吉林延边五凤金矿地质特征及矿床成因

五凤金矿床是位于延边地区的浅成低温热液金矿床。矿脉的产出受不同方向断裂构造控制,主要分布于碱长花岗岩、角闪安山岩等侵入体及地层之中。研究表明,热液金矿化可分为石英--冰长石--方解石阶段,石英--方解石1阶段,石英--方解石2阶段及方解石阶段4个阶段。流体包裹体研究表明,研究区主成矿阶段石英中主要发育气液两相流体包裹体;其均一温度范围为129.8℃~236.5℃,峰值区间为190℃~220℃,盐度w(NaCl)为0.83%~1.98%。成矿流体为低温、低盐度的NaCl--H2O体系热液。氢氧同位素研究结果表明,五凤金矿床成矿流体为岩浆热液与大气降水的混合流体,矿床属浅成低温热液成因类型。     

江苏仑山金矿床流体包裹体、稳定同位素和成矿年代学研究

仑山金矿床位于宁镇矿集区东端。成矿期分为沉积成矿期和热液成矿期,后者可进一步划分为热液Ⅰ阶段和热液Ⅱ阶段。流体包裹体研究表明,热液Ⅰ阶段石英中的气液两相流体包裹体均一温度多集中在330~366℃之间,盐度w(Na Cl_(eq))变化于4.96%~6.74%之间,热液Ⅰ阶段方解石中气液两相流体包裹体均一温度多集中在150~240℃之间,w(Na Cl_(eq))变化于0.71%~9.80%之间,成矿流体为中高温低盐度流体;热液Ⅱ阶段石英、方解石和萤石的流体包裹体均一温度变化于124~260℃,盐度w(Na Cl_(eq))变化于1%~8%之间,成矿流体为中温低盐度流体。氢、氧同位素研究表明,热液Ⅰ阶段成矿流体为岩浆流体,热液Ⅱ阶段成矿流体以大气降水占主导,但仍有少量岩浆流体。硫同位素研究表明,仑山金矿床沉积成矿期硫除来源于三叠系青龙群膏盐层外,有机质也参与了沉积成矿期中金矿的形成。热液Ⅰ阶段硫来源于沉积成岩阶段黄铁矿的活化迁移和富集,岩浆硫也提供了成矿物质。萤石Sm-Nd测年分析表明,仑山金矿床热液Ⅱ阶段成矿年龄为(93.7±3.1)Ma,推断主成矿阶段形成于晚白垩世。仑山金矿床的形成代表着长江中下游成矿带最晚期的成矿作用。     

黔西南卡林型金矿床与区域古油藏的关系:来自流体包裹体气相组成和沥青拉曼光谱特征的证据

黔西南地区是世界第二大卡林型金矿床集中区,同时也发育有大量古油藏,二者空间关系密切,但是否具有成因联系目前尚不清楚且存在较大争议。本文报道该区典型金矿床与成矿有关的热液矿物中流体包裹体的气相组成和高品位金矿石中沥青的激光拉曼光谱分析结果,以探讨含有机质流体与金成矿作用之间的关系。研究表明,虽然含砷富金黄铁矿、石英、方解石、萤石和雄黄等热液矿物形成于不同的成矿阶段,但其中流体包裹体的有机气相组分种类、含量及相对比例整体较为一致,表明成矿流体中的有机络离子团在成矿作用过程中没有发生明显的分解或重组,进而说明黔西南卡林型金矿成矿作用过程中有机质并未以有机络离子团的形式对金进行有效搬运或其搬运金的能力非常有限。在N2/Ar-CO2/CH4流体来源判别图解中,各蚀变矿物中的流体包裹体气相组成主要落在循环的大气降水区域,经大气水区域向岩浆流体区域延伸,整体上构成一条非常好的线性分布趋势,暗示成矿流体可能起源于深部岩浆但在演化过程中有大量循环大气水的加入。水银洞金矿床的1件石英样品偏离上述趋势线并向有机流体方向偏移,可能反映了流体迁移过程中有机质的加入。该区金矿床的矿石中均不同程度地发育浸染状沥青,不同矿床中沥青的激光拉曼光谱特征基本一致,说明该区金矿床中的沥青具有相同成因。根据沥青激光拉曼光谱特征地质温度计反演计算的成矿早阶段流体温度为317~336℃,明显高于区域古地温温度(160~250℃)以及区域古油藏的流体包裹体均一温度(73~175℃),说明该区卡林型金矿床的成矿热源与区域古地温无关。对区域地质及近年来地球物理与地球化学最新成果的综合分析表明,该区卡林型金矿床可能是叠加在区域古地温场之上的深部岩浆活动远端低温热液成矿作用的产物,与金矿床空间关系密切的有机质可能为来自先存古油藏并沿控矿构造发生逃逸的油气物质裂解产物,金成矿与区域古油藏之间不存在成因联系。     

