青海省乌兰乌珠尔斑岩铜矿床地质特征与成因

乌兰乌珠尔斑岩铜矿位于柴达木盆地西缘,为受花岗斑岩脉控制的斑岩型铜矿。岩石化学、稀土和微量元素特征表明:控矿花岗斑岩与围岩(似斑状)斜长花岗岩为钙碱性系列,具轻稀土富集、显著的δEu负异常和Sr、Ba、Ca亏损特征,形成于同碰撞造山环境,与华力西晚期—印支期松潘—甘孜古特提斯洋俯冲碰撞闭合有关。控矿花岗斑岩及其围岩热液蚀变强烈,显示良好的蚀变分带。主要蚀变有钾硅化、绢英岩化和青磐岩化,控矿斑岩内部为钾化和硅化叠加绢英岩化带,近斑岩两侧围岩为绢英岩化带,外侧为青磐岩化带。铜矿化强度与蚀变强度有显著正相关关系。铜矿体空间分布、产状及规模受控矿花岗斑岩体控制。矿床的矿物组合、热液蚀变、硫、氧同位素和流体包裹体测温结果显示矿床形成于中高温环境,流体和成矿物质主要来源于岩浆,乌兰乌珠尔铜矿属与高中温岩浆热液作用有关的斑岩型铜矿。     

巴基斯坦山达克铜金矿围岩蚀变与矿床成因

巴基斯坦山达克铜金矿矿体呈似层状、透镜状,主要产于云英闪长斑岩中。矿体围岩蚀变十分强烈,且具有明显的分带性,从中心向外侧依次出现钾化-硅化带、黄铁绢英岩化带,再到青磐岩化带。该矿床具有典型的钙碱系列斑岩型矿床特征。     

西藏多不杂富金斑岩铜矿床蚀变与脉体系统

多不杂富金斑岩铜矿床是班公湖_怒江成矿带第一个勘查评价出的大型斑岩铜矿床。文章在对矿区野外地质编录及室内镜下鉴定的基础上,对矿床蚀变与脉体系统进行了详细研究。结果表明,矿区发育典型斑岩铜矿蚀变系统,且分带性非常明显,从斑岩体内部向外具有钾硅酸盐化带(外缘叠加泥化蚀变与绢云母化蚀变)→绢英岩化带(大部分叠加有泥化蚀变)→青磐岩化带→角岩化带的分带特征。根据穿插关系、矿物组合及蚀变晕等特征可划分出21种脉体,早期形成的脉体包括在钾硅酸盐化带发育的磁铁矿细脉(M型脉共1种)、石英±钾长石±黑云母±磁铁矿±黄铜矿±黄铁矿脉(A型脉共8种)以及具有矿物组合分带特征的石英±磁铁矿±黑云母+钾长石+黄铜矿+黄铁矿脉(EB型脉共2种),中期形成的脉体包括主要在绢英岩化与泥化叠加带发育的石英±黄铜矿±黄铁矿±辉钼矿±石膏脉(B型脉共5种),晚期形成的脉体包括主要在青磐岩化带发育的石英±黄铁矿±黄铜矿±石膏±方解石脉(D型脉共5种),以A、B、D型脉最为发育。与矿化密切相关的蚀变带主要是钾硅酸盐化带、绢英岩化与泥化叠加带,与矿化密切相关的脉体主要为A型脉及B型脉。与国内外典型矿床相比,多不杂矿床蚀变模式及矿物组合与"二长岩"模式相似。多不杂矿床从内部的钾硅酸盐化带至外部的青磐岩化带均发育大量磁铁矿,且在青磐岩化带发育大量无矿石膏网脉,此是多不杂矿床的独有特色。     

