云南墨江金厂金矿床黄铁矿标型特征研究

黄铁矿在云南墨江金厂金矿床中广泛出现于蛇纹岩、黄铁铬绢英岩、硅质岩和石英脉中。通过对与黄铁矿成因产状密切关联的热液演化阶段的划分、黄铁矿的晶形统计、黄铁矿的热电性研究、黄铁矿的电子探针分析、黄铁矿所赋存的含金岩矿石标本中金品位化学分析，确定了与成矿物质来源——金厂蛇纹岩化镁质超基性岩、硅质岩和可能隐伏的酸性侵入岩有关的系列成因标型。在对黄铁矿热电标型的均方差参数的自然对数值(lnMp)与金品位自然对数值(lnTg)的相关性研究基础上，提出当lnMp值接近4．1时，金的品位值接近二业开采标准。金厂金矿体与镍矿体尽管空间上分离，但近镍矿体与富金石英脉中黄铁矿的共生元素组成成分表明金、镍矿体中部分矿质具有同源同期的特征。此外，全厂组硅质岩和可能的隐伏岩体在成矿物源和热源方面的贡献不容忽视。     

桂东北苗儿山中段向阳坪铀矿床钻孔岩心高光谱特征分析

热液蚀变是向阳坪花岗岩型铀矿床的重要找矿标志。利用ASD光谱仪对向阳坪矿床两个含矿钻孔进行岩心高光谱测量,基于光谱分析和光谱匹配技术提取了高岭石、蒙脱石、富铝绢云母、贫铝绢云母、赤铁矿、绿泥石+绢云母、碳酸盐等7类蚀变矿物信息。高光谱岩心编录与钻孔岩性、构造、矿化的综合分析结果表明:豆乍山和香草坪岩体对热液蚀变类型及发育程度的影响均不大,铀矿化和相关的热液蚀变发育主要受断裂构造控制,绿泥石+绢云母、蒙脱石、贫铝绢云母形成于矿前期,赤铁矿、富铝绢云母、高岭石及碳酸盐形成于成矿期—成矿晚期,构造带中的赤铁矿+富铝绢云母+高岭石可作为向阳坪地区铀矿化标型矿物组合。     

黑龙江金厂金矿床18号矿体围岩蚀变及短波红外光谱特征

金厂金矿18号矿体围岩蚀变发育顺序从早到晚为:钾化、硅化、绿泥石化、绢云母化、碳酸盐化、高蛉土化,从内往外依次发育青磐岩化带、绢英岩化带和钾化带.矿化出现在泥化和绢英岩化叠加处,以及泥化和青磐岩化叠加处.通过短波红外光谱测试技术,识别出本矿区有26种蚀交矿物,其中白云母含量与金矿体呈正相关,说明绢云母化与金矿化关系密切;青磐岩化带蚀变矿物组合为绿泥石+绿帘石+伊利石±埃洛石±蒙脱石±石英;钾化带蚀变矿物组合为钾长石+高岭石+埃洛石±蒙脱石±石英;绢英岩化带蚀变矿物组合为绢云母+埃洛石±蒙脱石±高岭石±石英.     

云南墨江含金脆—韧剪切构造带中显微构造的矿物地球化学研究

墨江－元江镍金矿床是哀牢山构造－成矿带上一个十分典型和重要的矿床，在野外实测构造岩石地层层序、矿物学详细填图的基础上，采用X射线粉晶衍射分析、扫描电镜、电子探针微区分析及矿物－构造－地球化学等方法，对墨江镍金矿床中含金脆－韧性剪切构造带的物质组成进行详细研究。显微构造的矿物地球化学研究是一种构造筛分新方法。脆性构造主要表现为含镍金石英脉－硅质岩－黄铁矿硅质岩中普遍发育碎裂岩化及裂隙，碎裂岩化－裂隙构造是深源热流体叠加成矿的储矿构造和运移上升通道，脆性剪切变形过程中伴有粘土化蚀变，粘土矿物主要有铬水云母、铬高岭石、多水铬高岭石、绿铬高岭石、铬蒙脱石、铬迪开石、铬埃洛石和绿鳞石等。在含金脆－韧剪切构造带中，铬绢云母－铬水云母－铬伊利石系列和铬绿泥石的矿物具（脆）韧剪切变形特征，在韧剪切变形过程中伴有强烈的热流体以及H2O为主要组分的矿化剂作用。     