新疆伊宁县塔吾尔别克金矿床流体包裹体特征研究及矿床成因

塔吾尔别克金矿床是西天山吐拉苏断陷盆地中一个重要的金矿床。矿体主要赋存于早石炭世二长斑岩及大哈拉军组第五岩性段安山岩、蚀变凝灰岩中,受断裂构造控制,矿床围岩蚀变作用普遍而强烈。矿石金属矿物主要为黄铁矿、自然金、赤铁矿和黄铜矿等,非金属矿物主要为石英、斜长石、方解石等。成矿过程大致划分为3个成矿阶段:1石英-黄铁矿阶段;2石英-硫化物脉阶段;3石英-碳酸盐阶段。石英及方解石中流体包裹体类型简单,主要为气液两相水包裹体和纯液相水包裹体。包裹体测试均一温度为100~196℃,流体盐度为0.0%~7.3%(质量分数,NaCl_(eq)),流体密度为0.9~1.0 g/cm~3,计算出成矿压力为5.2~81.9 MPa,对应成矿深度为0.5~7.4 km。塔吾尔别克金矿床成矿流体包裹体显示低温度、低盐度和较低密度的流体特征,表明成矿压力小和深度较浅。结合矿床地质特征、流体包裹体特征及前人研究成果,初步认为该矿床为浅成低温热液型金矿床。     

辽宁北票二道沟金矿床地球化学特征及意义

针对金矿床的矿石和岩石稀土元素、矿物的微量元素、金矿物成色、硫同位素和石英包裹体测温等方面阐述了二道沟金矿床的地球化学特征,对其成矿物质来源及矿床成因进行了探讨.二道沟金矿床岩石和金矿石具有轻稀土富集、重稀土亏损、稀土元素分布模式总体呈向右倾斜的特征.金矿石稀土模式曲线与早白垩世岩石稀土模式曲线近似,表明金矿成矿与早白垩世岩浆活动密切相关,同时稀土元素参数也反映出成岩成矿物源的一致性.黄铁矿具有含As高及As/Sb和Co/Ni比值高的特点.金矿物成色为630~948,多数金矿物成色值大于800;δ³⁴S值大多数在-2‰~+3‰之间,变化区向狭窄,显示出岩浆成因的热液硫化物之特征.石英包裹体成矿温度为210~322℃.研究表明,二道沟金矿床金矿石和岩石是地幔岩浆同熔地壳经分异作用而形成,成岩成矿系同源演化系列的产物,成矿物质来源具有上地幔或下地壳的特征,反映该金矿床是中深成中温岩浆热液金矿床.     

