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1.
该文以山东招远大尹格庄金矿床中微量元素为研究对象,通过对矿床围岩、矿石等微量元素的研究,表明大尹格庄金矿围岩中微量元素以富含 Bi,Au,Pb,W,Ag,Sn 为特点,矿体和矿化体中元素组合为 Au,Ag,As,Sb,Hg,B, Cu,Zn,Bi,Mo,Mn,Co,Ni,W。在5个成矿阶段中,第二阶段与第三阶段微量元素的富集程度较明显,表现为 Au, Ag,As,Co,Bi,Cu,Pb,Zn 等的富集,成矿元素可分为2个分带序列,主成矿元素为 Au Ag Cu Pb Zn Bi 组合、头晕元素 As Sb Hg 组合和尾晕元素 Co Ni 组合。 相似文献
2.
也金嘎波金矿位于冈底斯成矿带上,是对区域化探发现的Au、As多元素组合异常进行追踪发现的,属于热液型金矿床。矿区各类岩石Au、As、Sb、W、Hg、Ag、Bi、Pb元素平均值高于中国丰度值数倍以上,表明矿区具有丰富的物质来源基础。岩石地球化学研究证明,矿床地表发育Au、As、Sb等10多个元素组合异常。其中Au是成矿指示元素,As、Sb、W是密切伴生元素,Bi、Ag、Pb、Hg是一般的伴生元素。多元素组合异常浓度带发育,浓集中心互相套合叠置部位指示金矿(化)体位置。矿体指示元素(Au、As、Sb、W、Hg、Bi、Ag、Pb)异常分布在岩体、地层接触带和构造交汇处,显示金矿与岩浆活动、热液作用和断裂构造相关,属多次构造作用、岩浆热液叠加富集而成。该金矿床处在冈底斯成矿带内,此研究对该成矿带金异常的识别和查证,寻找新的金矿具有借鉴意义。 相似文献
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《Russian Geology and Geophysics》2007,48(8):643-655
The structure and petrologic composition of new gold-ore provinces in southeastern East Sayan (Tissa-Sarkhoi cluster) are considered. Several morphogenetic types of gold mineralization have been established: quartz veins with beresitization zones, veinlet-disseminated ores in granitoids, and listwaenitization and sulfidation zones in effusions of the Sarkhoi Group and intrusive rocks of the Late Riphean Khorin-Gol complex. According to geochronological dates and some mineralogical and geochemical features, the gold mineralization is close in age to these Precambrian island-arc complexes. Parageneses of two stages of ore formation have been recognized: early high-temperature (250–460 °C) gold-pyrite and late low-temperature (110–280 °C) gold-telluride. The latter mineralization is widespread and is represented by tellurides of Au, Ag, Pb, Bi, and Ni — petzite, calaverite, hessite, tellurobismuthite, altaite, and melonite. Native gold associated with these tellurides is characterized by a fineness of 750–900‰. The intimate temporal and spatial relationships of the gold mineralization with island-arc volcanoplutonic complexes and the wide occurrence of its veinlet-disseminated type suggest that this is porphyry gold mineralization related to the Late Riphean-Vendian island-arc magmatism. 相似文献
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选择胶东玲珑金矿典型矿体47号脉为研究对象,应用基岩地球化学方法,测试微量元素含量,研究微量元素与金的相关关系、计算微量元素的浓集系数并确定其轴向分带,探讨微量元素对深部金成矿的指示意义,期待能对玲珑金矿深部找矿提供一些参考.初步认识如下:矿区金矿体的最佳指示元素依次为Au、Ag、Bi、As、Cu、Co、Mo、Sb;金矿体的轴向分带序列从上到下依次为As、Pb、Ag、Cu、Hg、Sb、Mo、Ni、Th、V、U、Mn、Zn、Bi、Co、Au;矿体中Au、Bi、Ag、As富集系数大,Cu、Co富集系数中等,而Zn在矿体中相对亏损.研究结果表明,在深部47号矿体仍有较好的成矿前景. 相似文献
5.
