of “invisible” Au and Ag in troilites are 0.040 ± 0.013 wt % Au and 0.079 ± 0.016 wt % Ag. 相似文献
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R. G. Kravtsova V. L. Tauson G. A. Palyanova A. S. Makshakov L. A. Pavlova 《Geology of Ore Deposits》2017,59(5):375-390
The first data on native silver from the Rogovik Au–Ag deposit in northeastern Russia are presented. The deposit is situated in central part of the Okhotsk–Chukchi Volcanic Belt (OCVB) in the territory of the Omsukchan Trough, unique in its silver resources. Native silver in the studied ore makes up finely dispersed inclusions no larger than 50 μm in size, which are hosted in quartz; fills microfractures and interstices in association with küstelite, electrum, acanthite, silver sulfosalts and selenides, argyrodite, and pyrite. It has been shown that the chemical composition of native silver, along with its typomorphic features, is a stable indication of the various stages of deposit formation and types of mineralization: gold–silver (Au–Ag), silver–base metal (Ag–Pb), and gold–silver–base metal (Au–Ag–Pb). The specificity of native silver is expressed in the amount of trace elements and their concentrations. In Au–Ag ore, the following trace elements have been established in native silver (wt %): up to 2.72 S, up to 1.86 Au, up to 1.70 Hg, up to 1.75 Sb, and up to 1.01 Se. Native silver in Ag–Pb ore is characterized by the absence of Au, high Hg concentrations (up to 12.62 wt %), and an increase in Sb, Se, and S contents; the appearance of Te, Cu, Zn, and Fe is notable. All previously established trace elements—Hg, Au, Sb, Se, Te, Cu, Zn, Fe, and S—are contained in native silver of Au–Ag–Pb ore. In addition, Pb appears, and silver and gold amalgams are widespread, as well as up to 24.61 wt % Hg and 11.02 wt % Au. Comparison of trace element concentrations in native silver at the Rogovik deposit with the literature data, based on their solubility in solid silver, shows that the content of chalcogenides (S, Se, Te) exceeds saturated concentrations. Possible mechanisms by which elevated concentrations of these elements are achieved in native silver are discussed. It is suggested that the appearance of silver amalgams, which is unusual for Au–Ag mineralization not only in the Omsukchan Trough, but also in OCVB as a whole, is caused by superposition of the younger Dogda–Erikit Hg-bearing belt on the older Ag-bearing Omsukchan Trough. In practice, the results can be used to determine the general line of prospecting and geological exploration at objects of this type. 相似文献
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《Russian Geology and Geophysics》2014,55(2):252-258
The mineral and geochemical compositions of noble-metal (first of all, gold) deposits of the Fennoscandian, Siberian, and Northeast Asian orogenic belts are considered. These deposits are of several types: Au (disseminated Au–sulfide and Au–quartz), Au–Bi, Au–Ag, Au–Sb, Ag–Sb, Au–Sb–Hg, and Ag–Hg. They formed in different geodynamic settings as a result of the active motion of crustal tectonic blocks of different nature. Subduction processes (both at the front and at the rear of continent-marginal and island-arc magmatic arcs) resulted in Au–Ag, Ag–Sb, Ag–Hg, Au–Sb–Hg, and Au–Bi deposits. Collision events gave rise to Au and Au–Bi deposits. Intraplate continental rifting and formation of orogenic belts along the boundaries of block (plate) sliding led to the origin of Au and Au–Bi ores in association with Au–Ag, Au–Sb–Hg, and complex ores. In all cases, the formation of noble-metal mineralization was accompanied by magmatism of different types and metamorphism. Because of this diversity of ores, there is no single concept of the genesis of noble-metal mineralization. Several competing models of genesis exist: hydrothermal-metamorphic, pluton-metamorphic, plutonic, activity of mantle fluid flows, and multistage concentration during the crust–mantle interaction with the leading role of sedimentary complexes. 相似文献
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湖北银洞沟矿床是中国为数不多的较为典型的大型银矿床。文中系统总结了该矿床的地质特征,初步提出了矿床的成因类型。研究结果表明:银洞沟矿床产于秦岭造山带东南部武当群变质火山岩中,矿体受韧性剪切带控制,矿石类型主要为石英脉型和少量蚀变岩型,围岩蚀变矿物组合主要为石英、铁白云石、白云母、钠长石、绿泥石、黄铁矿等,成矿流体特征为低盐度、低密度、富含CO2±CH4±N2的水溶液,矿床上部为低品位银金矿体,中部为高品位银金矿体和少量铅锌矿体,深部银品位降低,金品位增高,同时出现较厚大铅锌矿体。其地质特征与典型的造山型矿床一致,表明其为一造山型银矿床,矿床矿化分带符合造山型矿床成矿模式——地壳连续模型,因此应该充分重视寻找矿山深部金、铅、锌、铜、钼等接替资源。 相似文献