安徽东溪浅成低温热液型金矿床成矿流体特征和形成时代——流体包裹体和赋矿安山岩U-Pb年代学约束

安徽东溪金矿床位于桐柏-大别造山带北淮阳构造带的中生代晓天火山盆地中,是桐柏-大别成矿带具有代表性的浅成低温热液金矿床。金矿体以含金方解石脉和方解石-石英脉形式产出,受NW向断裂控制,赋矿围岩为毛坦厂组安山质火山岩。该矿床热液成矿过程由早到晚可分为粗晶方解石阶段和方解石-石英阶段。早、晚阶段方解石中流体包裹体十分发育,主要类型有纯液相、纯气相和富液二相流体包裹体。早阶段流体包裹体均一温度范围为128~172℃,冰点温度介于-0.7~+23.4℃之间,盐度为0.35%~0.92%;晚阶段流体包裹体均一温度范围为105~160℃,冰点温度介于-0.5~+9.1℃之间,盐度为0.18%~0.52%。成矿流体从早阶段演化到晚阶段,温度和盐度具有小幅度的降低趋势。岩浆热液和加热循环的大气降水的混合可能是引起金属元素富集、沉淀的主要机制,该矿床是地表浅部热液对流系统的产物。LA-ICP-MS锆石U-Pb同位素研究表明,赋矿安山岩的锆石~(206)Pb/~(238)U加权平均年龄为126.7±1.4Ma(1σ,MSWD=0.95),代表了其火山作用时限。结合矿床地质特征认为,东溪金矿床成矿时间可能与安山岩喷发时限基本一致。该矿床形成于早白垩世陆壳强烈伸展和岩石圈地幔上涌的动力学背景。     

黔西南灰家堡金矿田成矿流体来源及演化:流体包裹体和稳定同位素证据

为厘清滇黔桂地区卡林型金矿床成矿流体的特征,本文以灰家堡金矿田为代表,对太平洞、紫木凼、水银洞和簸箕田4个典型矿床中热液矿物的流体包裹体进行了系统研究,并对热液矿物进行了碳、氢、氧、硫同位素的分析测试。结果表明,灰家堡金矿田流体包裹体类型丰富,包括NaCl-H2O溶液包裹体、CO2包裹体、CO2-H2O包裹体、烃-H2O包裹体和烃类包裹体五大类。从成矿早阶段到晚阶段,成矿流体组分大致经历了从H2O+NaCl→H2O+NaCl+CO2+CH4±N2→H2O+NaCl±CH4±CO2的演化,均一温度和盐度略有降低。流体包裹体及稳定同位素组成特征显示,成矿流体属于富含金属和碳氢化合物的盆地流体;沉积黄铁矿的硫主要来源于封闭海洋盆地中硫酸盐的细菌还原硫;热液硫化物与沉积黄铁矿的硫同位素特征相似,表明成矿流体中的硫来源于成岩黄铁矿的溶解作用,同时有机质热分解和硫酸盐有机质热还原作用亦提供了部分硫。成矿主阶段发生的H2O-NaCl-CO2流体不混溶作用是导致Au沉淀富集的重要机制。     

安徽池州地区金鸡山金矿床成矿流体特征

金鸡山金矿是安徽池州地区近年新发现的一个独立金矿床,成因上属于富硫化物石英脉型.采自主成矿阶段石英中的原生流体包裹体显微测温和激光拉曼光谱分析表明,主成矿阶段的温度峰值为280～320℃,成矿流体盐度为2.81%～10.11%NaCl,密度为0.61～0.96 g/cm3,是一种中温、低盐度、低密度的NaCl-H2O-CO2体系,具有中温热液金矿床的成矿流体特征.矿床形成于中浅成环境(成矿深度0.96～3.17 km);成矿流体的不混溶及流体中CO2和CH4等有机质对矿质的活化、运移及沉淀均起到了重要作用.     

