陕西省银洞子银-铅多金属矿床外围铜矿成矿条件与找矿预测

银洞子银-铅多金属矿床位于秦岭泥盆系多金属成矿带中的柞水—山阳成矿区西部,是一个受多级断陷盆地控制的海底热水喷流沉积矿床,而这种矿床的成矿条件非常有利于铜的硫化物矿床的形成。根据矿床成矿元素分带特征,结合电阻率异常预测,矿床北部具有寻找大型-超大型铜矿体的远景。

河南省嵩县大坪银-铅-锌多金属矿床地质特征及找矿标志

通过工作实践认为,大坪银-铅-锌多金属矿床是火山喷流沉积—后期热液叠加改造富集的块状硫化物多金属矿床。区域上NWW—SEE向晚元古—早古生代形成的裂谷型二郎坪蛇绿岩套是本区找矿的最佳区段,具四个含矿层位。矿化、矿石、矿物、元素等成矿作用要素具明显分带特征,并与火山作用及喷流作用有关。区域构造、同生断裂及岩浆作用为重要控矿条件,而硫化物层、重晶石层、硅质岩是银-铅-锌矿床的重要找矿标志。

河南省罗山县白石坡银-铅-锌多金属矿床成因研究

白石坡银-铅-锌多金属矿床产于以中元古界龟山岩组为基底的NE向白石坡正断裂带内,与中生代火山活动有密切关系。文章较系统地从矿区地质、矿床地质、微量元素、同位素及流体包裹体特征等方面,深入分析了成矿物质来源、介质来源和控矿因素及成矿机理。认为该矿床属火山活动后期的中—低温热液矿床,划分为早期与韧性剪切带有关的金、中期潜火山热液活动银多金属及后期浅成火山热液活动主银成矿的三个成矿期,并建立了矿床成矿模式。

滇西白象厂铅-锌-银-(铜-金)多金属矿床矽卡岩型铁-铜-(金)矿化类型的发现及找矿潜力分析

滇西白象厂铅-锌-银-(铜-金)多金属矿床是“三江”特提斯成矿域金沙江—哀牢山富碱斑岩带中的典型矿床之一,主要由与喜马拉雅期石英二长斑岩密切相关的斑岩型铜-金(钼)矿化和热液脉型铅-锌-银矿体组成。目前该矿床浅部的主要成矿类型和开采对象是大理岩中热液脉型铅-锌-银矿体,但矿床深部是否存在矽卡岩型成矿类型和斑岩型多金属成矿系统至今不明,直接影响到矿床资源潜力的判断和深部找矿工程部署。为此,应用大比例尺蚀变岩相填图方法,在矿区坑道PD7-3和PD2-3,发现矽卡岩型铁-铜-(金)矿化(体),且矽卡岩内分带性完整,从内接触带→外接触带,特征矿物组合依次为透辉石-石榴子石(钙铁-钙铝榴石)→绿帘石-阳起石-角闪石-磁铁矿→黄铜矿-斑铜矿-(辉钼矿-金)-磁黄铁矿-石英-萤石-方解石;各蚀变带内∑REE、LREE/HREE、(La/Yb)N、(La/Sm)N总体呈逐渐降低的趋势,表明成矿流体交代作用明显。弱Eu和Ce负异常→强Eu正异常和弱Ce负异常→弱Eu正异常和Ce负异常,指示矽卡岩型矿石形成于较高温氧化环境。矽卡岩型矿石Y/Ho比值相近,表明它们具有一致的成矿物质来源。在此基础上,与区域内毗邻的北衙超大型金多金属矿床、马厂箐大型铜钼金多金属矿床对比研究,认为该矿床深部具有矽卡岩型铜-金矿的找矿潜力。本次发现的矽卡岩型铁-铜-(金)矿化类型,不仅为该矿床斑岩型成矿系统提供了新依据,而且对矿床深部及外围找矿勘查具有重要意义,对“三江”特提斯成矿域成矿研究的价值不言而喻。

印尼中苏拉威西波龙谷金矿地质特征——一种斑岩型金-银、铅、锌多金属矿床

波龙谷金矿床产于新生代火山岩岛弧环境。金矿体主体赋存于石英闪长玢岩岩体和岩墙之内和内、外接触带,矿石构造以细脉状、细粒浸染状为主,蚀变带和矿化带受石英闪长玢岩岩体、岩墙形态和接触带控制。矿床形成与玢岩岩体、岩墙有密不可分的关系,属于斑岩型金-银、铅、锌多金属矿床。

Late Mesozoic magmatism and tectonic evolution in the Southern margin of the North China Craton

Late Mesozoic granitic magmatism(158–112 Ma) are widespread in the southern margin of the North China Craton(NCC), contemporary with many world-class Mo-Au-Ag-Pb-Zn polymetallic deposits. There are abrupt changes in the elements and isotopic compositions of these granites at about 127 Ma. The early stage(158–128 Ma) granites show slightly or no negative Eu anomalies, large ion lithophile elements enriched and heavy REE depleted(such as Y and Yb), belonging to typical I-type granite. The late stage(126–112 Ma) granites are characterized by A-type and/or highly fractionated I-type granite, with higher contents of SiO2, K2 O, Y, Yb and Rb/Sr ratio and lower contents of Sr, δEu value and Sr/Y ratio than that of the early-stage granites.Moreover, the whole rock Nd and Hf isotopic compositions of the granites younger than 127 Ma show more depleted than those of the older one. The two stages of Late Mesozoic granites were derived from a source region of the ancient basement of the southern margin of the NCC incorporated the mantle material. The late stage(126–112 Ma) granites contain more fractions of mantle material with depleted isotopic composition than the early ones. The granites record evidence for a strong crust-mantle interaction. They formed in an intracontinental extensional setting which was related to lithospheric thinning and asthenospheric upwelling in this region, which was possibly caused by westward subduction of the Paleo-Pacific plate. 127 Ma is an critical period of the transformation of the tectonic regime.