秦岭凤太矿集区铅锌金矿区域成矿规律研究

陕西秦岭凤太矿集区位于商丹缝合带和勉略缝合带之间,是著名的铅锌金多金属矿集区,区内发育海相沉积改造型铅锌矿和构造蚀变岩型金矿,成矿类型多样.在矿床地质特征、成矿地质条件、铅锌金矿时空分布规律、成矿流体来源研究分析的基础上,对凤太矿集区铅锌金矿成矿规律进行了剖析.认为凤太矿集区铅锌金矿床是多种成矿作用叠加改造形成的,早期...     

南秦岭沉积岩型金矿成矿潜力与找矿前景分析

南秦岭沉积岩区广泛分布于商丹缝合带与勉略缝合带间的秦岭地块中，并以上古生界泥盆系最为发育。该含矿与岩矿建造中产出多种类型的浸染状金矿床，具有一定的空间分布规律。本文根据各金矿类型地质特征、岩矿与含矿岩系组成、所在区地质背景等方面，分析了它们的成矿潜力和找矿前景。     

南秦岭寒武系黑色岩系中夏家店金矿床地质地球化学特征

研究取得如下成果和认识确定了微细浸染型金矿床赋存于含矿性好的重晶石-硅质岩热水沉积岩系之中;矿床形成经历同生沉积成矿预富集,韧-脆性剪切构造叠加和后生热液改造金的工业富集过程,与本区古大陆俯冲-碰撞造山大地构造演化密切耦合.成矿作用共划分为3期8阶段,矿石由3类11亚类型组成,体现出复杂改造的成矿过程.矿化矿物流体包裹体均-温度集中在199～300℃,成矿压力为370×105～820×105 Pa,具中-低温热液成矿特征;成矿早期流体包裹体盐度3.27(NaCl)%,中晚期5.25(NaCl)%;6件矿化矿物氢氧同位素组成δ18OH2O为-7.86‰～0.37‰,δDH2O为-80.70‰～66.30‰,具有由大气降水向右横向漂移的以天水为主的成矿流体受到较强烈的改造;金矿床属于热水沉积-韧脆性构造叠加-大气降水为主含矿热液改造的微细粒浸染型(类卡林型)金矿床.     

四川锦屏山地区金矿床的成矿机理和成因探讨

在对研究区典型金矿床的矿化地质特征、围岩蚀变特征分析的基础上,讨论了四川锦屏山地区金矿床的成矿机理和矿床成因。锦屏山地区金矿床的含矿围岩以浅变质的三叠系粉砂质片岩为主,金矿床围岩中广泛发育碳酸岩化（早期）和硅化（后期）,前者以铁白云石化为特征,后者以黄铁绢英岩化、绿泥石化和石英脉发育为特征。碳酸岩化主要发生在碳酸岩脉与泥质粉砂岩的接触带上的粉砂岩一侧,由碳酸岩脉侵入时的热液交代岩石中的泥质矿物而形成。金矿体的走向与碳酸岩化带的产状基本一致,金主要富集于硅化强烈、黄铁绢英岩化发育地段。碳酸岩化地层中具有较高的含金背景,指示成矿物质金来源于地幔,而矿化主要发生在黄铁绢英岩化和硅化带及石英硫化物脉中。结合矿床的同位素地球化学特征,认为研究区金矿的成矿作用主要是后期热液的改造作用中金元素发生再次富集的结果。金矿的形成经历了碳酸岩脉侵入、地层发生铁白云石化并初步富集形成矿源层（岩）阶段和以硫化物石英脉为代表的热液期的大规模富集成矿两个阶段,矿床的成因类型因属于改造型金矿床。     

豫西金矿地质特征与构造控矿探讨

豫西地区是国家重点金多金属成矿区带,成矿地质条件优越,区内金及多金属矿类型多样。通过对研究区地质特征及成矿地质条件的分析,得出区内金及多金属矿矿床形成受多重因素控制,包括地层、构造以及岩浆岩因素,并且在这些因素中,构造控矿占主导。在此基础上,将研究区内金矿矿床类型分为构造蚀变岩型金矿床、构造破碎带型金矿床、斑岩型金矿床以及爆破角砾岩筒型金矿床4种类型,并对每一种类型选取1个典型的矿床进行具体讲述。依据对研究区成矿地质特征以及5种构造控矿类型的叙述,论述了拆离-变质核杂岩构造对金矿成矿的构造控矿作用和构造控矿规律,并根据该区金矿矿床成矿规律,提出选取找矿靶区的8项依据,最后优选出7处找矿有利靶区。     

秦岭造山带泥盆系(陕西段)主要金矿床地球物理地球化学异常特征及找矿标志

以构造控矿和热液喷流沉积加后期改造的成矿观点,对秦岭造山带泥盆系(陕西段)主要层控金矿床的地球物理地球化学异常特征进行总结,从矿床地质分析入手,在充分认识泥盆系金矿成矿规律的基础上,提出该类金矿床的综合找矿标志.     

