北京市怀柔县北干沟金矿床地质特征及找矿方向

北干沟金矿床位于燕山金矿成矿带中段,属含金韧性剪切带石英脉型金矿床.新太古代变质岩含金丰度高,是金成矿的矿源层.韧性剪切带对金矿化具有控制作用.金矿化可分为2期,其与韧性剪切带脆性变形作用有关.自然金主要分布于黄铁矿、黄铜矿及其氧化物的微裂隙、粒间或空洞中.围岩蚀变强烈,主要类型有黄铁矿化、硅化、绢云母化、碳酸盐化、钠长石化、绿泥石化、重晶石化等.矿区今后的主要找矿方向是在I号断裂破碎带中寻找石英脉型、蚀变岩型金矿化和在Ⅱ号韧性剪切带东段的张性扩容段中寻找含金剪切带石英脉型金矿化.     

钦杭带南段庞西垌-金山银金矿田控矿构造分析及找矿指示

钦杭成矿带南段的庞西垌-金山银金矿田位于粤东与桂西交界处,包括庞西垌、金山、中苏、竹根坡、高村等银金矿床及一系列银金矿点,是20世纪80年代规划的十大银矿基地之一。庞西垌地区经历了多期的构造-岩浆活动,韧性剪切带和断裂构造尤其发育。印支期以来,可识别出3期主要构造:第一期为右行韧性剪切,前人利用糜棱岩中白云母测得时代为221 Ma;第二期为左行韧脆性剪切,北东向的庞西垌-金山断裂带反映最为突出,切过燕山晚期花岗岩;第三期为脆性走滑。银金矿体及矿石结构、构造主要受第二期左行韧脆性剪切带控制。应用里德尔剪切体系对控矿构造的分布特征分析显示,银金矿脉主要赋存于里德尔体系的D、R和T裂隙中;D裂隙是最重要的赋矿构造,热液蚀变岩型和石英脉型矿体呈透镜状左行斜列于主断裂面中,沿走向往南西侧伏;R和T裂隙主要发育梳状含金石英脉。R裂隙呈密集剪破裂产出,与主断裂面夹角15°~35°;T裂隙呈雁列状等距分布,与主断裂面夹角约为45°。这些矿脉就位体系,可以为该区进一步找矿作参考。     

鲁山县黄土岭韧性剪切带与含金石英脉

本文系统介绍了黄土岭韧性剪切带与含金石英脉的主要特征，阐述了含金石英脉与韧性剪切带内在的成生关系，指出了韧性剪切带内的次级Ｒ、Ｒ‘、Ｐ、Ｐ‘和Ｄ组剪切裂隙是含金热液运移的通道，富集的有利场所，是含金石英脉最有利的赋存空间，最后确认含石英脉属同韧性剪切型金矿脉。     

乌拉山金矿剪切带岩石显微构造演化初探——以113号矿化脉为例

本文以乌拉山金矿113号含金石英脉为例,论述了含金剪切带岩石的显微构造特征。通过对含金石英脉近百个岩石薄片的系统分析鉴定,对组成含金石英脉的主要矿物(石英、长石)和典型显微构造进行对比,分析了含金石英脉显微构造的演化过程和变形机制。研究表明,113号含金石英脉是通过韧性变形,后期转化为脆性变形所形成的应变石英脉,是早期无金石英经变形改造和金矿化作用的结果,属含金剪切带的一种特殊情况,即再活动的产物。     

金矿与剪切带

金矿与剪切带在空间上的关系大致可分为四种情况:①金矿体(脉)产于主剪切带中,并与其中的R、D、P裂隙一致。或呈浸染状弥散于断层岩中;②矿体(脉)与剪切带中的T、R裂隙一致,并穿过主(韧性)剪切带边界;③矿体(脉)横(斜)切主(韧性)剪切带:④矿体(脉)产于主(韧性)剪切带两侧的次级脆性断裂中。在成矿时代上有前剪切带期、同剪切带期和后剪切带期金矿。与剪切带有成因联系的金矿床的成矿作用称为构造—侧分泌作用或构造动力成矿作用。     