I. V. Vikentyev R. Kh. Mansurov Yu. N. Ivanova E. E. Tyukova I. D. Sobolev V. D. Abramova R. I. Vykhristenko A. P. Trofimov V. B. Khubanov E. O. Groznova S. S. Dvurechenskaya S. G. Kryazhev 《Geology of Ore Deposits》2017,59(6):482-520
Geological and structural conditions of localization, hydrothermal metasomatic alteration, and mineralization of the Petropavlovskoe gold deposit (Novogodnenskoe ore field) situated in the northern part of the Lesser Ural volcanic–plutonic belt, which is a constituent of the Middle Paleozoic island-arc system of the Polar Urals, are discussed. The porphyritic diorite bodies pertaining to the late phase of the intrusive Sob Complex play an ore-controlling role. The large-volume orebodies are related to the upper parts of these intrusions. Two types of stringer–disseminated ores have been revealed: (1) predominant gold-sulfide and (2) superimposed low-sulfide–gold–quartz ore markedly enriched in Au. Taken together, they make up complicated flattened isometric orebodies transitory to linear stockworks. The gold potential of the deposit is controlled by pyrite–(chlorite)–albite metasomatic rock of the main productive stage, which mainly develops in a volcanic–sedimentary sequence especially close to the contacts with porphyritic diorite. The relationships between intrusive and subvolcanic bodies and dating of individual zircon crystals corroborate a multistage evolution of the ore field, which predetermines its complex hydrothermal history. Magmatic activity of mature island-arc plagiogranite of the Sob Complex and monzonite of the Kongor Complex initiated development of skarn and beresite alterations accompanied by crystallization of hydrothermal sulfides. In the Early Devonian, due to emplacement of the Sob Complex at a depth of approximately 2 km, skarn magnetite ore with subordinate sulfides was formed. At the onset of the Middle Devonian, the large-volume gold porphyry Au–Ag–Te–W ± Mo,Cu stockworks related to quartz diorite porphyry—the final phase of the Sob Complex— were formed. In the Late Devonian, a part of sulfide mineralization was redistributed with the formation of linear low-sulfide quartz vein zones. Isotopic geochemical study has shown that the ore is deposited from reduced, substantially magmatic fluid, which is characterized by close to mantle values δ34S = 0 ± 1‰, δ13C =–6 to–7‰, and δ18O = +5‰ as the temperature decreases from 420–300°C (gold–sulfide ore) to 250–130°C (gold–(sulfide)–quartz ore) and pressure decreases from 0.8 to 0.3 kbar. According to the data of microanalysis (EPMA and LA-ICP-MS), the main trace elements in pyrite of gold orebodies are represented by Co (up to 2.52 wt %), As (up to 0.70 wt %), and Ni (up to 0.38 wt %); Te, Se, Ag, Au, Bi, Sb, and Sn also occur. Pyrite of the early assemblages is characterized by high Co, Te, Au, and Bi contents, whereas the late pyrite is distinguished by elevated concentrations of As (up to 0.7 wt %), Ni (up to 0.38 wt %), Se (223 ppm), Ag (up to 111 ppm), and Sn (4.4 ppm). The minimal Au content in pyrite of the late