河南省洛宁县寨凹钼矿床流体包裹体研究及矿床成因

寨凹钼矿床位于华北克拉通南缘的熊耳地体．矿床定位受马超营断裂带的次级断裂控制,矿体呈脉状贼存于太华超群石板沟组黑云角闪斜长片麻岩中。成矿过程包括3个阶段：石英-辉钼矿阶段（I）、石英-多金属硫化物阶段（Ⅱ）、石英-碳酸盐阶段（Ⅲ）,其中,I阶段为主成矿阶段。寨凹钼矿床可见2类流体包裹体,即水溶液型和含子晶包裹体;激光拉曼指示包裹体成分主要为H2O。从早到晚,流体包裹体均一温度从I阶段100～260℃,经Ⅱ阶段110～160℃．变化为Ⅲ阶段120—180℃．矿床总体属于低温热液矿床：流体包裹体盐度从I阶段的2～25wt％NaCl．eqv演化至Ⅱ阶段的6—30wt％NaCl．eqv．然后降为Ⅲ阶段的7～25wt％NaCl．eqv。I阶段均一温度范围宽广、流体包裹体盐度由双峰式演化为单峰式以及包裹体温度-盐度双变图的负相关性指示了流体混合是主要的成矿机制。寨凹钼矿流体包裹体以高密度、高盐度的低温低压流体为特征,是含CaCl,流体参与成矿的结果,热的岩浆流体与冷的含CaCl,的卤水的混合．导致了辉钼矿的沉淀。寨凹钼矿床地质和流体包裹体特征与侵入岩相关的成矿系统一致．指示其成因类型为与侵入岩有关的钼矿床．     

Skarns and Genesis of the Huanggang Fe-Sn Deposit, Inner Mongolia, China

Abstract: The skarns and genesis were studied of the Huanggang Fe‐Sn deposit and the nearby Sumugou Zn‐Pb deposit in Inner Mongolia, China. In the Huanggang mine, Nos. 1 to 4 Fe ore bodies are arranged along a calcareous horizon from proximal to distal in this order to a granite intrusion named Luotuochangliang, while Sn ore body is situated near another granite intrusion named 204. According to the distance from the granitic intrusions, mineral assemblages in skarns are systematically changed. Garnet is the most predominant skarn mineral throughout the deposit. Hastingsitic amphiboles, however, predominate in the proximal skarns. Fluorite is common in the proximal skarns, while instead calcite is common in the distal skarns. Chlorite is characteristically present only in No. 3 ore body, and chlorite geothermometry gives near 300C for the mineralization of later stage. When garnet crystal shows zonal structure, isotropic andraditic garnet occupies the core, and is surrounded with anisotropic less‐andraditic garnet. The presence of white skarn along the boundary between main skarns and host sedimentary rocks confirms relatively reducing environment prevailing as a whole in the studied area. However, the compositional relation between coexisting garnet and clinopyroxene demonstrates that relatively oxidizing condition was achieved for garnet skarn and magnetite ore in the distal, Nos. 2 to 4 Fe ore bodies and Sumugou deposit, compared to that for garnet skarn in the proximal, No. 1 and Sn ore bodies. Preliminary study on the tin content of garnets in the studied area revealed a certain degree of contribution brought from granitic intrusives since the early stage of skarn formation, irrespective of proximal or distal. Oxygen isotope study on garnet, magnetite, quartz and skarn calcite, as well as hydrogen isotope study on hastingsitic amphibole, demonstrates mainly meteoric water origin for the skarn– and ore‐forming solutions. The occurrence of Sn, W, Mo and F minerals indicates that those elements were mainly supplied to the deposit later than the formation of skarns and iron ores, overlapping to them. These constraints allow to delineate the formation model of the deposit as follows (Fig. 10): At the time of late Jurassic to early Cretaceous, felsic activity occurred in this region as a part of Yanshanian magmatism, and formed granitic intrusions as well as thick volcanic piles on the surface. The circulation of meteoric water was provoked by the heat brought by the intrusions. By this circulation, much amount of iron was extracted from andesites of the Dashizhai Formation, and precipitated as skarns and magnetite ores along calcareous horizons near the bottom of the Huanggangliang Formation. Subsequently, volatile‐rich fluids with Sn, W and Mo were expelled from the solidifying granitic magmas, and precipitated these metals in the pre‐existing skarns and ores.     