西藏甲玛铜多金属矿床成因研究——来自流体包裹体的证据

甲玛铜多金属矿床位于西藏冈底斯斑岩铜矿带东段,是近年来勘探发现的超大型斑岩-矽卡岩型铜多金属矿床。通过冷热台显微观察与测温、扫描电镜、激光拉曼探针测试,对甲玛矿床各成矿阶段典型矿物的流体包裹体研究表明,成矿流体富含挥发分,临界相均一的流体来自岩浆超临界流体出溶,主成矿阶段具有沸腾包裹体组合特征,有机质包裹体荧光效应显著。显微测温结果显示,岩浆-热液阶段斑岩中石英斑晶的流体包裹体均一温度范围为250～540℃,含石盐子晶高盐度包裹体盐度范围为35～61(wt%)NaCl.eq,中等盐度的临界均一的气液包裹体盐度范围为3～29(wt%)NaCl.eq,岩浆期后热液阶段斑岩、角岩中石英脉的流体包裹体均一温度范围为210～410℃,盐度范围为33～41(wt%)NaCl.eq,与其不混溶共生的中低盐度气液两相流体包裹体盐度范围为5～25(wt%)NaCl.eq。矽卡岩阶段矿物均一温度范围为130～360℃,盐度范围为3～41(wt%)NaCl.eq,从岩浆热液过渡阶段到石英-硫化物阶段均一温度与盐度呈阶梯式降低趋势。斑岩体石英的流体包裹体中含有较多黄铜矿子矿物,岩浆结晶分异过程中已经具成矿元素的富集。激光拉曼探针测试结果显示,成矿早期至主成矿期矿物流体包裹体气相成分主要为CO2、CH4和N2,各阶段矿物流体包裹体气相成分具有继承性。成矿流体为高温度高盐度,富含CO2、CH4的流体。成矿流体主要源于岩浆,后期混有大气降水。当岩浆热液上升时因压力的突然释放造成高温含矿热流体发生减压沸腾,CO2和CH4等气体大量逃逸,导致成矿物质快速沉淀。矿床在成因上与岩浆-热液成矿作用密切相关。     

球粒状铁绿纤石（?）的形貌结构特征与成因

球粒状铁绿纤石(?)产出于云南昭通玄武岩晶洞中,与其共生的矿物有绿帘石、硅铁灰石、水晶、葡萄石及方解石等矿物.扫描电镜(SEM)下,该矿物呈扁平长柱状,沿柱体方向呈不同程度的弯曲,并绕球粒中的包裹体聚合生长成不同形状的球粒,聚合生长的方式取决于包裹体在球体中的位置与距离,越近球粒表面,越趋于平行排列.水晶的流体包裹体测温及拉曼光谱分析表明,铁绿纤石(?)属低温(148～169℃)热液产物,热液的盐度为 11%～12%,富含H2O及微量CH4,铁绿纤石(?)的形成可能与有机质(CH4)有关.     

Hydrocarbon- and ore-bearing basinal fluids: a possible link between gold mineralization and hydrocarbon accumulation in the Youjiang basin,South China