湘西震旦—寒武系页岩中粘土矿物和层状变质矿物的研究

湘西震旦—寒武系页岩与沉积改造型铀矿床有关。页岩中的粘土矿物主要为水云母,次为高岭石、多水高岭石、蒙脱石,少量水铝英石。层状变质矿物为绢云母、绿泥石、斜绿泥石、滑石。采用多种方法对这些矿物作了分析,认为水云母是赋铀的重要载体矿物。     

基于红外光谱技术的内蒙古达斯矿区蚀变地质填图及其勘查指示意义

红外光谱技术,辅以显微镜下鉴定和矿物地球化学分析,通过系统采集达斯矿区地表岩石与钻孔岩芯样品,开展精细蚀变矿物填图,利用绢云母矿物Al- OH基团在2200 nm附近的光谱变化特征,开展勘查区及其外围的找矿预测。结果显示：① 研究区主要矿物为钠长石、微斜长石、石英、绢云母、高岭石、蒙脱石和绿泥石,另含有少量明矾石、电气石、石膏和黑云母等;② 电气石、明矾石、高岭石和绢云母矿物及其组合与成矿关系密切,具有中硫化浅成低温热液型矿床蚀变矿物组合特征;③ 目前已发现的Pb矿（化）体,主要产于300 m以浅,矿体底板为一套蒙脱石+绿泥石为主的蚀变矿物组合。矿体赋存于绢云母（高岭石+少量明矾石+电气石）蚀变带内,蚀变分带特征（矿化体中心向外）表现为：绢云母化→绢云母+高岭石（+少量明矾石+电气石）→绢云母+蒙脱石→蒙脱石+绿泥石;④ 区内长波绢云母指示了深部热源的位置,短波绢云母反映出热液流体与浅部大气降水的混合作用,根据绢云母矿物Al- OH波长插值填图及矿物组合特征变化确定了成矿流体pH值偏中性、温度逐渐降低的变化趋势;⑤ 绢云母矿物在2200 nm附近的光谱吸收深度与Pb品位之间呈正相关关系,10%吸收深度阈值可区分具有相似Al- OH吸收特征的绢云母和高岭石矿物;⑥ 结合GIS空间叠加分析,认为勘查区外围仍具一定找矿潜力。     

砂宝斯金矿区多矿物脉特征及其对砂岩的改造

砂宝斯矿区的成矿围岩为长石石英砂岩，砂岩被多期次的石英脉、方解石脉和高岭石脉所穿切，这些多矿物脉是热液流体运移的结果。矿物脉形成过程中对围岩进行了热改造，使砂岩发生了压溶作用、胶结作用和溶蚀作用，形成了蚀变砂岩。由于流体酸碱性和温压的变化，孔隙水介质的性质由酸性向碱性转变，在酸性成岩环境下形成的蚀变高岭石、伊利石将转变成绿泥石、绢云母等。绢云母的大量出现，石英次生加大和自生粘土矿物的形成均是热液流体活动的产物。     

高硫-低硫化浅成低温热液矿床的短波红外矿物分布特征及找矿模型——以西藏铁格隆南(荣那矿段)、斯弄多矿床为例

本文以铁格隆南(荣那矿段)高硫化浅成低温热液矿床和斯弄多低硫化浅成低温热液矿床为研究对象,运用短波红外技术快速厘定了上述两个矿床的蚀变矿物类型及组合特征,构建了基于短波红外勘查技术的找矿模型。研究发现:铁格隆南矿床(荣那矿段)的蚀变矿物垂向分带组合为:高岭石→高岭石+(地开石+明矾石)→高岭石+明矾石+(地开石)→高岭石+地开石+明矾石。由于高硫化浅成低温热液交代黄铁绢英岩化带的斑岩型矿体,致使上部矿石中还有少量交代残余的绢云母;斯弄多低硫化浅成低温热液矿床的蚀变矿物垂向分布为:白(绢)云母+(钠云母)→白(绢)云母+钠云母+(伊利石)→白(绢)云母+钠云母+蒙脱石+伊利石→白(绢)云母+钠白云母+蒙脱石+伊利石,其中顶部白(绢)云母是后期黑云母花岗斑岩蚀变所产生,本身与成矿无关;矿体主要赋存在伊利石+蒙脱石带,随着蒙脱石被伊利石化,矿体也逐渐尖灭。     