四川广元市董家院金矿剪切带构造特征及控矿作用

董家院金矿区地处扬子地台与秦岭及松潘—甘孜褶皱带结合部,区内金矿体主要为含金石英脉,矿脉形态复杂,以单脉、组合脉和脉群形态产出。矿体的空间分布受区内北东—南西向展布的一组脆—韧性剪切带的控制。Ⅰ级主剪切带和Ⅱ级次级剪切带是矿区金矿形成的导矿构造,而Ⅲ级和Ⅳ级剪切带却是金矿的容矿构造;该金矿床为与剪切带有关的石英脉型金矿床。     

辽宁省清原县南龙王庙金矿地质特征与成矿

南龙王庙金矿位于抚顺-清原太古宙绿岩带内.金矿赋存于太古宇鞍山群红透山岩组上部的火山岩-碎屑岩建造中,容矿围岩为磁铁角闪石英岩、黑云变粒岩及浅粒岩.矿体产出受韧性剪切带控制,金矿体沿韧性剪切带分布,呈透镜状、脉状、似层状,矿体规模一般较小.矿体为浸染-细脉含金黄铁矿和含金黄铁矿石英脉.金以自然金形式产出.硫同位素源自深部,铅同位素表明矿质来自绿岩,氢氧同位素指示成矿流体是变质水和大气降水的混合.研究认为南龙王庙金矿为具层控性受韧性剪切带控制的变质-大气降水混合热液型金矿.     

含金剪切带蚀变特征及其与金成矿的关系——以新疆天格尔金矿带为例

含金剪切带剪切变形过程中构造、流体-岩石相互作用导致系统内组分的迁移和再分配，这些过程控制着含金剪切带内蚀变特征及其金的成矿作用。在含金剪切带脆-韧性变形域内，成矿层次从深到浅矿石类型由蚀变糜棱岩型向石英脉型过渡，矿床成因类型由韧性剪切带型向蚀变破碎带型过渡，是主期剪切成岩成矿过程中不同时空演化阶段的产物。     

东准噶尔蒙西斑岩铜钼矿床脉体特征及其形成机制

蒙西斑岩铜钼矿床位于东准噶尔伊吾县琼河坝花岗岩北侧,以发育细脉、网脉状矿化为特征。脉体类型多样,包括石英脉、石英硫化物脉和硫化物脉等。根据脉体力学成因机制,其又可划分为水压破裂充填脉和构造破裂充填脉。构造破裂充填脉体按破裂形成的位错特征有正断与逆断两种。地表石英脉产状陡立,明显受断裂控制。脉体体积分数统计结果显示流体富集区呈向北缓倾的带状分布于深100～400m范围内,并与矿化富集带有较好的对应关系。脉体富集带内,脉体以共轭形式存在,一组为倾角较小的逆断破裂充填脉,另一组为倾角较大的正断破裂充填脉,他们可能为缓倾逆冲剪切带的次级破裂与充填脉,即富矿带内脉体是沿矿区低角度逆冲断裂次级破裂面充填的。矿区地表及深部(400m以下)脉体以陡立为主,矿化较弱。矿区流体的运移具先沿水压直立破裂往上运移,进入剪切带后沿剪切带次级破裂侧向和向上运移,并在剪切带中富集成矿。低温矿物组合脉体穿切高温矿物组合脉体的特征说明脉体形成过程矿区处于隆升构造环境,这对斑岩铜矿成矿有利。     

一种新的金矿化类型——含金碎裂钠长石岩型

在粤北清远—英德交界处的新洲地区,发育着一个中大型的褶皱式逆冲推覆构造;表现为震旦系浅变质地层在印支—燕山期由南西向北东逆冲到上古生界沉积岩之上.在这个逆冲推覆断裂系统中,除已完成勘探评价的中型碎裂毒砂石英脉型金矿床外,最近又发现一种新的金矿化类型——含金碎裂钠长石岩型.目前初步勘探该矿床已达中型规模.金矿体主要受新洲西部大沟谷—风门坳一带的北北西向Ⅱ级低角度韧性逆冲推覆断裂带控制.这些韧性断裂带在韧—脆性时期由钠长石沿R、D、P裂隙充填或交代,后期伴有钙质或白云质碳酸盐交代充填,共同组成碳酸盐—钠长石岩脉带.单条脉带一般厚数至数十米,长1～3km.脉带的围岩为钠长石化云母石英质糜棱岩或糜棱岩化岩石.脉带近旁的糜棱岩和糜棱岩化岩石有时局部也富含金.     