The Youjiang basin, which flanks the southwest edge of the Yangtze craton in South China, contains many Carlin-type gold deposits and abundant paleo-oil reservoirs. The gold deposits and paleo-oil reservoirs are restricted to the same tectonic units, commonly at the basinal margins and within the intrabasinal isolated platforms and/or bioherms. The gold deposits are hosted by Permian to Triassic carbonate and siliciclastic rocks that typically contain high contents of organic carbon. Paragenetic relationships indicate that most of the deposits exhibit an early stage of barren quartz ± pyrite (stage I), a main stage of auriferous quartz + arsenian pyrite + arsenopyrite + marcasite (stage II), and a late stage of quartz + calcite + realgar ± orpiment ± native arsenic ± stibnite ± cinnabar ± dolomite (stage III). Bitumen in the gold deposits is commonly present as a migrated hydrocarbon product in mineralized host rocks, particularly close to high grade ores, but is absent in barren sedimentary rocks. Bitumen dispersed in the mineralized rocks is closely associated and/or intergrown with the main stage jasperoidal quartz, arsenian pyrite, and arsenopyrite. Bitumen occurring in hydrothermal veins and veinlets is paragenetically associated with stages II and III mineral assemblages. These observations suggest an intimate relationship between bitumen precipitation and gold mineralization. In the paleo-petroleum reservoirs that typically occur in Permian reef limestones, bitumen is most commonly observed in open spaces, either alone or associated with calcite. Where bitumen occurs with calcite, it is typically concentrated along pore/vein centers as well as along the wall of pores and fractures, indicating approximately coeval precipitation. In the gold deposits, aqueous fluid inclusions are dominant in the early stage barren quartz veins (stage I), with a homogenization temperature range typically of 230°C to 270°C and a salinity range of 2.6 to 7.2 wt% NaCl eq. Fluid inclusions in the main and late-stage quartz and calcite are dominated by aqueous inclusions as well as hydrocarbon- and CO₂-rich inclusions. The presence of abundant hydrocarbon fluid inclusions in the gold deposits provides evidence that at least during main periods of the hydrothermal activity responsible for gold mineralization, the ore fluids consisted of an aqueous solution and an immiscible hydrocarbon phase. Aqueous inclusions in the main stage quartz associated with gold mineralization (stage II) typically have a homogenization temperature range of 200–230°C and a modal salinity around 5.3 wt% NaCl eq. Homogenization temperatures and salinities of aqueous inclusions in the late-stage drusy quartz and calcite (stage III) typically range from 120°C to 160°C and from 2.0 to 5.6 wt% NaCl eq., respectively. In the paleo-oil reservoirs, aqueous fluid inclusions with an average homogenization temperature of 80°C are dominant in early diagenetic calcite. Fluid inclusions in late diagenetic pore- and fissure-filling calcite associated with bitumen are dominated by liquid C₂H₆, vapor CH₄, CH₄–H₂O, and aqueous inclusions, with a typical homogenization temperature range of 90°C to 180°C and a salinity range of 2–8 wt% NaCl eq. It is suggested that the hydrocarbons may have been trapped at relatively low temperatures, while the formation of gold deposits could have occurred under a wider and higher range of temperatures. The timing of gold mineralization in the Youjiang basin is still in dispute and a wide range of ages has been reported for individual deposits. Among the limited isotopic data, the Rb–Sr date of 206 ± 12 Ma for Au-bearing hydrothermal sericite at Jinya as well as the Re–Os date of 193 ± 13 Ma on auriferous arsenian pyrite and ⁴⁰Ar/³⁹Ar date of 194.6 ± 2 Ma on vein-filling sericite at Lannigou may provide the most reliable age constraints on gold mineralization. This age range is comparable with the estimated petroleum charging age range of 238–185 Ma and the Sm–Nd date of 182 ± 21 Ma for the pore- and fissure-filling calcite associated with bitumen at the Shitouzhai paleo-oil reservoir, corresponding to the late Indosinian to early Yanshanian orogenies in South China. The close association of Carlin-type gold deposits and paleo-oil reservoirs, the paragenetic coexistence of bitumens with ore-stage minerals, the presence of abundant hydrocarbons in the ore fluids, and the temporal coincidence of gold mineralization and hydrocarbon accumulation all support a coeval model in which the gold originated, migrated, and precipitated along with the hydrocarbons in an immiscible, gold- and hydrocarbon-bearing, basinal fluid system.     

构造驱动大巴山前陆烃类流体排泄:含烃包裹体纤维状方解石脉证据

含烃包裹体纤维状方解石脉被认为是超高压下油气流体形成和排泄的标志。大巴山前陆构造带一些断裂和下古生界黑色泥岩和泥灰岩烃源岩微裂隙中分布有含烃包裹体纤维状方解石脉,成分分析表明其为低镁方解石。纤维状方解石脉δ13CVPDB和δ18OVPDB比围岩碳酸盐岩的明显变轻,前者δ13CVPDB和δ18OVPDB变化范围分别为-1.9%～-4.8‰和-8.4%～-12.8‰,后者分别为-1.7%～+3.1‰和-8.7%～-4.5‰,且δ13C与δ18O具有明显的线性关系,反映出纤维状方解石脉具有成岩有机流体与浅部流体混合的流体特征。纤维状方解石脉含有共生的固体沥青包裹体、含甲烷液相包裹体和气液二相盐水包裹体等多相态包裹体,其中沥青包裹体为油气运移的残余沥青。气液二相盐水包裹体均一温度主要位于140℃和196℃之间（峰值为179℃）,盐度较高（平均为9.7wt% NaCl）。分别应用盐水包裹体和甲烷包裹体等溶线P-T相图确定出含烃包裹体纤维状方解石脉形成的流体压力为150~200 MPa,属于异常超高压流体。地质和地球化学特征分析认为,大巴山含烃包裹体纤维状方解石脉不具有泥岩因压实成岩作用而形成的超高压流体特征。结合沉积和构造演化历史分析认为,印支碰撞造山运动和燕山前陆构造作用导致大巴山褶皱隆起并伴随天然气藏破坏和改造,挤压环境下的超高压构造应力驱动天然气流体排泄,大巴山前陆构造带含烃包裹体纤维状方解石脉就是超高压构造应力驱动天然气排泄的产物。     