甘肃阳山超大型卡林-类卡林型复合式金矿床特征

阳山金矿于世纪之交勘查并扩大为超大微细浸染型金矿,矿床形成受地层、浅成花岗斑岩、韧-脆性剪切构造及热液活动的多种因素的叠加与改造控制,研究认为矿床具有卡林型和类卡林型两种矿化类型特点,卡林型矿化于韧性剪切早、早—中期阶段和晚期阶段,分别出现含砷黄铁矿-毒砂-次显微金-白云石-石英矿化组合及黄铁矿-辉锑矿-石英方解石矿化组合,及Au-As-Sb-Hg的成矿地球化学组合;类卡林型矿化出现在脆性中—晚期阶段,以黄铁矿-毒砂-自然金-碲铋矿-白云石-石英矿化(含黄铜-闪锌-方铅矿)组合为特征,及Au-As-Cu-Pb-Zn-Te-Bi成矿地球化学组合。阳山复合式金矿含矿地层中沉积成岩黄铁矿δ34S为-24.6‰～-29.0‰,早期—早中期韧-脆性剪切金属硫化物矿化产物δ34S值为5.0‰～7.0‰,中—晚期蚀变花岗斑岩中金属硫化物矿化产物δ34S值为-2.9‰～-2.1‰,显示地层中生物硫、强变形造山带地壳硫、少量岩浆硫混入的多源特征。流体包裹体氢氧同位素与硫同位素近同步特征,成矿热液显示地下流体、强烈改造水和少量岩浆水的混合。     

湘、桂地区碳硅泥岩型金矿床成矿地质条件

产于碳质硅岩、碳质泥（板）岩、泥质板岩、粉砂质板岩及不纯的碳酸岩盐中的金矿床，因与碳硅泥岩型铀矿含矿主岩很相似并有一定的共生关系，将该类金矿床称之为碳硅泥岩型金矿。其含矿主岩属裂谷构造环境下形成的海相热水沉积产物－碳硅泥岩系，该类矿床的形成与沉积其后 的构造改造有关，多数与岩体关系不明显。对湘中桂北地区碳硅泥岩型金矿床成矿地质条件的研究，总结出该类金矿床形成的三个阶段；（１）矿源层金的原始富集，（２）构造改造－热液成矿阶段蚀 变带富集，（３）表生氧化改造富集。     

陕西石泉县羊坪湾金矿床地质-地球化学特征及金的富集规律

羊坪湾金矿床是在南秦岭造山带石泉-汉阴北部地区继黄龙金矿床和鹿鸣金矿床开发之后近年来新发现的金矿床,对该金矿床的研究对于该区域找矿实践及金成矿理论研究具有重要意义.笔者通过野外调研和室内测试相结合对羊坪湾金矿床地质、地球化学特征及金的富集规律进行了研究.羊坪湾金矿产于下志留统梅子垭组(S1m)含炭二云母石英片岩中,目前矿区圈出南、北两条平行展布的金矿化蚀变带,在矿带内圈出3条平行展布的金矿体.金矿化特征为硅化、黄铁矿化.金粒度较粗,主要为明金,以粒间金、裂隙金等形式赋存.含炭二云母石英片岩夹石英岩互层有利岩性段和韧(脆)性剪切构造控制着金矿的产出.流体包裹体研究表明:均一温度为170～220℃,属中-低温;氢、氧同位素的特征显示,成矿热液中的水介质是以大气降水和变质分泌水为主的混合水.硫同位素的变化范围是7.5‰～11.7‰,说明成矿物质主要来源于地层.综合地质地球化学特征认为该矿床为沉积-改造型中低温热液矿床.     