中国单一银(-金)矿主要类型及其地质特征

对我国单一银（-金）矿床地质特征、成因类型和空间分布特点进行了总结.以成矿作用和成矿地质条件为基础,矿床成因为依据,我国单一银（-金）矿床可分为：（1）变质（混合岩化）热液型矿床;（2）火山（含次火山）热液型银（-金）矿床;（3）岩浆-热液型银（-金）矿床;（4）地热水溶滤型银（-金）矿床.     

峨眉山玄武岩与铅锌矿床成矿关系初探—以云南会泽铅锌矿床为例

本文以云南会泽铅锌矿为例，从成矿时代、成矿物来源、成矿流体来源和成矿热动力等方面初步讲座主峨眉山玄武岩与铅锌矿床成矿的关系。结果表明：矿床成矿时代可能与峨眉山玄武岩岩浆活动时代相近；峨眉山玄武岩在成矿过程中提供了部分成矿物质；伴随峨眉山玄武岩岩浆活动过程去气作用（包括地幔去气作用和岩浆去气作用）形成的流体参与了会泽铅锌矿成矿流体的形成；峨眉山玄武岩岩浆活动为成矿热动力的主要来源。     

河南嵩县喂母寺钨锰多金属矿地质特征及成因探讨

嵩县喂母寺钨锰多金属矿区位于华熊台缘拗陷东段,熊耳山隆起与嵩县断陷盆地的结合部位,为近年来在豫西地区发现的新型钨锰多金属矿床.矿体赋存在断陷盆地边缘的北东向断裂破碎带中,已圈出钨锰多金属矿体3条,钨、锰、铅、铁共生.矿体受地层岩性、构造、岩浆热液等因素控制,矿床成因与岩浆期后热液充填交代作用关系密切,属岩浆期后热液型钨锰多金属矿床.     

吉木萨尔县帐篷沟膨润土矿矿石性能及工业应用试验

该矿为钠基膨润土,由硬质矿块与软质胶结物组成。主要矿物为蒙脱石,平均含量72.85％,其次为石英、方英石及少量石盐、赤铁矿。阳离子交换容量75.95mmol/100g胶质价93ml/15g,湿态抗压强度4.41×10~4～5.79×10~4Pa,20％HCl活化土脱色力110.4～332.5,原矿造浆率5.78m~3/t～12.2m~3/t。浇注铸件质量优良,表面光滑。     