黔西南灰家堡金矿田有机岩相学和地球化学

灰家堡金矿田是黔西南卡林型金矿床的集中产地之一,对其中的水银洞、紫木凼、太平洞和簸箕田4个代表性金矿床进行了有机岩相学和地球化学研究。灰家堡金矿田的矿床中固体沥青主要产于矿石内,与矿化关系密切,产出形态受孔隙、构造裂隙控制;沥青与热液期矿物的共生组合关系表明其形成时间与成矿时间大致一致。矿石中普遍发育有机质包裹体。有机地球化学特征表明,金矿石和围岩中的有机质成熟度均较高,经历了类似的地质作用过程;有机质形成于强还原、中低盐度的沉积环境;有机质来源以海相菌藻类等低等生物为主,有少量陆源高等植物的输入。     

新疆萨热克砂砾岩型铜矿床富烃类还原性盆地流体特征

新疆萨热克大型砂砾岩型铜矿床含矿地层为上侏罗统库孜贡苏组,与下伏下-中侏罗统煤矿形成"同盆共存"现象。在萨热克铜矿床的铜矿体内,构造裂隙中含较多沥青(有机碳含量达0.11%~2.55%),并与辉铜矿等铜硫化物共生。铜矿石中次生石英、方解石和白云石等胶结矿物包裹体含烃盐水类、含烃盐水-液烃共生类、含烃盐水-气烃共生类、轻质油类等四类富烃类盆地流体的包裹体。研究认为铜矿石中的有机质主要来源于下伏烃源岩煤层,当盆地深部富含有机质的还原性流体沿NE向构造裂隙上侵到渗透率较高的上侏罗统库孜贡苏组上段(J3kz2)砂砾岩层时,该层上部的下白垩统克孜勒苏群下段(K1kz1)褐红色粉砂质泥岩,与下部的上侏罗统库孜贡苏组下段(J3kz1)灰绿色粉砂质泥岩形成封闭的隔水层,还原性流体沿砂砾岩层发生水平渗滤扩散,与盆地中封存的地层水淋滤含铜赤铁矿质砾岩类后形成的含铜氧化相流体混合时,造成了辉铜矿的大量沉淀和碳酸盐等矿物的结晶析出,并沿砾石间隙充填分布。     

根据储层沥青和流体包裹体综合判识油气成藏期:以黄骅坳陷北大港古生界潜山为例

渤海湾盆地潜山油气资源较丰富,近期黄骅坳陷古生界潜山油气勘探取得重大进展,但油气藏的形成时期及期次尚不明确.以黄骅坳陷北大港古生界潜山为例,综合利用储层沥青、流体包裹体观察、测温、拉曼光谱及红外光谱分析等地球化学分析手段,结合烃源岩生烃史,对其油气成藏期进行了系统研究.结果表明:研究区古生界发育碳质、胶质-沥青质、油质3种沥青,经历了生物降解和氧化作用等多种次生改造过程,结合研究区的构造演化及生烃史,推测早侏罗世中期之前存在油气充注;古生界潜山发育两期烃类包裹体,第一期包裹体发黄褐色荧光,主要分布于石英颗粒表面及方解石脉内,均一温度峰值区间为75~80℃,第二期包裹体包括黄色、蓝绿色荧光两类,分布在石英颗粒内裂缝、穿石英颗粒裂缝及方解石脉内,均一温度峰值范围分别为85~90℃和95~100℃;综合古生界潜山储层沥青及包裹体特征,结合烃源岩生烃史,确定古生界存在两期油气充注,分别为中三叠世（235~223 Ma）和新近纪-第四纪（22~0 Ma）,且以晚期成藏为主.      