河南庄金矿地球化学特征及成矿流体探讨

河南庄金矿位于华北板块最南端的秦岭构造带上,赋矿围岩为一套碳酸盐岩钙泥质建造,矿化受地层和构造发育控制.通过微量元素、稀土元素、C-H-O-S同位素分析对成矿流体来源和成矿条件进行了研究.其中微量元素、稀土元素、氢-氧同位素分析都指示成矿流体来自岩浆,后期受到变质作用和沉积改造作用影响;碳-氧同位素数据表明碳和部分氧元素来自海相碳酸盐的溶解作用,并催化了金元素的富集;硫同位素与微量元素分析得出成矿环境为缺氧的还原环境,并指示成矿流体来自深地壳或地幔.河南庄金矿同蚀变岩型金矿的矿床地质-地球化学特征相似,应属于蚀变岩型金矿.     

内蒙古阿右旗卡休他他夕卡岩型铁金矿床地质特征及控矿因素探讨

内蒙古阿右旗卡休他他铁金矿床属于夕卡岩-热液叠加型矿床。特定岩性、岩浆岩、构造是形成该种类型矿床的基本条件：辉长岩和石英闪长岩与围岩的接触带控制矿床的产出部位,岩体接触带的夕卡岩控制着铁、金矿体的分布范围,层间破碎带和构造裂隙带则控制着铁、金矿体的形态。铁矿化产于中基性岩体和围岩接触的夕卡岩带中,金矿体产在富铁矿体及其附近的夕卡岩中,金矿和铁矿是同一地质作用过程中不同阶段的产物,矿床可能形成于海西中期。     

加拿大萨斯喀彻温省索西(Southey)钾盐矿床特征及成因

加拿大萨斯喀彻温省索西(Southey)钾盐矿床,主要赋存于中泥盆统的Elk Point(埃尔克波因特)群上部Prairie Evaporite(草原蒸发岩)组。钾盐矿层稳定,似水平状展布,埋深约1250~1550 m;钾盐矿物主要有钾石盐(KCl)和光卤石(KCl·Mg Cl2·6H2O),矿石品位高,w(K2O)可达11.17%~21.85%,是世界少有的高品质钾盐矿床。文章分别从构造位置、古地理条件、物源补给、沉积韵律和成矿过程等多个方面综合分析了索西钾盐矿床的成因。     

论凤山铜矿床的再生成因

凤山铜矿床产于中元古界昆阳群绿汗江组凤山段，其下伏为中元古代晚期的滇中裂陷槽中的狮山铜矿床。凤山铜矿床矿体呈脉状、巢状、囊状，切割围岩，形态产状受断裂构造及狮山段紫色层“刺穿体”的控制，是典型的后生矿床。矿石物质成分（以黄铜矿、斑铜矿为主）、黄铁矿的Co含量（0．6％）及Co/Ni比值（75．71）和硫化物的δ^34S值均继承了狮山铜矿床的特点；矿石具碎斑状、角砾状，细脉状和网脉状等后生矿石构造，凤山铜矿床黄铜矿、斑铜矿对各种波长入射光的反射率均高于狮山铜矿床黄铜矿、黄铜矿的Cu、Au、Ag含量高于狮山铜矿的黄铜矿，而S、As、Zn含量低于狮山矿的黄铜矿。基于上述特征，提出了凤山铜矿床的再生成矿模式。凤山铜矿床的成矿物质来自下伏的狮山铜矿床及狮山段紫色层细碧质火山角砾岩，经后期非含矿热液溶解而沿构造上升，而后在上覆地层的构造中沉淀、富集而形成再生矿床。     