含金剪切带的类型划分及成矿机理

含金剪切带型金矿床是一种重要的新型矿床类型。本文系统地总结了含金剪切带的特征,提出了含金剪切带的几何学和运动学分类方案,并以成矿源,成矿场、成矿期和成矿相等方面论述了含金剪切带型金矿床的剪切动力成矿机制,建立了过渡型和叠加型两类动力成矿模式。     

中国南天山萨恨托亥-大山口成矿带韧性剪切带与金成矿作用

以南天山中段萨恨托亥-大山口成矿带内控矿韧性剪切带为例,对韧性剪切带的金成矿作用进行了初步探讨.通过对地质体的构造变形特点、变形演化过程的分析表明,韧性剪切带的构造属性控制了金矿的产状及规模,金矿化阶段与韧性剪切带的变形演化过程密切相关.矿化类型、矿化强度及矿化方式受韧性剪切带发展阶段制约,剪切带内物质组分迁移变化揭示出韧性剪切带与金在剪切带内的迁移富集、沉淀成矿的内在联系.韧性剪切带成矿作用是南天山成矿带中段重要的金矿成矿作用.     

剪切带型金矿中金沉淀的力化学过程与成矿机理探讨

剪切带型金矿是一种重要的金矿床类型,有关该类型金矿的成因问题已开展了大量研究,但对于剪切带中金的沉淀析出机制和成矿过程仍存在较大争议,对于赋矿部位的构造属性与矿床关系的研究尚显薄弱。对此笔者整理分析了近年来国内外有关剪切带型金矿的研究进展,并结合我国胶东金矿的研究实例,运用断层阀和力化学理论分析发现,无论是脆性还是韧性剪切带,无论是脉型还是蚀变岩型金矿,其成矿的关键部位均与构造应力集中而导致的脆性破裂(特别是R、T、R’破裂的产生)和碎裂作用以及(多期)岩体侵位密切相关,并且脆性破裂所导致的压力骤降从而引发流体闪蒸的力化学过程可能是造成金沉淀析出成矿的有效机制,其中多期岩体侵位所提供的流体是成矿的物质基础。此外,从国内外实例可以看出,剪切带中的脆性破裂不仅发生于脆性或脆韧性构造域,也可以发生在较深层次的韧性构造域中,尽管韧性域中产生脆性破裂的原因还不十分清楚,但这可能是韧性剪切带成矿的关键机制之一。最后,综合岩体、流体、剪切带三者对成矿的耦合作用,文中提出剪切带型金矿的成矿机理为:(多期)岩体侵位-热液活动-构造剪切-应力集中-脆性破裂(碎裂)产生-压力骤降-流体闪蒸-元素(金)析出,如此循环往复方可形成大型剪切带型金矿。     

江西金山剪切带型金矿床两类矿石的地球化学特征—兼论两阶段成矿机制

金山剪切带型金矿床主要发育含金硅质糜棱岩和含金石英脉两类矿石，它们分别在矿化第一和第二阶段形成。含金硅质糜棱岩与围岩－双桥山群上亚群具有一致的稀土和微量元素分布特征及相近的元素比值，后者为矿床第一阶段矿化的形成提供了物质来源。含金石英脉中流体包裹体的化学和同位素组成特征表明，矿化第二阶段的成矿流体为源于大气降水的地下热水，引起自然金沉淀的因素主要是流体的相分离。     

The role of fluids in partitioning brittle deformation and ductile creep in auriferous shear zones between 500 and 700 °C

The fabric, mineralogy, geochemistry, and stable isotope systematics of auriferous shear zones in various hydrothermal gold deposits were studied in order to discuss the role of fluids in rock deformation at temperatures between 500 °C and 700 °C. The strong hydrothermal alteration and gold mineralization indicates that effective permeability development goes ahead with high-temperature rock deformation. The economic gold enrichment is often hosted by breccias and quartz veins in the ductile shear zones, which either formed at fast strain rates or by low strain continuous deformation at slow strain rates. Both processes require (1) a close-to lithostatic to supralithostatic fluid pressure and/or (2) a strong rheology contrast of the deformed lithologies that is often developed during progressive hydrothermal alteration. Compartments of high fluid pressure are sealed from the rest of the shear zones by high-temperature deformation mechanisms, e.g. intracrystalline plasticity and diffusion creep, and compaction. In contrast, in mylonites with heterogeneous crystal plastic and brittle deformation mechanisms for the various minerals, an interconnected network of a grain-scale porosity forms an effective fluid conduit, which hampers fluid pressure build-up and the formation of veins.The auriferous shear zones of the various gold mines represent fluid conduits in the deeper crust, 100 m along strike and up to 1000 m down-dip. The hydrothermal fluids infiltrated may be responsible for low magnitude earthquakes in the Earth's lower crust, which otherwise deforms viscously.     