高硫-低硫化浅成低温热液矿床的短波红外矿物分布特征及找矿模型

本文以铁格隆南(荣那矿段)高硫化浅成低温热液矿床和斯弄多低硫化浅成低温热液矿床为研究对象, 运用短波红外技术快速厘定了上述两个矿床的蚀变矿物类型及组合特征, 构建了基于短波红外勘查技术的找矿模型。研究发现: 铁格隆南矿床(荣那矿段)的蚀变矿物垂向分带组合为: 高岭石→高岭石+(地开石+明矾石)→高岭石+明矾石+(地开石)→高岭石+地开石+明矾石。由于高硫化浅成低温热液交代黄铁绢英岩化带的斑岩型矿体, 致使上部矿石中还有少量交代残余的绢云母; 斯弄多低硫化浅成低温热液矿床的蚀变矿物垂向分布为: 白(绢)云母+(钠云母)→白(绢)云母+钠云母+(伊利石)→白(绢)云母+钠云母+蒙脱石+伊利石→白(绢)云母+钠白云母+蒙脱石+伊利石, 其中顶部白(绢)云母是后期黑云母花岗斑岩蚀变所产生, 本身与成矿无关; 矿体主要赋存在伊利石+蒙脱石带, 随着蒙脱石被伊利石化, 矿体也逐渐尖灭。     

皖东地区毛山金矿蚀变矿物特征及其地质意义

毛山金矿属于中小规模金矿山。通过对矿体两侧的黄铁绢英岩进行热分析与透射电镜观察研究以及对绢云母的热分析及其化学成分研究，认为水热蚀变、硅化及矿化程度均较高，成矿热液可能来自矿区南部和深部，该地区是寻找隐伏矿体的靶区。黄铁绢英岩中出现微细石膏，反映在成矿过程中可能出现过氧化阶段，是出现富矿的显示。进而提出乳白色石英脉中出现石膏晶体是寻找金矿化的新的找矿标志。     

滇西墨江金厂金矿床时空四维结构模型

对墨江金厂金矿关键性地质问题研究结果表明,矿区金厂韧性剪切带（ＳＺｊｃ）、ＮＷＷ向褶皱构造和金矿超镁铁岩体侵位构造是不同成矿期的控矿构造,金矿床有三种成因类型,分别对应三期三种不同类型的成矿作用。     

西藏冈底斯成矿带西段罗布真浅成低温热液型金银多金属矿床地质特征及发现意义

在野外地质调查基础上,通过详细的岩相学和矿物学观察,以及矿床对比研究等手段,初步探讨了罗布真金银多金属矿床成因类型和地质意义。罗布真金银多金属矿床位于冈底斯陆缘火山-岩浆弧西段,矿体受NWW向断裂构造控制,呈似层状、脉状、透镜体状产于帕那组火山岩中,或产于火山岩与始新世闪长岩的接触部位。金银矿体由石英脉、蚀变岩和角砾岩组成。矿石具有角砾状、条带状和网脉状等热液型矿床典型构造。金属矿物主要有自然金、碲银矿、黄铁矿、方铅矿、毒砂和闪锌矿等,非金属矿物有石英、玉髓、绿泥石、方解石等。围岩蚀变属于中、低温环境下的一套蚀变矿物组合,有绢云母化、硅化、碳酸盐化、绿泥石化等;围岩蚀变具有从矿脉中心到围岩有绢英岩化到青磐岩化过渡分带,垂向上也有顶部伊利石、硅华、玉髓层,深部绿泥石、绢云母、微细粒石英-玉髓脉的分带。成矿流体显示出低温、低盐度的特点,主要来自于大气降水;而金、银等成矿物质主要来源于围岩。通过矿床对比研究,初步确定罗布真金银多金属矿床属于低硫化型浅成低温热液型矿床,该成因类型矿床在冈底斯成矿带西段尚属首次发现。     