西藏多不杂斑岩铜金矿床地质与蚀变

[摘 要]西藏多不杂斑岩铜金矿是近年来新发现的一个矿床,位于班公湖-怒江成矿带西段。多不杂矿床内发育三期花岗闪长斑岩,侵入到侏罗系曲色组变砂岩中,北东向断层是多不杂矿床的主要控岩断层。多不杂矿床由内向外发育钾化、绢英岩化、青磐岩化,钾化主要发育于第一期花岗闪长斑岩出露区域,绢英岩化环绕钾化带发育,并叠加在钾化带之上,青磐岩化在矿床西侧的玄武安山岩和南侧的火山角砾岩中呈团块状发育。多不杂矿床的的铜矿化以黄铜矿矿化为主,金矿化与铜矿化密切共生。黄铜矿化主要发育于第一期花岗闪长斑岩及其与变砂岩接触带内,第一期花岗闪长斑岩为多不杂矿床的成矿斑岩。     

香格里拉陆家村银金多金属矿围岩蚀变及矿床成因

矿床具斑岩型铜矿化蚀变特征,从岩体中心向外,蚀变呈环带状分带发育,依次为强硅化带→钾硅化带→绢英岩化带→青磐岩化带。矿化在浅部表现为断裂破碎带控制的热液脉型Cu、Au、Pb、Ag矿床,深部则为斑岩型Cu、Mo矿床。     

中甸普朗斑岩型铜矿床围岩蚀变初步研究

普朗斑岩型铜矿床是近年发现的一个重要铜矿床,通过大量的野外地质资料收集和室内综合分析研究,结合钻探、物探、化探和遥感技术应用的成果,初步认为普朗印支期斑岩铜矿床热液蚀变是经过多期次、多阶段构造-热液事件形成的,具有由中心向外依次为硅化核、硅化、钾化带-绢英岩化带-青磐岩化带-角岩化带的面型蚀变特征。其中硅化、钾化、绢英岩化蚀变带与铜矿关系密切。蚀变作用既影响岩(矿)石的结构、构造,又导致矿石中主要氧化物含量和Cu品位的变化。矿化与蚀变引起的物探、化探和遥感异常有较好的关联性,异常是找矿与勘查的直接标志和指导工程布置的依据,对于在中甸地区寻找与勘查同类型矿床有重要意义。     

西藏多龙矿集区波龙斑岩铜矿床蚀变与脉体系统

波龙铜矿床是多龙矿集区继多不杂斑岩铜矿床后发现的又一大型斑岩铜矿床.文章在详细的野外地质编录及室内镜下鉴定基础上,对波龙斑岩矿床蚀变与脉体系统进行系统梳理.结果表明,波龙矿床发育明显的蚀变分带,从深部(或核部)往浅部(或外侧)具有钾化带→黄铁绢英岩化带→泥化叠加黄铁绢英岩化带→角岩化带(或外侧的青磐岩化带)的蚀变分带特征.共识别出M、A、B、D4种脉体类型,以A、B脉最为发育.与成矿关系密切的主要为钾化带、黄铁绢英岩化带及A、B脉.与国内外典型斑岩矿床蚀变特征相比,波龙矿床蚀变特征总体与“二长岩”模式相似,特征矿物组合与阿根廷Bajo de la Alumbrera矿床,国内驱龙铜矿、多不杂铜矿等都具有相似之处.但波龙矿床从钾化带至黄铁绢英岩化带都大量发育的稀疏-稠密浸染状及脉状磁铁矿是该矿床的独有特色.     