海南岛西部戈枕含金剪切带及其金矿成矿系列

古生代以来，海南西部戈沈含金剪切带至少经历了三次类型不同的构造变形，并发生了三次相关的金矿化。该剪切带的构造变形，在加里东旋回发生于抱板群矿源层下构造层次，表现为韧性剪切，其晚期形成含金长英质脉；在海西－印支旋回发生于中构造层次，表现为韧－脆性变形，形成糜棱岩型和石英脉型金矿床。     

The role of the granite emplacement and structural setting on the genesis of gold mineralization in Egypt

The Eastern Desert of Egypt is well known as a gold-mining district since ancient times. Gold mineralization is closely associated with the granitic rocks in such way that the mineralization is either hosted by or occurs immediately adjacent to the granite intrusions. Granitic rocks accompanying gold mineralization in the Eastern Desert can be grouped into three categories i.e. syn-late tectonic calc-alkaline granites, calc-alkaline to mildly alkaline granites of the transitional stage and post-tectonic alkaline granites.Tectonically, gold mineralization is linked with the tectonothermal stages that were operative during the evolution of the Arabian–Nubian Shield (ANS). During the primitive stages of the island-arc formation, pre-orogenic gold mineralization (auriferous exhalites) was formed by hot brines accompanying submarine volcanic activity. No role for the granite is observed in this stage. Syn-orogenic gold mineralization (i.e. gold hosted in altered ophiolitic serpentinites along thrust faults and in sutures, quartz veins hosted in the metavolcano-sedimentary assemblage and/or the I-type granitic rocks surrounding them) connected with the collision and accretion stage is characterized by emplacement of calc-alkaline (I-type) older granite batholiths. Shear fractures reflected in brittle–ductile shear zones and amphibolite-green schist facies regional metamorphism were broadly contemporaneous with this intense compressional tectonic regime. Available fluid inclusion microthermometry and isotopic studies reveal that both metamorphic and magmatic fluids related to the syn-late tectonic calc-alkaline granites were operative. A further indication for the role of the granites is indicated by the presence of some concentrations of Antimony, Bismuth, Molybdenum, Tungsten, Rubidium, Beryllium, Tin, Yttrium, Ytterbium, Tantalum and Niobium in some auriferous quartz veins in the Egyptian gold mines.In the cratonal development of the (ANS), the land underwent a transitional stage between the major subduction-related calc-alkaline magmatic activity and the subsequent post-tectonic plutonism represented by the alkaline granites. This transitional stage is dominated by the eruption of Dokhan volcanics and deposition of molass-type Hammamat sediments. At ~ 590–530 Ma, the Arabian–Nubian Shield was deformed by post-accretionary structures, in the form of N-trending shortening zones such as the Hamisana shear zone and NW-trending strike-slip faults such as the Najd fault system. The regional NNW–SSE directed extension opened spaces that were progressively sealed with different magmatic phases including among them a considerable proportion of rocks referred to as “younger granites” in the Egyptian literature. Late-orogenic gold mineralization connected with the transitional stage is represented principally by the gold-bearing quartz veins traversing Hammamat molasse sediments, quartz veins traversing syn-extensional younger granites and generally quartz veins in ductile to brittle shears related to the Najd fault system and within Hamisana shear zone and its splays.By the end of Pan African orogeny until the Tertiary, the basement was intermittently intruded by a number of sub-alkaline to per alkaline granite bodies that host Mo, Sn, W, Nb–Ta and U mineralization in the Eastern Desert of Egypt. Anorogenic gold mineralization connected with post-orogenic granites is represented by small amounts of the element in disseminations, stockworks and quartz veins of Sn–W–Ta–U mineralization.The present review shows that gold mineralization in Egypt is an expression of two major cycles with distinct magmatic and tectonic characteristics, and the two cycles were separated by a transitional stage. The emplacement of granites in the compressional cycle played an important role in metamorphosing the country rocks by producing the heat energy required for the regional metamorphism and the providing of the magmatic fluids. The H₂O–CO₂ fluids enriched in volatiles were released at the greenschist–amphibolite facies transition at 450°–500 °C and mixed with the I-type calc-alkaline granite related fluids and both moved down a temperature gradient away from the amphibolite-green schist transition at depth to a lower temperature regime in the upper levels where it is deposited in brittle–ductile shear zones. With the extensional cycle, the syn-extensional granite intrusions acted as heat engine in such way that the heat of the granite drove the convective cells to circulate through the auriferous host-granite contacts, leaching gold and other elements and depositing it in structurally favorable sites. In addition, the contrasts in competency between the granites with brittle deformational characteristics and the surrounding country rocks with a ductile response to stress, led to a generation of extensive fracture pattern within the more competent unit.     

