新疆阿吾拉勒山西段穷布拉克铜矿床流体包裹体和碳氧硫同位素研究

穷布拉克铜矿床是新疆阿吾拉勒铁铜成矿带西段规模最大的一个铜矿床.本文对该矿床Ⅰ号矿体3种矿石中的方解石脉开展了流体包裹体和稳定同位素研究,结果表明:3种矿石的包裹体均为气液两相包裹体,流体体系为NaCl-H2O体系.包裹体的均一温度为85～343℃,盐度范围为(1.57～17.79) wt％NaCl eq.,密度为0.7～1.05 g/cm3.方解石的δ 13C值为-3.2‰～-6.5‰,平均-4.08‰,显示出幔源的特征.成矿流体的δ18O值为0.45‰～4.44‰.硫化物δ 34S值变化范围较大,为-10.5‰～5.5‰.Ⅰ号矿体与矿区内的火山热液型矿体具有相似的流体包裹体和稳定同位素特征,沉积特征不明显,并非沉积-改造型,与其他矿体具有相同的成因类型.成矿流体由火山热液和参与了水-岩反应的大气水两种流体混合而成,以火山热液占主导地位.矿物沉淀主要与流体混合后缓慢降温有关,但混合后的稀释作用以及水-岩反应导致pH值升高可能也起到了一定作用.     

铜矿数字矿床模型专家系统的原理与技术实现

数字矿床模型是指将传统的地质学语言描述的矿床特征,转化成计算机可以识别的数字和符号,并加入人工智能的推理规则和知识,使之具备矿床自动推理和勘查辅助决策的功能。本项研究是在基于前人的工作基础上,结合国内外数字矿床模型的先进理论和经验进行了系统的实现。本文论述了铜矿床数字化的方法原理以及在系统实现时的关键性技术问题。系统知识库和规则库的建立是在多位铜矿专家的协助下完成的,专家对一系列先验概率等相关参数进行赋值,并用统计学方法下进行了处理。铜矿专家系统中知识库和规则库的保存和管理使用了数据库开发技术,采用数据挖掘作为知识发现的新手段。系统使用产生式规则,采用主观贝叶斯方法为推理的总体算法,搜索策略采用广度优先向前搜索的策略;在地质证据的输入方面不只提供与铜矿类型直接相关的证据,同时系统也提供了更为充分的地质证据,使推理的过程更加可靠和合理,同时地质词典功能的加入方便用户对相关地质术语进行查询和检索。系统不仅能实现单一成因的矿床进行推理,也能对复合矿床类型进行推理。     

铜与间氯偶氮安替比林显色反应研究及铜的形态分析

在ｐＨ４８的邻苯二甲酸氢钾＿ＮａＯＨ缓冲介质中，Ｃｕ（Ⅱ）与间氯偶氮安替比林形成１∶２的蓝色配合物，其最大吸收峰位于６３０ｎｍ处，表观摩尔吸光系数为４２６×１０４Ｌ·ｍｏｌ－１·ｃｍ－１，Ｃｕ（Ⅱ）的质量浓度在０～２ｍｇ／Ｌ时符合比尔定律。应用该法测定了桃叶及牛肝标样中的铜含量，测定值与标准值一致。结合活性炭分离，建立了铜的形态分析流程，并测定了茶汤中铜的各种主要形态及其分布。     

~(186)锇和~(188)锇双同位素稀释法在辉钼矿铼-锇测年中的应用

以经过负离子热表面电离质谱仪准确标定的1 86Os和1 88Os双同位素作为稀释剂 ,利用1 86Os和1 88Os计算1 87Os的含量 ,能有效地减少用等离子体质谱仪测定1 87Os时由于仪器本身的不稳定性及质量歧视效应所产生的误差 ,使测量准确度比用单同位素作为稀释剂有明显提高。方法应用于辉钼矿Re -Os年龄标准参考物及样品的测定 ,结果与参考值一致 ,5份试样测定的RSD <3%。     

东秦岭(河南段)二郎坪群铜多金属成矿环境及成矿效应

二郎坪群位于北秦岭造山带中,在二郎坪群这套火山—沉积岩系中,含有在河南省占有重要地位的铜多金属矿。文章通过对二郎坪群的沉积建造特征、变基性火山岩的形成环境和岩浆来源特征的研究,认为二郎坪群形成于弧后盆地环境,其盆地规模和岩浆来源在盆地东西方向上存在差异,而铜多金属矿床成矿作用与二郎坪群的形成环境和变基性火山岩岩浆来源有着紧密的内在联系。二郎坪群弧后盆地在海底喷流作用下形成了不同成矿元素组合的铜-锌型和铅-锌型两种矿床类型。     

安徽铜陵冬瓜山热液叠加改造型铜矿床流体包裹体地球化学特征

研究了安徽冬瓜山热液叠加改造型铜矿床流体包裹体地球化学特征（包裹体均一温度、盐度、压力、成分、流体的H，O，C和Cu同位素），探讨了成矿流体的性质及其来源。认为该矿床是在岩浆水和后期少量大气水的加入而形成的混合热液共同作用下，活化碳酸盐岩地层和石英闪长岩中的铜等成矿元素，形成含矿热液，并以铜的氯络合物方式运移，在弱还原性条件下使原始沉积矿胚层加厚变富。     

青海龙尾沟铜、金矿床地质特征、矿床成因及成矿远景分析

龙尾沟铜、金矿床是在青海省柴北缘成矿亚区内所取得的重大找矿突破,该矿床产于下元古界达肯大坂群(Pt1dk)地层内,并受F6断裂破碎带控制.通过对矿床地质特征、矿石及花岗斑岩脉地球化学特征研究,首次提出龙尾沟铜、金矿床是与岩浆作用有关的斑岩型矿床.从已查明铜、金矿床(体)的控矿因素和矿化特征分析,深部存在规模较大矿化体的前景,应进一步加强该地区深部勘探及研究力度,以期获得找矿的更大突破.     