关于建立斑岩型铜矿床勘查标识体系的初步探讨

斑岩型铜矿床勘查标识体系,是建立在全球超大型.大型斑岩型铜矿床丰富研究成果和勘查经验基础上,凝炼不同矿床之间的共性和差异性来作为斑岩型铜矿床普适性标志和区分标准,探寻矿床特征与勘查方法之间的内在联系,最大程度结合科研成果,优选科学的勘查方案并给出评价依据,构建以地质事实→成矿机制研究→勘查方法应用“三位一体”的勘查标识体系。该体系架构分为矿床地质、矿床成因机制和勘查方法三个部分。建立斑岩型铜矿床勘查标识体系将有利于增进对斑岩型铜矿床的有效勘查。本文以特提斯.喜马拉雅成矿域的西藏驱龙斑岩型铜.钼矿床、环太平洋东段成矿域的智利ElTeniente斑岩型铜.钼矿床和中亚成矿域东部的蒙古OyuTolgoi斑岩型铜.金矿床三个超大型斑岩型铜矿床为例,重点对比勘查标识体系中矿床地质和致矿岩体地球化学特征,归纳提炼不同矿床之间的共性和差异,对构建斑岩型铜矿(床)勘查标识体系进行初步探讨。研究结果显示:产于不同构造环境下的三个斑岩型铜矿床中均发育钾化带、青磐岩化带和绢英岩化带;铜矿化在钾化带和绢英岩化带中均有发育,钼矿化更倾向于在含水蚀变如绢云母化带、石英.绢云母蚀变部位,金矿化赋存于钾化带发育部位;矿化中心向矿区外围硫化物具有斑铜矿→黄铜矿(+斑铜矿)→黄铁矿的分布规律,铜矿化和钼矿化相叠加,但高品位的铜钼矿体相分离。驱龙矿床未发育ElTeniente矿床和OyuTolgoi矿床共有的(高级)泥化蚀变,可能与其形成环境或剥蚀有关。在地球化学数据收集中,为了确保数据分析的有效性提出筛选方法和程序。岩石地化数据结果显示:致矿斑岩体主要由30%~50%斜长石斑晶和60%左右基质(石英、钾长石)组成,均为高钾钙碱性、过铝质、埃达克质岩石,具有相似的右倾型稀土元素配分模式;但是致矿岩体的硅碱成分、稀土元素配分模式、Sr-Nd同位素表现出与产出环境一致的变化规律,Sr/Y-Y图解显示ElTeniente矿床较驱龙矿床和OyuTolgoi矿床的致矿岩体表现出更典型埃达克岩特征。总之,斑岩型铜矿勘查标识体系的提出和以三个矿床为例的初步探讨为下一步构建该勘查体系奠定了一定的基础。     

福建省紫金山矿田东南矿段铜钼矿床蚀变与矿化特征

紫金山矿田东南矿段铜钼矿床地处紫金山浅成低温热液型铜金矿床和罗卜岭斑岩型铜钼矿床之间。利用近红外光谱技术测试蚀变矿物特征,并结合地质填图、钻孔编录和岩矿鉴定等工作,划分出钾化带、绿泥石绢英岩化带、黄铁绢英岩化带、地开石硅化带、明矾石地开石硅化带等5个蚀变带。钻孔编录和镜下观察发现,金属矿物分为2个期次,生成顺序为磁铁矿-黄铁矿（第1期）→赤铁矿→辉钼矿-黄铜矿-斑铜矿-黄铁矿（第2期）→硫砷铜矿-蓝辉铜矿-铜篮。矿化类型与蚀变分带关系密切：以黄铜矿+斑铜矿+辉钼矿为主的Ⅱ号矿体产出于绿泥石绢英岩化带,与罗卜岭铜钼矿的蚀变矿化特征相似;以蓝辉铜矿+铜蓝交代黄铜矿+斑铜矿为主的Ⅳ号主矿体主要产出于地开石硅化带和明矾石地开石硅化带底部;以蓝辉铜矿+铜蓝+硫砷铜矿为主的Ⅴ号矿体产出于明矾石地开石硅化带,与紫金山铜金矿的蚀变矿化特征相似。明矾石温度分带显示具有罗卜岭斑岩和紫金山火山机构2个高温中心,中、低温混合明矾石化与Ⅳ号主矿体空间上呈显耦合关系。另外,Ⅳ号主矿体的云母矿物Al-OH吸收峰小于2205 nm。初步认为Ⅳ号主矿体是紫金山浅成低温热液叠加罗卜岭斑岩矿床外带所形成。     