quartz–carbonate assemblage is up to 1.7 ppm and geometric average is 0.3 ppm. The significant correlation between Au and As (furthermore, negative–0.6) in pyrite from ore of the Petropavlovskoe deposit is recorded only for the gold–sulfide assemblage, whereas it is not established for other assemblages. Pyrite with higher As concentration (up to 0.7 wt %) is distinguished only for the Au–Te mineral assemblage. Taking into account structural–morphological and mineralogical–geochemical features, the ore–magmatic system of the Petropavlovskoe deposit is referred to as gold porphyry style. Among the main criteria of such typification are the spatial association of orebodies with bodies of subvolcanic porphyry-like intrusive phases at the roof of large multiphase pluton; the stockwork-like morphology of gold orebodies; 3D character of ore–alteration zoning and distribution of ore components; geochemical association of gold with Ag, W, Mo, Cu, As, Te, and Bi; and predominant finely dispersed submicroscopic gold in ore. 相似文献
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吉林省小石人金矿区微量元素地球化学特征 总被引:3,自引:0,他引:3
以吉林省小石人金矿区内不同类型岩(矿)石微量元素测试结果为基础,从数据结构和空间结构两方面,对微量元素的地球化学特征进行探讨。统计参数表明:所观测元素在矿区内具有明显的浓集、富集特点,在不同类型岩(矿)石中元素的分布分配也不尽相同。依据分布分配特点,可将矿区内的岩(矿)石分为正常岩石、弱蚀变岩石和强蚀变/矿化岩石3类。多元统计分析成果揭示:所观测元素都参与了金的成矿活动,但行为特点有所差异。依据多元统计特征,可将微量元素分为3个组合类型:Au、As、Sb、Bi、Hg、Mn,Cu、Pb、Zn、Ag,Co、Ni、V;第一组合为成矿成晕组合,第二组合为金的多金属矿化组合,第三组合为黄铁矿化蚀变组合;元素组合也对应于不同的矿化阶段,指示金的成矿活动及特征。土壤、岩石地化剖面显示所观测的元素间存在空间相关性,但Mn与Au相异,其异常出现在矿化蚀变带的外侧。 相似文献
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为预测和评价那仁陶勒盖金矿的成矿潜力,运用多元统计方法,结合地球化学各参数信息,对那仁陶勒盖金矿原生晕进行系统研究.结果显示:那仁陶勒盖金矿赋矿花岗闪长岩中Au、Ag、Bi等元素浓集克拉克值明显偏高,与那仁陶勒盖金成矿作用关系密切;矿石中Au与Sb、Cu、Pb、Ag、Hg、Zn、As、Bi等关系最为密切;矿体原生晕轴向分带序列出现尾晕元素W、Sn等与前缘晕元素As叠加的现象,同时(As+Sb)/(Bi+Mo)、100Sb/(Bi·Mo)等分带性指数出现转折,指示深部存在盲矿体.依据上述矿体原生晕特征,建立矿体叠加晕预测模型,预测盲矿体赋存位置在海拔710m以下的岩体与地层接触带附近. 相似文献
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槐树坪金矿床位于河南省洛阳市嵩县境内,是豫西熊耳山地区近年来新发现的大型金矿床。本次研究对槐树坪金矿区地表及井下不同类型的较新鲜围岩、蚀变岩和矿石以及地表1∶20000面积性土壤采样,分析29项微量元素,从岩石和土壤两种采样介质来确定槐树坪金矿床的地球化学找矿指示元素。一方面基于较新鲜围岩的元素含量特征确定每个微量元素在该区岩石中的异常下限,进而分别计算了蚀变岩和矿石中微量元素平均含量与异常下限的比值,即异常衬度。按照异常衬度大于1.4的标尺确定了蚀变岩与矿石中明显富集的微量元素组合。另一方面,基于Au与28项微量元素在较新鲜围岩、蚀变岩、矿石三种介质中含量关系散点图直观确定了指示金成矿的微量元素组合。综合二者确定出槐树坪金矿区岩石地球化学找矿的指示元素组合为Au、Ag、As、Sb、Hg、Sn、Mo、Bi、Cu、Pb、Zn、Cd、Nb计13项。针对地表1∶20000面积性土壤调查,采用上述岩石中异常衬度为1.4作为土壤异常下限绘制了槐树坪金矿区微量元素的地球化学异常剖析图,以槐树坪金矿区已探明鸡公山一带的主成矿段为模型确定了土壤地球化学找矿的指示元素组合为Au、Ag、As、Sb、Hg、Bi、Cu、Pb、Zn、Cd、B计11项。综合上述结果认为在找矿指示元素组合方面土壤对岩石具有明显的继承性。基于岩石与土壤介质中共同的10项找矿指示元素,构建了归一化的综合异常指标,以鸡公山矿段为标准对整个槐树坪矿区进行了综合评价,发现槐树坪矿区内马蹄沟、秦佛爷沟、姜疙瘩和天坪西4处具有类似鸡公山矿段的找矿潜力。 相似文献
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莅香洼金矿发育有与金矿关系密切的地球化学异常,Au及相关元素的平均含量从安山岩→蚀变安山岩→蚀变岩→矿化蚀变岩呈几何级数递增。沿F985构造蚀变带走向,Pb、Ag与Au的组合异常通常与金的矿体晕分布一致,而As、Sb组合则更多反映了矿体前缘晕的组合特点,沿倾向,Au及相关元素自浅而深具有分段富集特征,并在1023m标高和976m标高构成二个浓集中心。其理想的元素轴向分带序列为:前缘晕As、Sb—Ba,矿体晕Au、Ag、Pb、Zn、Cu、Mo,矿尾晕(Cu、Mo)-(Co、Ni、Bi)。文章在前人研究的基础上,系统总结了莅香洼金矿床的地球化学特征,总结了构造蚀变岩型金矿床的地球化学找矿标志,建立了萑香洼金矿床的地球化学找矿模型。 相似文献
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新疆富蕴县希勒库都克钼铜矿床地球化学特征 总被引:1,自引:0,他引:1