Orogenic Gold Mineralization in the Qolqoleh Deposit, Northwestern Iran

The Qolqoleh gold deposit is located in the northwestern part of the Sanandai‐Sirjan Zone, northwest of Iran. Gold mineralization in the Qolqoleh deposit is almost entirely confined to a series of steeply dipping ductile–brittle shear zones generated during Late Cretaceous–Tertiary continental collision between the Afro‐Arabian and the Iranian microcontinent. The host rocks are Mesozoic volcano‐sedimentary sequences consisting of felsic to mafic metavolcanics, which are metamorphosed to greenschist facies, sericite and chlorite schists. The gold orebodies were found within strong ductile deformation to late brittle deformation. Ore‐controlling structure is NE–SW‐trending oblique thrust with vergence toward south ductile–brittle shear zone. The highly strained host rocks show a combination of mylonitic and cataclastic microstructures, including crystal–plastic deformation and grain size reduction by recrystalization of quartz and mica. The gold orebodies are composed of Au‐bearing highly deformed and altered mylonitic host rocks and cross‐cutting Au‐ and sulfide‐bearing quartz veins. Approximately half of the mineralization is in the form of dissemination in the mylonite and the remainder was clearly emplaced as a result of brittle deformation in quartz–sulfide microfractures, microveins and veins. Only low volumes of gold concentration was introduced during ductile deformation, whereas, during the evident brittle deformation phase, competence contrasts allowed fracturing to focus on the quartz–sericite domain boundaries of the mylonitic foliation, thus permitting the introduction of auriferous fluid to create disseminated and cross‐cutting Au‐quartz veins. According to mineral assemblages and alteration intensity, hydrothermal alteration could be divided into three zones: silicification and sulfidation zone (major ore body); sericite and carbonate alteration zone; and sericite–chlorite alteration zone that may be taken to imply wall‐rock interaction with near neutral fluids (pH 5–6). Silicified and sulfide alteration zone is observed in the inner parts of alteration zones. High gold grades belong to silicified highly deformed mylonitic and ultramylonitic domains and silicified sulfide‐bearing microveins. Based on paragenetic relationships, three main stages of mineralization are recognized in the Qolqoleh gold deposit. Stage I encompasses deposition of large volumes of milky quartz and pyrite. Stage II includes gray and buck quartz, pyrite and minor calcite, sphalerite, subordinate chalcopyrite and gold ores. Stage III consists of comb quartz and calcite, magnetite, sphalerite, chalcopyrite, arsenopyrite, pyrrhotite and gold ores. Studies on regional geology, ore geology and ore‐forming stages have proved that the Qolqoleh deposit was formed in the compression–extension stage during the Late Cretaceous–Tertiary continental collision in a ductile–brittle shear zone, and is characterized by orogenic gold deposits.     

The Crater Mountain Deposit,Papua New Guinea: Porphyry‐related Au–Te System

Ore mineralization and wall rock alteration of Crater Mountain gold deposit, Papua New Guinea, were investigated using ore and host rock samples from drill holes for ore and alteration mineralogical study. The host rocks of the deposit are quartz‐feldspar porphyry, feldspar‐hornblende porphyry, andesitic volcanics and pyroclastics, and basaltic‐andesitic tuff. The main ore minerals are pyrite, sphalerite, galena, chalcopyrite and moderate amounts of tetrahedrite, tennantite, pyrrhotite, bornite and enargite. Small amounts of enargite, tetradymite, altaite, heyrovskyite, bismuthinite, bornite, idaite, cubanite, native gold, CuPbS₂, an unidentified Bi‐Te‐S mineral and argentopyrite occur as inclusions mainly in pyrite veins and grains. Native gold occurs significantly in the As‐rich pyrite veins in volcanic units, and coexists with Bi‐Te‐S mineral species and rarely with chalcopyrite and cubanite relics. Four mineralization stages were recognized based on the observations of ore textures. Stage I is characterized by quartz‐sericite‐calcite alteration with trace pyrite and chalcopyrite in the monomict diatreme breccias; Stage II is defined by the crystallization of pyrite and by weak quartz‐chlorite‐sericite‐calcite alteration; Stage III is a major ore formation episode where sulfides deposited as disseminated grains and veins that host native gold, and is divided into three sub‐stages; Stage IV is characterized by predominant carbonitization. Gold mineralization occurred in the sub‐stages 2 and 3 in Stage III. The fS₂ is considered to have decreased from ～10^?2 to 10^?14 atm with decreasing temperature of fluid.     