云南中甸普朗斑岩铜矿成因探讨

普朗斑岩铜矿位于义敦岛弧带南段,产于印支-燕山早期普朗复式斑(玢)岩中.主要岩性由石英闪长玢岩、石英二长斑岩和花岗闪长斑岩组成,岩石化学和地球化学特征显示为碱性岩石系列Ⅰ型花岗岩.成矿流体具高盐度和成矿温度150～300℃变化.硫同位素834CDT丌为-2.23‰～3.75‰,采源于深源岩浆.矿床的构造作用、液压致裂作用和蚀变脉体形成等成矿机理经历了一个复杂过程.成岩和成矿作用的时间大致为235～206 Ma,具多阶段性,其中石英-辉钼成矿阶段为(213±3.8)Ma,成岩和成矿时代主体为印支期.矿床蚀变由中心向外依次为硅化钾化带-绢英岩化带-青磐岩(角岩)化带的面型蚀变特征.成因类型属岛孤斑岩型铜矿床.     

Geology and Re-Os Geochronology of Mineralization of the Miduk Porphyry Copper Deposit, Iran

The Miduk porphyry copper deposit is located in Kerman province, 85 km northwest of the Sar Cheshmeh porphyry copper deposit, Iran. The deposit is hosted by Eocene volcanic rocks of andesitic–basaltic composition. The porphyry‐type mineralization is associated with two Miocene calc‐alkaline intrusive phases (P1 and P2, respectively). Five hypogene alteration zones are distinguished at the Miduk deposit, including magnetite‐rich potassic, potassic, potassic–phyllic, phyllic and propylitic. Mineralization occurs as stockwork, dissemination and nine generations (magnetite, quartz–magnetite, barren quartz, quartz‐magnetite‐chalcopyrite‐anhydrite, chalcopyrite–anhydrite, quartz‐chalcopyrite‐anhydrite‐pyrite, quartz‐molybdenite‐anhydrite ± chalcopyrite ± magnetite, pyrite, and quartz‐pyrite‐anhydrite ± sericite) of veinlets and veins. Early stages of mineralization consist of magnetite rich veins in the deepest part of the deposit and the main stage of mineralization contains chalcopyrite, magnetite and anhydrite in the potassic zone. The high intensity of mineralization is associated with P2 porphyry (Miduk porphyry). Based on petrography, mineralogy, alteration halos and geochemistry, the Miduk porphyry copper deposit is similar to those of continental arc setting porphyry copper deposits. The Re‐Os molybdenite dates provide the timing of sulfide mineralization at 12.23 ± 0.07 Ma, coincident with U/Pb zircon ages of the P2 porphyry. This evidence indicates a direct genetic relationship between the Miduk porphyry stock and molybdenite mineralization. The Re‐Os age of the Miduk deposit marks the main stage of magmatism and porphyry copper formation in the Central Iranian volcano‐plutonic belt.     

The San Jorge porphyry copper deposit, Mendoza, Argentina: a combination of orthomagmatic and hydrothermal mineralization

The San Jorge porphyry copper deposit (SJPCD) is hosted by Carboniferous clastic sedimentary rocks and Permian intrusions located within the Permo-Triassic belt of Chile and Argentina. Its hypogene mineralization and alteration are products of superposed orthomagmatic and hydrothermal events that were strongly fault controlled. Copper related to orthomagmatic processes includes disseminated chalcopyrite in the matrix of porphyritic granodiorite and andesite, and chalcopyrite with tourmaline and quartz in breccias, both of which have accompanying potassic alteration. Soon thereafter, disseminated chalcopyrite is associated with a structurally controlled silicification of the sedimentary sequence. Finally, multiple episodes of hydrofracturing, probably driven by a deep-seated intrusion, deposited sulfide minerals in veinlets throughout the sedimentary sequence; the centers of these systems are characterized by potassic alteration. Total sulfides, which include chalcopyrite, pyrite, arsenopyrite, and pyrrhotite, and pyrite:chalcopyrite form a linear NNE trend, parallel to the main faults. Quartz–sericite is the dominant alteration and is ubiquitous. Zones of potassic alteration can be delineated even though phyllic alteration can be superposed. Much of the system evolved under reducing conditions. Despite uplift along a reverse fault during the Tertiary, and subsequent erosion, the system is preserved at high levels. Supergene processes redistributed copper in secondary oxides and sulfides. These processes were more effective where the deposit is covered by unconsolidated alluvial sediments. The unique history of the San Jorge deposit renders it an important variation of porphyry copper-style mineralization.     