新疆青河科克萨依韧性剪切带型金矿床的构造演化模式

科克萨依金矿床为典型的韧性剪切带蚀变糜棱岩型金矿床,它与克孜勒它乌推覆构造系统有着十分密切的内在成因联系,其变形作用以韧性变形为主,具典型的深层次变形构造组合特点,其成矿过程可划分为３个重要的构造演化阶段,即早期的剪切片理化阶段、中期的变形分解阶段和晚期的液压致裂阶段,从而建立了该剪切带金矿床的构造演化模式。早期的剪切片理化阶段仅具微弱的金矿化;中期变形分解过程中,含金流体的渗流导致水热蚀变和金在递进缩短应变域的大规模沉淀,形成了主成矿期的金矿化;在晚期液压致裂阶段,含金流体涌入张裂隙,形成高品位、小规模的含金石英脉。     

韧性剪切带型金矿三阶段构造成矿模式——以广东河台金矿床为例

基于对粤西河台韧性剪切带型金矿的构造解析,本文提出了韧性剪切带型金矿成矿的一种新构造模式,即:在大型韧性剪切带运动指向的前锋,当扩展弱化而出现分支糜棱岩带时,就会在韧性剪切带中出现由强变形带包绕的构造透镜体弱变形域。由于透镜体域中央岩石处于脆性环境,在变形分解过程中,强变形带中含金流体会通过岩石中的微破裂渗透到相对低压的弱变形构造透镜体域中央,并通过构造泵吸机制在其中产生周期性的液压致裂与裂开‒愈合,这为在韧性剪切阶段活动的金提供了一个理想的沉淀场所。上述构造机制很好地解释了河台金矿床中透镜状特富矿体的成因。河台含金韧性剪切带在韧性、韧‒脆性及脆性阶段在同位空间并列与叠加了不同类型金矿体,从早到晚分别形成细脉‒浸染型、石英脉型与破碎带蚀变岩型金矿体。河台韧性剪切带群为粤西深层次逆冲推覆构造前缘陡坡带的分支糜棱岩带,其韧性剪切阶段为左旋平‒逆剪切,韧‒脆性与脆性阶段转变为右旋平‒逆剪切,并依此讨论了金矿体的侧伏规律及隐伏矿体的预测方向。     

大山口剪切带大理岩糜棱岩的变形机制分析

大山口韧性剪切带是大别造山带"结晶轴带"内平行造山带延长方向的走滑型剪切带,其内发育的大理岩糜棱岩呈现了各种在绿片岩相变质条件下形成的显微构造,如碎斑构造、S-C组构、核幔构造等。糜棱岩化作用是以方解石颗粒粒度的减小为特征的,这一过程表现了大别造山带古老中地壳应变软化带和局部化带的岩石流变行为和物理状态。根据各种显微标志,并综合宏观特征,得出大山口剪切带总体为以右行剪切为主的走滑型剪切带,并被以正向滑动为主的近水平剪切带所改造。
作者在综合分析宏观及微观地质资料的基础上,初步建立了广水地区主要地质及变形事件序列,并指出:大别造山带三维空间上的变形及结构图象,主要是印支-燕山期陆-陆俯冲、碰撞造山运动的变形及造山期后的揭顶、塌陷等作用的综合结果。