通过对希勒库都克钼铜矿床的矿床地质、矿区地层、岩浆岩微量元素含量特征进行研究,认为下石炭统南明水组上亚组地层富集成矿元素,为矿区的主要含矿层位,该地层中强蚀变砂岩、凝灰质粉砂岩的成矿元素含量较高,为矿区的主要赋矿围岩。岩浆岩中成矿元素及主要伴生元素的含量特征显示,海西中晚期侵入的花岗闪长岩、花岗闪长斑岩和闪长斑岩(玢岩)与成矿作用密切,可能直接或间接提供了成矿物质来源。矿床在水平和垂直方向上均具有良好的分带特征,水平上由矿床中心向外呈现Mo、Cu(Au)、→V、Ti、Co、Cr、Ni、Mn、As、Sb、Hg、W、Sn、Bi→Ag、Zn、B、F的分带特征,垂向上自上而下呈现F、B、As(Cr、Ni)→Au、Cu、W(Mo、V、Co、Bi)→Mn(Au、V、Bi、Mo)的分带特征,对指导找矿具有一定意义。 相似文献
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《Russian Geology and Geophysics》2015,56(3):435-445
The spatial coexistence and synchronous formation of magmatogene porphyry Cu–Mo mineralization and epithermal gold mineralization are due to the genetic relationship between their formation processes. This relationship might be due to the generation of metal-bearing fluids of different geochemical compositions by the porphyry ore-magmatic system, which then participate in the formation of magmatogene porphyry Cu–Mo(Au) and associated epithermal gold deposits. Synthesis of fluid inclusions in quartz was performed for experimental study of the behavior of Cu, Mo, W, Sn, Au, As, Sb, Te, Ag, and Bi in heterophase fluids similar in composition and aggregate state to natural ore-forming fluids of porphyry Cu–Mo(Au) deposits. We have established that at 700 °C, a pressure decrease from 117 to 106 MPa leads to a significant enrichment of the gas phase of heterophase chloride fluid with Au, As, Sb, and Bi. The heterophase state of carbonate–chloride–sulfate fluids is observed at 600 °C and 100–90 MPa. It characterizes the highly concentrated liquid carbonate–sulfide phase–liquid chloride phase–low-density gas phase equilibrium. A decrease in the pressure of heterophase carbonate–chloride–sulfate fluid leads to a noticeable enrichment of its chloride phase with Cu, Mo, Fe, W, Ag, Sn, Sb, and Zn relative to the carbonate–sulfate phase. The processes of redistribution of ore elements between the phases of heterophase fluids can be considered a model of generation of metal-bearing chloride fluids, which occurs in nature during the formation of porphyry Cu–Mo(Au) deposits, as well as a model of generation of gas fluids supplying Au, Te, As, and other ore elements to the place of formation of epithermal Au–Cu and Au–Ag mineralization.© 2015, V.S. Sobolev IGM, Siberian Branch of the RAS. Published by Elsevier B.V. All rights reserved. 相似文献
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New data on platinum mineralization in ores, metasomatic rocks, concentrates, and tailings and wastes of some gold–polymetallic, Au–Bi, Cu–Mo porphyry, Cu–Ni, and titanomagnetite ore deposits and occurrences of the Upper Amur Region are presented. The contents of platinoids, Au and Ag in multimetal ores of gold-polymetallic, Au–Bi, Cu–Mo porphyry, Cu–Ni, and titanomagnetite ore deposits and ore occurrences are given. In addition, recommendations on the necessity of continuing scientific studies, revision, and resampling works in the search for platinoids in other complex ores of deposits and occurrences of the Upper Amur Region are given. 相似文献