西藏革吉县尕尔穷铜金矿床地质特征及其成因意义

位于西藏阿里地区革吉县的尕尔穷铜金矿床是班公湖-怒江成矿带西段首个达到详查程度的大型铜金矿床。矿区发育三条断裂,其中F1和F2断层呈北东-南西向展布,F3断层为南北向展布。F1断裂产状复杂、延伸大于3000m,破碎带内发育的铜金矿体严格受其控制。目前,矿床主要由斑岩型钼(铜、金)矿体、接触带矽卡岩型铜金矿体、F1断裂破碎带内似IOCG型铁铜金矿体组成。不同矿体特征差别显著,斑岩型矿体主要产于石英闪长岩、花岗斑岩中,金属矿物以网脉状辉钼矿主,次为黄铜矿、磁铁矿、黄铁矿;矿物组合有磁铁矿+黄铁矿、黄铜矿+辉钼矿。矽卡岩型矿体主要产于石英闪长岩、花岗斑岩与碳酸盐岩接触带,呈层状、似层状,金属矿物主要为细脉-网脉状黄铜矿、斑铜矿、辉铜矿、铜蓝、自然铜、自然金、自然银,矿物组合为黄铜矿-磁铁矿-自然金、黄铜矿-斑铜矿-磁铁矿-自然金-银、黄铜矿-赤铁矿-自然金、辉钼矿、黄铜矿-自然金。破碎带内似IOCG型铁铜金矿体产于F1断裂破碎带,呈似层状,金属矿物以细脉-网脉状矿石和角砾状赤铁矿、磁铁矿、黄铜矿、斑铜矿、辉铜矿、铜蓝、自然金为主;矿物组合为黄铜矿-自然金、黄铜矿-斑铜矿-自然金-银矿、赤铁矿-磁铁矿-自然金、黄铜矿-自然金。根据矿床地质特征,综合前人研究资料,本文对矿床的成因进行了进一步探讨,认为尕尔穷铜金矿床是晚白垩世班怒洋关闭后南羌塘-三江复合板片与冈底斯-念青唐古拉板片之间弧-陆碰撞阶段形成的,具有与钾玄岩-高钾钙碱性闪长类岩体、陆-陆同碰撞钾玄岩-高钾钙碱性重熔型花岗斑岩有成因密切联系的构造-岩浆岩"三位一体"的成矿特征,即主矿体赋存于斑岩、矽卡岩、构造破碎带中形成的"斑岩-矽卡岩-似IOCG"型铜金矿床。     

五子骑龙矿床——被改造的斑岩铜矿上部带

五子骑龙矿床产于紫金山矿田的一个早白垩世火山管道旁侧。火山管道中充填的英安斑岩向深部逐渐相变为花岗闪长斑岩。由于后期断裂的破坏，该花岗闪长斑岩及其矿化系统被上冲到与五子骑龙矿床相邻的中寮矿床近地表位置，从而形成斑岩型铜矿床－中寮矿床。五子骑龙矿床中，环绕英安斑岩发育明矾石化、迪开石化、埃洛石化和红柱石化蚀变，这些蚀变是改造并叠加早期绢英岩化蚀变的结果。其铜矿石中的铜蓝、硫砷铜矿和蓝辉铜矿，也经常交     