Metallogeny of the Lannigou Sedimentary Rock-hosted Disseminated Gold Deposit in Southwestern Guizhou Province, China

The Lannigou deposit is a large-sized sedimentary rock-hosted disseminated gold （SRHDG） deposit located in the Youjiang Basin. It is hosted by the Middle Triassic turbidite. Wall rock alterations, including silicification, pyritization, arsenopyritization, carbonatization and argillization, commonly occur along fractures. PGE study demonstrates that either Permian basalts or Triassic ultrabasic intrnsives are unlikely to be the main source of gold mineralization. Coupled with the lack of other nmgmatic activity in the vicinity of the mining area, an amagmatic origin is proposed. Organic matter compositions and GC-MS analysis of the ores and host rocks show that the organics in the ores and the host rocks have a common source; the organic matter in the ores was mainly indigenous. The positive correlation between S2 and Au contents, along with the common occurrence of organic inclusions, suggest involvement of organic matter in the ore-forming process in terms of promoting Au leaching from the source rocks, making colloidal Au migration possible, as well as hydrocarbon reduction of sulphate. Geological and geochemical characteristics of the Lannigou deposit suggest that it was formed through circulation of meteoric water and probably less importantly organic bearing formation water driven by high geothermal gradient caused by late Yanshanian extension, which leached Au from the source bed, and then migrated as Au-bisnlfides and colloidal Au, culminating in deposition by reduction-adsorption and surface complexation of gold onto the growth surface of arsenlan pyrite.     

河南银洞坡金矿成矿流体与矿床成因研究

银洞坡金矿位于桐柏县围山城金银矿带的中部,为一超大型金矿床,伴生银、铅锌。对金矿石中主要成矿阶段流体包裹体进行了详细的岩相学、显微测温及激光拉曼光谱成分研究,结果表明：金矿石中发育气液两相包裹体、富气相包裹体和含CO2三相包裹体,流体成分为H2O NaCl CO2体系,含少量N2、CH4、H2S和H2。流体不混溶是导致矿质沉淀的主要因素。3类包裹体的均一温度为1692～3992 ℃,流体盐度为18%～122%,其中含CO2三相包裹体的盐度明显小于气液两相包裹体的盐度。利用不混溶体系估算得到包裹体的捕获压力为62～1263 MPa,成矿深度为52 km左右。矿石中黄铁矿的δ34S为16‰~33‰,围岩中纹层状黄铁矿的δ34S为33‰～62‰,矿石中的δ34S小于围岩中δ34S值,表明成矿物质中的硫可能来源于地幔硫和围岩硫的混合。     

小秦岭金矿流体包裹体挥发组分与金的矿化

小秦岭石英脉型金矿矿物包裹体中挥发组分以Ｈ２Ｏ和ＣＯ２为主，还有少量的ＣＨ４、ＣＯ、Ｈ２、Ｈ２Ｓ等。富金矿石中包裹体的ＣＯ２＞３０ｍｏｌ％．ＣＯ２／Ｈ２Ｏ＞０．４，而贫金矿石中包裹体的ＣＯ２＜２０ｍｏｌ％，ＣＯ２／Ｈ２Ｏ＜０．２。前者包裹体的气体成分中含有较多的ＣＨ４、ＣＯ和Ｈ２等还原性气体．表明这种金矿的成矿流体以富含ＣＯ２为特征，ＣＯ２含量的变化对金的富集起着重要作用．因此金矿石中矿物包裹体的ＣＯ２含量或ＣＯ２／Ｈ２Ｏ比值可以作为深部预测的主要判据之一，并应用于小秦岭金矿山已取得良好的效果。     