西藏昌都赵发勇溶洞控矿MVT铅锌矿床地质特征与矿床成因

赵发勇铅锌矿床位于三江成矿带中段昌都地区,铅锌矿化发育在新生代区域逆冲推覆构造中,以逆冲断层相关的古溶洞构造为主要控矿构造,代表了逆冲褶皱系MVT铅锌矿床中一种新的成矿模式——溶洞控矿成矿模式。因此,笔者在对赵发勇矿区详细地质填图基础上,对其成矿流体特征、成矿期方解石和硫化物的同位素组成进行了系统研究,以期对逆冲褶皱系MVT铅锌矿床中这一新成矿模式的成因机制进行探讨。赵发勇铅锌矿床矿体呈漏斗状-筒状发育在逆(冲)断层上、下盘的下二叠统和上三叠统灰岩古溶洞中,以角砾状、块状和皮壳状为主要矿石构造,以方铅矿、闪锌矿为主要矿石矿物,经历了硫化物期(I)和硫化物-碳酸盐期(II)两期成矿过程。I期成矿流体总体具低温度(130～140℃)、高盐度(23%～24%NaCl eq.)特征,部分呈现中高温度(约高达400℃)、中低盐度(约低达8%NaCleq.)特征;δDV-SMOW值介于–147‰～–94‰,δ18O流体值介于1.25‰～13.62‰;同成矿期方解石δ13CV-PDB值为–2.4‰～5.1‰,δ18OV-SMOW值为15.1‰～27.4‰。两期硫化物δ34S均为负值(–15.1‰～–1.6‰), 206Pb/204Pb、207Pb/204Pb、208Pb/204Pb组成分别为18.703 0～18.966 2、15.638 9～15.687 2、38.554 8～38.924 0。研究表明, I期铅锌矿化由①封存在地层中的蒸发浓缩的海水或/和区域古近纪—新近纪盆地下渗的盆地卤水形成的低温度、高盐度的本地流体和②由区域或矿区地层释放的蒸发浓缩海水和变质基底释放的变质水混合而成的中低温、中高盐度的区域流体两种流体组成;两期矿化的成矿金属来自造山带中从基底变质岩到盖层灰岩或/和碎屑岩等在内的多套地层,还原硫来自古近纪—新近纪盆地卤水中的硫酸盐±灰岩地层封存水中的硫酸盐的细菌还原作用;富还原硫的本地流体和富金属物质的区域流体的混合是铅锌硫化物沉淀的主要机制。结合对三江带区域溶洞控矿MVT铅锌矿床研究认识,笔者初步建立了逆冲褶皱系溶洞控矿MVT铅锌矿床成矿模型。     

地面高精度磁法在陕南西乡地区磁铁矿勘查中的应用

陕南西乡太山庙地区以往物化探工作程度低,方法单一,异常信息量少。为了探明基性岩体中磁铁矿的展布、延伸边界及深部变化情况,利用地面高精度磁法,使用向上延拓、2.5D人机交互反演等方法,结合1∶2.5万水系沉积物地球化学测量成果和初步的地质特征,对异常作出解释推断和综合评价。通过对地面高精度磁法资料的精细处理,圈定了磁异常范围,确定了基性岩体中磁铁矿的分布范围和空间特征,为地质勘查工程部署提供了可验证靶区。     

黑龙江省三矿沟夕卡岩型铁铜矿床矿物学特征及成矿物理化学条件

黑龙江三矿沟铁铜矿床位于大兴安岭北段多宝山矿集区,矿体产于燕山期侵入岩与奥陶系多宝山组大理岩接触带的夕卡岩内。根据矿物共生组合及交代关系,确定热液成矿过程包括夕卡岩阶段、退夕卡岩阶段和石英硫化物阶段。铁矿化主要发生在退夕卡岩阶段,形成磁铁矿、镜铁矿等铁氧化物,呈浸染状、条带状、块状产于钙铁榴石夕卡岩中。铜矿化主要发生在石英硫化物阶段,形成黄铜矿、斑铜矿等硫化物,交代早期矿物。电子探针分析等研究表明,三矿沟铁铜矿床发育钙质夕卡岩矿物组合,其石榴子石主要为钙铝榴石和钙铁榴石,辉石为透辉石钙铁辉石系列,角闪石属于钙角闪石系列,绿泥石属于I型三八面体富铁绿泥石。石榴子石有3种类型：早期自形粗粒的钙铝榴石(Grt-Ia)和钙铁榴石(Grt-Ib),以及晚期呈脉状产出的钙铁榴石(Grt-Ⅱ)。夕卡岩阶段成矿流体具有高温、弱酸性、高氧逸度的特征;退夕卡岩阶段流体温度降低,pH升高,形成大量铁氧化物;石英硫化物阶段流体温度和氧逸度降低,金属硫化物沉淀。     

吉林海沟金矿地质特征及应力场分析

海沟金矿是大型石英脉型金矿床,矿体严格受NE向断裂构造控制,成矿时代为晚侏罗世-早白垩世.矿石中金属矿物以黄铁矿、自然金、方铅矿和黄铜矿为主.28号主矿脉中,Au平均品位20.59×10-6.成矿物质来自地层和岩体.对构造应力场研究表明,矿区有3期构造应力场,分别是早期近S-N向挤压、中期NW向挤压和晚期NE向挤压.成矿期应力场最大主压应力方向为NE向.