华北克拉通和西澳克拉通金矿床对比研究及其对中国金矿勘查的启示

华北克拉通固结时间较晚,活动性较强,金矿床赋矿围岩以中深变质的镁铁质岩石和花岗岩类岩石为主,大规模金矿床一般产在韧、脆性剪切叠加的构造带中,成矿时代在188~46Ma之间.西澳克拉通固结较早,稳定性较好,金矿床主要产在太古宙花岗岩-绿岩地体中,一般产在韧-脆性剪切过渡带或叠加的构造带中,金矿化年龄在2640~2600Ma之间.华北克拉通金矿床比西澳金矿床形成晚,受剥蚀程度低,许多矿床尚未出露地表,在深部寻找盲矿体前景可观.     

甘肃天水李子金矿床物质组分及金银赋存状态研究

甘肃天水李子金矿具有斑岩型和韧性剪切带型两种类型的金矿床。本文在详细野外工作的基础上,采用光薄片鉴定、人工重砂分析、化学成分分析、化学物相分析、电子探针波谱分析等技术方法,查明了矿床主要具有蚀变岩型和石英脉型两种金矿石类型,其中韧性剪切带型金矿矿石类型主要为石英脉型,斑岩型金矿矿石类型主要为斑岩型-蚀变岩型;韧性剪切带...     

新疆阿尔金盘龙沟金矿高光谱蚀变矿物找矿标志研究

高光谱遥感技术是近年来兴起并逐渐成熟的蚀变矿物研究方法。盘龙沟金矿床围岩蚀变发育,主要蚀变类型包括硅化、绿泥石化、绢云母化、碳酸盐化、钠长石化、褐铁矿化等,蚀变与金矿化关系密切。文章通过航空高光谱遥感数据和地面光谱数据,提取和诊断盘龙沟金矿床的不同地段、不同地质体的蚀变矿物信息,研究分析金矿区的航空和地面高光谱蚀变矿物、蚀变矿物组合特征,以及矿区围岩蚀变特征,总结航空和地面光谱蚀变矿物分带找矿标志规律,结合金矿床地质矿产特征,系统剖析金矿床的综合找矿标志特征,构建盘龙沟金矿床高光谱蚀变矿物找矿标志;同时依据绢云母、绿泥石的诊断光谱,研究两种蚀变矿物的光谱变化特征,分析了金矿床围岩蚀变的形成条件和蚀变矿物的温压条件,进而初步推测盘龙沟金矿床为中低温热液型金矿,其矿体与围岩形成的环境条件不同。     

The Bepkong gold deposit,Northwestern Ghana

The Bepkong gold deposit is located in the Wa–Lawra belt of the Paleoproterozoic Baoulé-Mossi domain of the West African Craton, in NW Ghana. It occurs in pelitic and volcano-sedimentary rocks, metamorphosed to greenschist facies, in genetic association with zones of shear interpreted to form during the regional D₃ deformational event, denominated D_B1 at the deposit scale. The ore zone forms a corridor-like body composed of multiple quartz ± carbonate veins surrounded by an alteration envelope, characterized by the presence of chlorite, calcite, sericite, quartz and disseminated pyrite, arsenopyrite plus subordinate pyrrhotite and chalcopyrite. The veins contain only small proportions of pyrite, whereas most of the sulphides, particularly arsenopyrite, occur in the altered host rock, next to the veins. Pyrite is also common outside of the ore zone. Gold is found in arsenopyrite, where it occurs as invisible gold and as visible – albeit micron-size – grains in its rims, and as free gold within fractures cross-cutting this sulphide. More rarely, free gold also occurs in the veins, in fractured quartz. In the ore zone, pyrite forms euhedral crystals surrounding arsenopyrite, but does not contain gold, suggesting that it formed at a late stage, from a gold-free hydrothermal fluid.