安徽铜陵冬瓜山铜(金)矿床H-O-S-Pb同位素组成及其示踪成矿物质来源

冬瓜山铜(金)矿床中主矿体成层状,受石炭系层位控制,对于其物质来源尚存在较大分歧。为了查明冬瓜山铜(金)矿床成矿物质来源,本文对冬瓜山铜(金)矿床不同类型矿体的氢、氧、硫、铅同位素进行了系统地测定。并将冬瓜山铜(金)矿床与铜陵矿集区内典型矽卡岩型矿床的硫、铅同位素组成进行了对比研究。结果表明:冬瓜山铜(金)矿床不同类型矿体之间具有相同的物质成分来源,不同类型矿体的成矿流体主要来源于岩浆水,硫源均为岩浆硫,且与区域上典型矽卡岩型矿床的硫同位素组成一致,铅同位素特征表明,不同类型矿体铅的来源主要为与岩浆作用有关的幔源铅。

安徽铜陵冬瓜山铜(金)矿床成矿流体特征及成矿过程探讨

流体包裹体的研究表明冬瓜山铜(金)矿床原生流体包裹体分为气液两相水溶液包裹体(Ⅰ型)和含子矿物多相水溶液包裹体(Ⅱ型),以Ⅰ型包裹体为主。同一矿物中多种类型包裹体共存,且均一温度相近、均一方式不同,显示成矿过程中流体可能发生过沸腾作用。流体包裹体均一温度大致可分为318.8～547.5℃、220.1～378.2℃和196.7～263.2℃三个区间,对应流体密度和均一压力分别为0.86～0.98 g/cm3和(219～661)×105Pa、0.66～1.08 g/cm3和(26～190)×105Pa、0.88～0.96 g/cm3和(17～48)×105Pa,盐度w(NaCleq)峰值为12%～16%和40%～48%。结合成矿流体的演化特征,对成矿过程进行了探讨,认为流体的不混溶是引起成矿物质沉淀富集成矿的重要因素。

铜陵矿集区冬瓜山铜(金)矿床成因分析

冬瓜山矿床是安徽铜陵矿集区内的大型铜(金)矿床,赋存于中—上石炭统黄龙组和船山组(C_(2+3))地层中,主矿体受地层、褶皱及层间滑脱带控制,呈层状产出。长期以来,人们对冬瓜山矿床的成因认识还存在较大的争议。本文从地层、构造、岩浆岩等方面对冬瓜山矿床的成矿地质条件进行了分析,认为围岩灰岩、砂岩及大理岩中Cu含量低,不具备提供成矿物质的能力,而岩体中Cu含量高于克拉克值近两个数量级,具有提供成矿物质的能力;构造上青山脚岩体控制了斑岩型矿体的产出,青山背斜和层间滑脱构造控制了主矿体的产状及规模;提出冬瓜山矿床为与燕山期岩浆侵入有关的斑岩-矽卡岩型铜(金)矿床。

安徽铜陵冬瓜山矿床矿石硫化物环带及地质意义

安徽冬瓜山矿床是铜陵矿集区内一个重要的大型铜（金）矿床,颇受关注,成因认识分歧较大。矿床内块状硫化物矿石中普遍发育以黄铁矿为核部、黄铜矿为中间带、磁黄铁矿为边部带的硫化物环带。这些环带核部黄铁矿多呈自形-半自形晶,黄铜矿呈他形晶围绕黄铁矿沉淀,磁黄铁矿呈他形分布在黄铜矿外围,内带常被外带硫化物溶蚀交代。硫同位素分析结果显示,环带中硫化物矿物的硫同位素（δ34S=1.6‰~5.1‰）具有岩浆硫源特征,同时从核部黄铁矿到中间带黄铜矿,再到边部磁黄铁矿δ34S值逐渐降低。以上特征表明环带从内到外硫化物之间并非平衡共生关系,而是黄铁矿、黄铜矿和磁黄铁矿先后依次晶出。硫化物环带核部粗粒黄铁矿（粒径大于1.5cm）的Co、Ni含量分别为292×10-6~1504×10-6和32.7×10-6~39.9×10-6,Co/Ni=7.32~46.0（平均26.7）,与海底火山喷流沉积型黄铁矿的Co、Ni特征基本一致。核部黄铁矿由颗粒中心向边缘,Fe/S原子比值、Mo和Co含量先逐渐升高,再逐渐降低,而Cu、Zn等成矿元素主要富集于颗粒边缘,并向边缘有逐渐升高趋势。与此同时,细粒黄铁矿（粒径小于0.5cm）中的Cu、Zn等元素的含量明显高于粗粒黄铁矿。环带中三种硫化物矿物的REE配分曲线和微量元素蛛网图极为相似,相对富集LREE、Rb、Th等元素,而亏损Nb、Ta、Zr、Hf、Sr、Ba和HREE等元素,由环带核部到边部δEu逐渐减小,与矿区石英二长闪长（玢）岩表现出较高的相似性。以上特征综合分析表明,冬瓜山铜（金）矿床中硫化物环带经历了以下形成过程：石炭纪海底喷流沉积作用在矿区形成沉积黄铁矿,到燕山期,在区内强烈的构造-岩浆活动作用下,致使早期沉积的黄铁矿首先发生变质重结晶作用,形成粒状黄铁矿,随后岩浆热液对其进行叠加改造,并在岩浆热液作用下相继围绕粒状黄铁矿增生,依次沉淀出热液型黄铁矿、黄铜矿和磁黄铁矿,最终形成硫化物环带。这一认识,结合硫化物环带中元素及硫同位素特征进一步表明冬瓜山铜（金）矿床的形成先后经历了古生代海底喷流沉积成矿作用和燕山期岩浆热液成矿作用,矿床中的成矿物质（特别是Cu、Zn等成矿元素）主要来源于燕山期岩浆热液,但石炭系海底喷流沉积作用也提供了部分物质（例如,Fe、S、Mo、Co和Ni等）。此外,环带中微量元素的变化特征表明,随着硫化物环带的形成,成矿热液系统的温度、硫逸度和氧逸度逐渐降低和（或）p H值升高。

Rock-forming mechanism of Qingshanjiao intrusion in Dongguashan copper(gold) deposit, Tongling area, Anhui province, China

Dongguashan deposit is a large porphyry-skarn copper（gold） deposit in Tongling ore district. The Qingshanjiao intermediate acid intrusion of Yanshanian had a direct genetic relationship with mineralization. The magma origin, rock-forming dynamic background and rock-forming process were studied, and the rock-forming mechanism of Qingshanjiao intrusion was discussed, based on geological characteristics, detailed observation of petrography and systematic investigation of petrochemistry, trace elements and REE geochemistry characteristics of Qingshanjiao intrusion. The results show that Qingshanjiao rock body belongs to high-K calc-alkaline series with higher LREE elements, Th, Rb and Sr abundance, but depleted in HREE elements, Ba, Nb and Ta. The primary magma originated from the mantle-crust mixtures which were caused by basaltic magma of mantle mixing with syenite magma of partial melting of the lower crust, and the formation environment of Qingshanjiao intrusion was emplaced in the transitional environment from compression to extension. The Harker diagram and hybrid structures of plagioclase and potassium feldspar indicate that the fractional crystallization occurred in the process of magmatic evolution. The petrochemistry, trace elements and REE geochemistry characteristics indicate that the magma was contaminated by crustal material during the rock-forming. These results suggested that the Qingshanjiao intrusion was formed by fractional crystallization and assimilation and hybridization of mantle-crust magma in the transitional environment from compression to extensional.