内蒙古查干诺尔铜矿区矿石特征及成因探讨

查干诺尔铜矿床产在西伯利亚板块和华北板块汇聚带附近,华力西晚期构造岩浆带内。成矿与早二叠世洋盆闭合,后碰撞高钾钙碱性花岗岩类岩浆演化晚期的钾质花岗岩有关。铜矿(化)体呈细脉浸染状产在钾质花岗岩的内外接触带内。铜矿石的主要金属矿物为黄铜矿、黄铁矿、闪锌矿、方铅矿等;化学组分以铜、钼、金、银、铅、锌为主。主要的矿化发生在热液期,围岩蚀变明显,有钾长石化、绢英岩化、高岭土化、青盘岩化等。铜矿形成在华力西晚期,属斑岩型铜矿床。     

巴布亚新几内亚奥克泰迪铜金矿床成矿特征和控制因素

巴布亚新几内亚西部Fubilan山奥克泰迪矿床是一个世界级铜金矿床,在大地构造上位于新几内亚造山带的巴布亚褶皱带。该矿床的铜金矿化赋存于Fubilan二长斑岩及其周边的磁铁矿夕卡岩和硫化物夕卡岩中。矿石类型以原生硫化物矿石为主,金属矿物包括磁铁矿、黄铁矿、磁黄铁矿、白铁矿、黄铜矿、斑铜矿等。蚀变类型包括夕卡岩化、钾化、泥化和青盘岩化。矿床氧化次生富集带发育,表生矿石矿物为蓝辉铜矿、辉铜矿、自然铜、铜蓝和银金矿。成矿作用主要受区域构造、侵入杂岩体、Darai组灰岩地层、断裂等因素的控制。根据矿床的主岩、矿石特征、蚀变特征和控矿因素,认为该矿床成因类型属于较为典型的夕卡岩一斑岩型矿床。     

西藏甲玛铜多金属矿床深部斑岩矿体找矿突破及其意义

甲玛铜多金属矿是西藏冈底斯成矿带中东段勘查程度最高、成矿元素与矿体类型复杂的超大型斑岩-矽卡岩型矿床。通过4年多、近350 个钻孔的验证,不仅实现了矽卡岩矿体的找矿突破,同时在0-40线深部发现了产于二长花岗斑岩与石英闪长玢岩中的斑岩钼（铜）矿体,建立了“四位一体”的找矿勘查模式。斑岩矿体赋存标高一般处于4 600 m以下,矿体走向NW-SE,倾向NE,近直立,矿体垂向延伸大于350 m;斑岩矿石以发育细脉-浸染状、网脉状构造为特征;矿石中的矿石矿物主要为黄铜矿与辉钼矿,少见斑铜矿;脉石矿物主要为石英。初步查明:与铜矿化有关的含矿岩体主要为偏中性的石英闪长玢岩,蚀变以典型的细粒热液黑云母交代角闪石斑晶和基质而成的黑云母化蚀变为主;与钼矿化有关的含矿岩体主要为二长花岗斑岩,蚀变以硅化为主,次为绿帘石化、泥化和钾化。斑岩体与碳酸盐岩接触带常产出厚度超过200 m的巨厚矽卡岩矿体,且在岩体一侧有内矽卡岩产出。甲玛深部斑岩矿体的发现不仅证实了“斑岩-矽卡岩型”的矿床成因观点,而且完善了甲玛矿床成矿模式与勘查模型。     

Rosia Poieni copper deposit,Apuseni Mountains,Romania: advanced argillic overprint of a porphyry system