新疆和田县雪凤岭锂矿床、雪盆锂矿床和双牙锂矿床地质特征及伟晶岩脉群分带初步研究

作为战略性关键金属矿产,锂矿勘查与研究已成为当今矿产勘查和地学研究的热点。项目组2017年以来通过多次野外勘查、系统取样与室内化验分析,确认在新疆和田县白龙山锂多金属矿床东部的雪凤岭一带发现了雪凤岭、雪盆和双牙3处花岗伟晶岩型锂多金属矿床。雪凤岭锂矿床由3个含矿伟晶岩脉群共计47条锂多金属矿体组成,矿体长32~360 m,厚0.9~8 m,走向110°~120°,倾角49°~78°。对雪凤岭矿区伟晶岩脉群研究,发现含矿伟晶岩脉群‒含白云母伟晶岩脉群‒块体石英长石伟晶岩脉群‒含黑色电气石伟晶岩脉群‒块体石英长石伟晶岩脉群‒含白云母伟晶岩脉群‒含矿伟晶岩脉群具对称分带特征,进而在距雪凤岭1550 m南部的双牙山和雪盆沟发现较好的锂矿体,其中双牙锂矿床主矿体长850 m,厚12 m,出露最宽处近100 m;雪盆锂矿床3条锂矿体,长800~1200 m,厚4~8 m,向西合成一个矿体,厚12~20 m。各矿体Li2O品位0.6%~4.02%。伴生BeO品位0.04%~0.15%,Rb2O品位0.10%~0.23%,Nb2O5品位0.007%~0.047%,Ta2O5品位0.003%~0.046%。预测雪凤岭、雪盆、双牙3个矿床334资源量共计Li2O为7.1886×105 t,BeO为2.648×103 t,Rb2O为1.433×103 t,Nb2O5为3.387×103 t,Ta2O5为1.727×103 t,雪凤岭一带有望成为一个超大型锂多金属稀有金属矿产基地。     

云南大平掌铜多金属矿床硫、铅、氢、氧同位素地球化学

对云南大平掌铜多金属火山岩型块状硫化物矿床的矿石矿物和火山岩围岩的Ｓ、Ｐｂ同位素及脉石矿物、硅 化岩、硅质岩等的Ｈ、Ｏ同位素地球化学特征进行了研究,认为矿床中大多数硫来源于热液对火山岩的淋滤,或直接 来源于火山喷气作用;矿石铅与火山岩铅属同一来源,且以富放射性成因铅为特征;成矿流体可能主要来源于深循环的海水与岩浆水的混合流体,而大气降水参与的可能性很小。     

云南白牛厂银多金属矿床成因

对云南白牛厂超大型银多金属矿床的地质、地球化学特征及矿床形成的长期性及多阶段性的研究认为:白牛厂银多金属矿床是热水沉积—叠生成因矿床,早期呈现寒武纪的热水同生沉积成矿作用,晚期为燕山期花岗岩浆热液成矿作用。该矿床是热水沉积成矿作用与岩浆热液成矿作用叠加成矿的产物。     

Silver-Bearing and Associated Minerals in El Zancudo Deposit, Antioquia, Colombia

The occurrence and the chemical compositions of ore minerals (especially the silver‐bearing minerals) and fluid inclusions of the El Zancudo mine in Colombia were investigated in order to analyze the genetic processes of the ore minerals and to examine the genesis of the deposit. The El Zancudo mine is a silver–gold deposit located in the western flank of the Central Cordillera in Antioquia Department. It consists mainly of banded ore veins hosted in greenschist and lesser disseminated ore in porphyritic rocks. The ore deposit is associated with extensive hydrothermally altered zones. The ores from the banded veins contain sphalerite, pyrite, arsenopyrite, galena, Ag‐bearing sulfosalts, Pb‐Sb sulfosalts, and minor chalcopyrite, electrum, and native silver. Electrum is included within sphalerite, pyrite, and arsenopyrite, and is also partially surrounded by pyrite, arsenopyrite, sphalerite, and tetrahedrite. Native silver is present in minor amounts as small grains in contact with Ag‐rich sulfosalts. Silver‐bearing sulfosalts are argentian tetrahedrite–freibergite solid solution, andorite, miargyrite, diaphorite, and owyheeite. Pb‐Sb sulfosalts are bournonite, jamesonite, and boulangerite. Two main crystallization stages are recognized, based on textural relations and mineral assemblages. The first‐stage assemblage includes sphalerite, pyrite, arsenopyrite, galena and electrum. The second stage is divided into two sub‐stages. The first sub‐stage commenced with the deposition and growth of sphalerite, pyrite, and arsenopyrite. These minerals are characterized by compositional growth banding, and seem to have crystallized continuously until the end of the second sub‐stage. Tetrahedrite, Pb‐Cu sulfosalts, Ag‐Sb sulfosalt, and Pb‐Ag‐Sb sulfosalts crystallized from the final part of the first sub‐stage and during the whole second sub‐stage. However, one Pb‐Ag‐Sb sulfosalt, diaphorite, was formed by a retrograde reaction between galena and miargyrite. The minimum and maximum genetic temperatures estimated from the FeS content of sphalerite coexisting with pyrite and the silver content of electrum are 300°C and 420°C, respectively. These estimated genetic temperatures are similar to, but slightly higher than the homogenization temperatures (235–350°C) of primary fluid inclusions in quartz. The presence of muscovite in the altered host rocks and gangue suggest that the pH of the hydrothermal solutions was close to neutral. Most of the sulfosalts in this deposit have previously been attributed as the products of epithermal mineralization. However, El Zancudo can be classified as a xenothermal deposit, in view of the low pressure and high temperature genetic conditions identified in the present study, based on the mineralogy of sulfosalts and the homogenization temperatures of the fluid inclusions.     