Geological and Geochemical Characteristics of Gold Mineralization in the Salu Bulo Prospect,Sulawesi, Indonesia

The Salu Bulo prospect is one of the gold prospects in the Awak Mas project in the central part of the western province, Sulawesi, Indonesia. The gold mineralization is hosted by the meta‐sedimentary rocks intercalated with the meta‐volcanic and volcaniclastic rocks of the Latimojong Metamorphic Complex. The ores are approximately three meters thick, consisting of veins, stockwork, and breccias. The veins can be classified into three stages, namely, early, main, and late stages, and gold mineralization is related to the main stage. The mineral assemblage of the matrix of breccia and the veins are both composed of quartz, carbonate (mainly ankerite), and albite. High‐grade gold ores in the Salu Bulo prospect are accompanied by intense alteration, such as carbonatization, albitization, silicification, and sulfidation along the main stage veins and breccia. Alteration mineral assemblage includes ankerite ± calcite, quartz, albite, and pyrite along with minor sericite. Pyrite is the most abundant sulfide mineral that is spatially related to native gold and electrum (<2–42 μm in size). It is more abundant as dissemination in the altered host rocks than those in veins. This suggests that water–rock interaction played a role to precipitate pyrite and Au in the Salu Bulo prospect. The Au contents of intensely altered host rocks and ores have positive correlations with Ag, Ni, Mo, and Na. Fluid inclusions in the veins of the main stage and the matrix of breccia are mainly two‐phase liquid‐rich inclusions with minor two‐phase, vapor‐rich, and single‐phase liquid or vapor inclusions. CO₂ and N₂ gases are detected in the fluid inclusions by Laser Raman microspectrometry. Fluid boiling probably occurred when the fluid was trapped at approximately 120–190 m below the paleo water table. δ¹⁸O_SMOW values of fluid, +5.8 and +7.6‰, calculated from δ¹⁸O_SMOW of quartz from the main stage vein indicate oxygen isotopic exchange with wall rocks during deep circulation. δ³⁴S_CDT of pyrite narrowly ranges from ?2.0 to +3.4‰, suggesting a single source of sulfur. Gold mineralization in the Salu Bulo prospect occurred in an epithermal condition, after the metamorphism of the host rocks. It formed at a relatively shallow depth from fluids with low to moderate salinity (3.0–8.5 wt% NaCl equiv.). The temperature and pressure of ore formation range from 190 to 210°C and 1.2 to 1.9 MPa, respectively.     

滇黔交界地区玄武岩铜矿流体包裹体地球化学特征

为了探讨玄武岩铜矿成矿流体的特征,对滇黔交界地区峨眉山玄武岩铜矿3个成矿期次铜矿石中石英和方解石的气液包裹体进行了激光拉曼成分研究和均一温度、盐度测定,对古石油包裹体通过荧光显微镜进行了成分鉴定。结果表明：第1、2期次成矿流体主要为盆地卤水,其气液包裹体气液比小（一般5%～10%）,w（NaCl）为8%～22%,气相为甲烷,液相为水,无子晶及液相CO2,均一温度为80℃～260℃;第2期次成矿流体除盆地卤水外,还有以古石油为代表的有机流体,古石油包裹体由液态烃、固体沥青和气相组成,均一温度变化大（30℃～290℃）,液态烃以荧光性强的芳烃为主;第3期次成矿流体具有大气降水成因,其气液包裹体气液比一般为5%～10%,w（NaCl）〈4%,无子晶及液相CO2,均一温度140℃～270℃,但以小于200℃为主。从第1期次到第3期次,成矿流体盐度逐渐降低,特别是第3期次的盐度非常低,但温度变化不明显。本区最重要的自然铜沉淀富集成矿是第2期次不同性质成矿流体混合或成矿流体与有机流体混合、有机质的还原的结果。