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东秦岭两类花岗岩与两个金矿系列 总被引:14,自引:3,他引:14
本文根据东秦岭地区花岗岩金矿的特征,全面地探讨了花岗岩与金矿化的关系,将东秦岭地区与花岩有关的金矿床分为深源浅成型花岗岩金矿系列和浅源深成型花岗岩金矿系列。不同成因系列的花岗岩与金矿的关系完全不同。文中还简要地阐述了与两个系列金矿有关的花岗岩的地花岗岩的地质地球化学特征和秦岭造山带的构造演化。 相似文献
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Two groups of granitoids associated with gold mineralization in the Appalachian orogen of southwestern New Brunswick are recognized: a Late Silurian to Early Devonian (423–396 Ma) granodioritic to monzogranitic series (GMS), and a Late Devonian (370–360 Ma) granitic series (GS). The GMS granitoids are relatively low in silica, calc-alkaline, metaluminous to weakly peraluminous, and show characteristics of normal (oxidized) to reduced I-type granites depending on the properties of country rocks. They may have been derived from partial melting of lower crustal rocks triggered by underplated basaltic magmas; and country rocks bearing reduced organic carbon and/or graphite may have played an important role in the reduction of normal I-type intrusions to reduced I-type, which is essential in the formation of intrusion-related gold systems. In contrast, the GS granites, although calc-alkaline and metaluminous to peraluminous, are relatively rich in silica, incompatible elements, and high field strength elements. They are fractionated I-type granites, and are probably related to the coeval Mount Douglas granite in the Saint George batholith through fractional crystallization. Their parental magmas may have been derived from partial melting of quartzofeldspathic sources at relatively low temperatures. Both GMS and GS intrusions are orogenic, although some of them display the affinity of those emplaced into a within-plate environment. The origin of intrusion-related gold systems in this region appears to be controlled by several factors, including magma sources, magmatic processes, redox conditions (country-rock nature), and local structural regimes. 相似文献
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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. 相似文献
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The formation of the Tongyu gold deposit, controlled by regional polyphase deformation-metamorphism.is closely related to the regional composite antiform-shear slip fracture zone. Late-stage reworking of theTaihua Group accounts for the enrichment of ore substances. It is a typical syntectonic gold deposit. The formation and evolution of the deposit involved four stages: (Ⅰ) the state of preparation of ore sub-stances, in which primary source beds originated: (Ⅱ) the stage of remobilization of ore substances, in whichregional progressive metamorphism and migmatization and thermodynamic-chemical differentiation led toremobilization of gold and its initial local concentration: (Ⅲ) the stage of gold deposit formation, in which re-gional folding produced concordant and cross shear-slip fractures and under the dynamic action gold was sepa-rated and migrated in a certain direction and concentrated to form a gold deposit: (Ⅳ) the stage ofsuperpositon, reworking and exposure of orebodies, in which the block uplifted and the deposit againunderwent reworking through faulting and mechanical differentiation.Thermodynamic mineralization played adominant role in the formation of the deposit. 相似文献
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黑龙江东安金矿床赋矿岩浆岩锆石U-Pb年代学及岩石地球化学特征 总被引:6,自引:1,他引:5
东安金矿床是环太平洋成矿域的一处大型低硫型浅成低温热液金矿床,赋存于燕山期碱长花岗岩和中酸性火山岩中。本文通过LA-ICP-MS锆石U-Pb同位素定年,获得赋矿的碱长花岗岩和光华组流纹岩的加权平均年龄分别为183.2±1.3Ma和109.1±1.2Ma,表明碱长花岗岩的侵位年代为早侏罗世,光华组火山岩的喷出时代为早白垩世。在地球化学组成上,东安碱长花岗岩具高硅、高钾和低磷的特征,富集Rb、Th和K,亏损Nb、Ta、Sr、P和Ti,属于高分异的I型花岗岩,是太平洋板块俯冲作用的产物。光华组中酸性火山岩富集Rb、Th、U和K,亏损Nb、Ta、P和Ti,为太平洋板块俯冲方向发生改变后的岩石圈伸展减薄环境下,镁铁质下地壳部分熔融而形成的。东安金矿床成矿年龄(107~108Ma)与光华组火山岩的成岩年龄在误差范围内一致,表明成矿与成岩作用为同一地质事件,均形成于早白垩世太平洋板块俯冲背景下的拉张构造环境中。结合区内其他浅成低温热液型金矿床的赋矿围岩特征,认为早白垩世陆相火山岩是东北地区寻找浅成低温热液金矿床的有利场所。 相似文献
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小秦岭地区金矿化与花岗岩浆活动的关系──流体标型特征提供的依据 总被引:1,自引:0,他引:1
徐启东 《大地构造与成矿学》1998,22(1):35-44
对小秦岭地区与金矿化有关的主要地质体中流体包裹体叠加组合标型特征和有关地质体Sr、H、O同位素组成的标型性研究证明,小秦岭地区中生代中温热液金矿化流体与中生代花岗岩浆分界出的热液之间没有直接联系,成矿流体更可能是一种演化的大气降水。花岗岩浆活动对金矿化的贡献主要表现为提供了一组局部热源,间接地影响了金矿化的形成。 相似文献
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中朝准地台原生金矿铅同位素特征及有关问题的讨论 总被引:2,自引:1,他引:2
本文研究了中朝准地台原生金矿床各类地质体铅同位素组成特征,认为中朝准地台构造环境的演化趋势是从活动带到稳定克拉通又到活化克拉通;与此同时,由于构造环境的缘故,金的演化历史主要分为两个阶段:一是金矿源层的形成(37~20亿年),二是金的活化与成矿作用(1.8~1.0亿年);并初次确立了在准地台上寻找同类金矿床的地质、地球化学找矿模式,即:太古代变质岩系(金源)—中生代花岗岩浆作用(金的活化、转移、富集)—含金构造裂隙(金的集中、沉淀、成矿)。 相似文献
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I.V. Gaskov A.S. Borisenko V.V. Babich E.A. Naumov 《Russian Geology and Geophysics》2010,51(10):1091-1101
Gold mineralization at copper-skarn deposits (Tardanskoe, Murzinskoe, Sinyukhinskoe, Choiskoe) in the Altai–Sayan folded area is related to different hydrothermal-metasomatic formations. It was produced at 400–150 ºC in several stages spanning 5–6 Myr, which determined the diversity of its mineral assemblages. Gold mineralization associated with magnetite bodies is spatially correlated with magnesian and calcareous skarns, whereas gold mineralization in crushing zones and along fault sutures in moderate- and low-temperature hydrothermal-metasomatic rocks (propylites, beresites, serpentinites, and argillizites) is of postskarn formation. Different stages were manifested with different intensities at gold deposits. For example, the Sinyukhinskoe deposit abounds in early high-temperature mineral assemblages; the Choiskoe deposit, in low-temperature ones; and the Tardanskoe and Murzinskoe deposits are rich in both early and late gold minerals. Formation of commercial gold mineralization at different copper-skarn deposits is due to the combination of gold mineralization produced at different stages as a result of formation of intricate igneous complexes (Tannu-Ola, Ust’-Belaya, and Yugala) composed of differentiated rocks from gabbros to granites. 相似文献