Geology, Geochemistry and Minerogenesis of the Shijuligou Zinc–Copper Deposit in Gansu, China

Abstract: The Shijuligou deposit was separated by an arcuate ductile shear zone cross the center of the deposit region, resulting in the difference between the southern and northern ore bodies. The lead (Pb) isotopic data of ores of the Shijuligou copper deposit have averages of 206Pb/204Pb, 207Pb/204Pb, and 208Pb/204Pb in 17.634, 15.444, and 37.312, respectively. It has been shown that ore-forming metals originated from intrusive and extrusive rocks in the upper part of ophiolites. The sulfur isotopic data of pyrite and chalcopyrite in the northern part change from +7.61‰ to +8.09‰ and +4.95‰ to +8.88‰ in the southern part. Isotopes of δ18O in the Shijuligou copper deposit are between +11.1‰ and +18.6‰, with the calculated δ18OH2O at +0.65‰. It is suggested that the mineralized fluid is a mixture of magma fluid, meteorological water, and seawater through circulating and leaching metals from the volcanic rocks. The zircon uranium-lead (U–Pb) dating of gabbro is 457.9±1.2 Ma, and the lower crossing age of the discordant and concordia curves of pyroxene spilite of zircon is 454±15 Ma. It is indicated that the Shijuligou deposit formed in a new ocean crust (ophiolite) of the back-arc basin in the late Ordovician. Mineralization should occur in the intermittence period after strong volcanic activity, and the age should be the late Ordovician. Moreover, the mineralization of ophiolite-hosted massive sulfide deposits in the ancient orogenic belt of the late Ordovician in the northern Qilian Mountains was controlled by the primary fault/fracture, with the forming of a metallogenic hydrothermal system by a mixture of volcanic magma fluid and seawater, which circularly leached the metallogenic metals from the volcanic rocks, resulting in their accumulation. The ore bodies were transformed with morphology and metallogenic elements. Jasperoid is an important sign for prospecting such deposits. There were many island arcs in the continent of China. This study provides evidence for understanding and exploration of ophiolite-hosted massive sulfide deposits in western China, especially in the area of northern Qilian Mountains.     

甘肃岷县寨上金钨矿床中钨矿特征及找矿标志

寨上矿床属于以金为主、伴生钨的多金属矿床。目前已发现15条钨矿化体,其中主要的6条钨矿体均与金矿体相重合。寨上矿区9处异常中有7处Au、W异常相重合。Au、W元素相伴生存在,局部地区形成金、钨矿化体共生的局面。钨矿物主要为白钨矿,极少量黑钨矿。白钨矿也是重要的载金矿物,金与钨关系密切。矿体主要产于碳质板岩、泥质板岩、钙质板岩等较软弱岩性地层。矿脉受控于层间或顺层断裂破碎带。矿区的主要蚀变类型有硅化、黄铁矿化,其次为碳酸盐化、绢云母化。低阻高极化异常能较准确的反映矿化带和矿脉的延伸位置。钨的水系沉积物异常和土壤异常均呈带状低值异常特征,与已知矿带吻合较好。研究成果及勘查实践证明,在该金矿化(带)体中寻找钨矿化体是最简捷的方法。     

新疆且末县卡特里西铜锌矿地质特征

卡特里西铜锌矿是近年在新疆南部昆仑山一带发现的、规模最大的有色金属矿床.矿床产于下石炭统托库孜达坂群火山岩地层中,矿体分布明显受地层控制.含矿岩性为双峰式火山岩建造上部的灰绿色基性凝灰岩,矿体多呈平行层状、似层状、透镜状分布于灰岩中及灰岩与含碳粉砂岩的接触处.该矿为海相火山岩型铜矿.主成矿元素为铜、锌,伴生元素为银、铅、硫,共有14个矿体,其中Ⅵ、Ⅷ号矿体为主矿体,矿石品位较富,目前估算铜、锌资源量均超过中型.通过进一步的地质、地球化学、地球物理工作表明,矿床主矿体向深部仍有较大延深,预测该矿床规模有望达到大型.