The Rosia Poieni deposit is the largest porphyry copper deposit in the Apuseni Mountains, Romania. Hydrothermal alteration and mineralization are related to the Middle Miocene emplacement of a subvolcanic body, the Fundoaia microdiorite. Zonation of the alteration associated with the porphyry copper deposit is recognized from the deep and central part of the porphyritic intrusion towards shallower and outer portions. Four alteration types have been distinguished: potassic, phyllic, advanced argillic, and propylitic. Potassic alteration affects mainly the Fundoaia subvolcanic body. The andesitic host rocks are altered only in the immediate contact zone with the Fundoaia intrusion. Mg-biotite and K-feldspar are the main alteration minerals of the potassic assemblage, accompanied by ubiquitous quartz; chlorite, and anhydrite are also present. Magnetite, pyrite, chalcopyrite and minor bornite, are associated with this alteration. Phyllic alteration has overprinted the margin of the potassic zone, and formed peripheral to it. It is characterized by the replacement of almost all early minerals by abundant quartz, phengite, illite, variable amounts of illite-smectite mixed-layer minerals, minor smectite, and kaolinite. Pyrite is abundant and represents the main sulfide in this alteration zone. Advanced argillic alteration affects the upper part of the volcanic structure. The mineral assemblage comprises alunite, kaolinite, dickite, pyrophyllite, diaspore, aluminium-phosphate-sulphate minerals (woodhouseite-svanbergite series), zunyite, minamyite, pyrite, and enargite (luzonite). Alunite forms well-developed crystals. Veins with enargite (luzonite) and pyrite in a gangue of quartz, pyrophyllite and diaspore, are present within and around the subvolcanic intrusion. This alteration type is partially controlled by fractures. A zonal distribution of alteration minerals is observed from the centre of fractures outwards with: (1) vuggy quartz; (2) quartz + alunite; (3) quartz + kaolinite ± alunite and, in the deeper part of the argillic zone, quartz + pyrophyllite + diaspore; (4) illite + illite-smectite mixed-layer minerals ± kaolinite ± alunite, and e) chlorite + albite + epidote. Propylitic alteration is present distal to all other alteration types and consists of chlorite, epidote, albite, and carbonates. Mineral parageneses, mineral stability fields, and alteration mineral geothermometers indicate that the different alteration assemblages are the result of changes in both fluid composition and temperature of the system. The alteration minerals reflect cooling of the hydrothermal system from >400 °C (biotite), to 300–200 °C (chlorite and illite in veinlets) and to lower temperatures of kaolinite, illite-smectite mixed layers, and smectite crystallization. Hydrothermal alteration started with an extensive potassic zone in the central part of the system that passed laterally to the propylitic zone. It was followed by phyllic overprint of the early-altered rocks. Nearly barren advanced argillic alteration subsequently superimposed the upper levels of the porphyry copper alteration zones. The close spatial association between porphyry mineralization and advanced argillic alteration suggests that they are genetically part of the same magmatic-hydrothermal system that includes a porphyry intrusion at depth and an epithermal environment of the advanced argillic type near the surface.Editorial handling: B. Lehmann     

安徽沙溪斑岩型铜金矿床成岩序列及成岩成矿年代学研究

沙溪矿床是长江中下游成矿带中典型的斑岩型铜金矿床,位于庐枞盆地北外缘、郯庐断裂内,矿床成岩成矿时代确定对该矿床成因研究及区域成矿规律的认识具有重要意义。在详细野外地质工作的基础上,采集沙溪矿床与成矿有关的主要岩浆岩样品(粗斑闪长玢岩、黑云母石英闪长玢岩、中斑石英闪长玢岩、细斑石英闪长玢岩和闪长玢岩)和与黄铜矿密切共生的辉钼矿,分别利用Cameca、LA-ICP-MS U-Pb和Re-Os同位素定年方法,获得矿床内主要岩浆岩的成岩年龄(130.60±0.97Ma、129.30±1.00Ma、127.10±1.50Ma、129.46±0.97Ma和126.7±2.1Ma)以及成矿年龄(130.0±1.0Ma),并重新厘定了沙溪岩体从早到晚岩浆的侵位序列。通过区域对比,提出长江中下游存在两阶段斑岩型铜金矿化,沙溪矿床为长江中下游成矿带第二阶段形成的斑岩型矿床,沙溪矿床的成岩成矿作用既不同于庐枞盆地,也不同于断隆区第一阶段的斑岩矿床,而是受郯庐断裂和长江断裂动力学演化联合作用的产物。