Fluid inclusion evidence for hydrothermal fluid evolution in the Darreh-Zar porphyry copper deposit,Iran

The Darreh-Zar porphyry copper deposit is associated with a quartz monzonitic–granodioritic–porphyritic stock hosted by an Eocene volcanic sedimentary complex in which magmatic hydrothermal fluids were introduced and formed veins and alteration. Within the deepest quartz-rich and chalcopyrite-poor group A veins, LVHS2 inclusions trapped high salinity, high temperature aqueous fluids exsolved directly from a relatively shallow magma (0.5 kbar). These late fluids were enriched in NaCl and reached halite saturation as a result of the low pressure of magma crystallization and fluid exsolution. These fluids extracted Cu from the crystallizing melt and transported it to the hydrothermal system. As a result of ascent, the temperature and pressure of these fluids decreased from 600 to 415 °C, and approximately 500–315 bars. At these conditions, K-feldspar and biotite were stabilized. Type A veins were formed at a depth of ∼1.2 km under conditions of lithostatic pressure and abrupt cooling. Upon cooling and decompressing, the fluid intersected with the liquid–vapor field resulting in separation of immiscible liquid and vapor. This stage was recorded by formation of LVHS1, LVHS3 and VL inclusions. These immiscible fluids formed chalcopyrite–pyrite–quartz veins with sericitic alteration envelopes (B veins) under the lithostatic–hydrostatic pressure regime at temperatures between 415 and 355 °C at 1.3 km below the paleowater table. As the fluids ascended, copper contents decreased and these fluids were diluted by mixing with the low salinity-external fluid. Therefore, pyrite-dominated quartz veins were formed in purely hydrostatic conditions in which pressure decreased from 125 bars to 54 bars and temperature decreased from 355 to 298 °C. During the magmatic-hydrothermal evolution, the composition and P–T regime changed drastically and caused various types of veins and alterations. The abundance of chalcopyrite precipitation in group B veins suggests that boiling and cooling were important factors in copper mineralization in Darreh-Zar.     

The Rio Narcea gold belt intrusions: geology, petrology, geochemistry and timing

This paper discusses the petrographical, mineralogical and geochemical characteristics of the intrusive rocks located along the Rio Narcea Gold Belt, and the timing of formation of the El Valle-Boinás deposit. Rocks in the belt range from quartz-monzodiorites through quartz-monzogranites to monzogranites. The former are made up of pyroxene (clino and ortho), amphibole (magnesiohornblende), biotite, zoned plagioclase (An35-70), and to a lesser degree quartz and K-feldspar. The monzogranites consist of biotite, zoned plagioclase (An30-60), quartz and K-feldspar. All igneous rocks are characterized by the presence of ilmenite and the lack or scarce presence of magnetite indicating their formation under reducing conditions. The granitoids are calc-alkaline I type, potassium-rich and highly reducent with more ferrous than ferric iron. Their characteristics are like the plutons associated with gold and copper (zinc) skarns, but their characteristics reflect more reducent formation conditions, increasing their capacity to form gold skarns.The Boinas granitoid emplacement occurred at about 303±6 Ma and generated calcic and magnesic skarns at the contact with limestone and dolostones of the Láncara Formation. Skarns and granitoids were first altered to amphibole and sericite, respectively, and mineralized at 302±9 Ma. The intrusion of subvolcanic porphyritic dikes produced a second period of alteration at 285±4 Ma, characterized by carbonatization and sericitization of the monzogranites and chloritization and serpentinization of the skarns. The later intrusion of diabasic dikes at 255±6 Ma produced limited carbonatization, silicification and sericitization and hypogene oxidation of the previous stages. Supergene oxidation then occurred at the top of the ore and along fractures and breccias.     

高峰100号矿体硫、铅同位素特征

10 0号矿体的成矿物理化学环境为 :成矿温度 30 0± 30℃ ;成矿压力为 84.2× 10 5Pa ;LogfO2 =- 30 .4～- 35 .6 ,LogfCO2 =- 2 .5 5～ +0 .36 ,LogfS2 =- 8.3～ - 11.0 ,pH =4.2～ 4.9。同位素的分析结果 :硫化物的硫同位素为 6 4‰～ 12 .3‰ ,δ3 4 SΣS 值为 6 6～ 13 8;2 0 6Pb 2 0 4Pb值为 17 4 91～ 18 96 0 ,2 0 7Pb 2 0 4Pb值为 15 5 39～15 940 ,2 0 8Pb 2 0 4Pb值为 37 95 7～ 39 4 90。表明 10 0号矿体的硫源是混合硫 ,铅源是两种异常铅混合的结果。