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The geochemical zoning of the Rogovik epithermal deposit in northeast Russia has been established on the basis of endogenic anomalous geochemical fields (AGCF) of Au–Ag zones, their qualitative and quantitative compositions, and spatial distribution of chemical element indicators of Au–Ag mineralization. The obtained geochemical data (monoelemental AGCF, associations of elements, their composition, contrast, and correlation) allowed us to estimate the erosion level of Au–Ag ore zones. It has been shown that AGCF related to Au–Ag mineralization are distinguished by simple component composition (Au, Ag, Hg, Sb, As, Cu, Pb, Zn) and regular spatial distribution of the elements. It has been established that the least eroded central part of the object is characterized by widespread and the most contrasting Au, Ag, Hg, Sb, and As AGCF closely related to the ore-bearing units of the deposit. The contrast of these fields gradually decreases with depth. Low-contrast Cu, Pb, and Zn AGCF typical of the footwall depth intervals and flanks of Au–Ag zones intervals appear at depth. The northern part of the area is eroded to the deepest level. The contrast of Ag, Hg, Sb, and As geochemical fields abruptly decreases here, and Cu, Pb, and Zn AGCF become widespread with depth. The relatively contrasting fields of anomalous Au concentrations develop here extremely locally and near the surface. It has been concluded that the as yet poorly explored southern part of the Rogovik deposit most likely is promising for further geological exploration and the discovery of new mineralized areas. 相似文献
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《Russian Geology and Geophysics》2015,56(10):1367-1383
New data on the mineral composition and the first data on the geochemical composition of ores of the Rogovik gold-silver deposit (Omsukchan ore district, northeastern Russia) have been obtained. Study of the regularities of the spatial distribution of ore mineralization shows that the deposit ores formed in two stages. Epithermal Au-Ag ores of typical poor mineral and elemental compositions were generated at the early volcanic stage. The major minerals are low-fineness native gold, electrum, acanthite, silver sulfosalts, kustelite, and pyrite. The typomorphic elemental composition of ores is as follows: Au, Ag, Sb, As, Se, and Hg. The content of S is low, mostly < 1%. Silver ores of more complex mineral and elemental compositions were produced under the impact of granitoid intrusion at the late volcanoplutonic stage. The major minerals are high-Hg kustelite and native silver, silver sulfosalts and selenides, fahlore, pyrite, chalcopyrite, galena, and sphalerite. The typomorphic elemental composition of ores is as follows: Ag, As, Sb, Se, Hg, Pb, Zn, Cu, and B. The content of S is much higher than 1%. The ores also have elevated contents of Mo, Ge, F, and LREE (La, Ce, and Nd). At the volcanoplutonic stage, polychronous Au-Ag ores formed at the sites of the coexistence of silver and epithermal gold-silver mineralization. Their specific feature is a multicomponent composition and a strong variability in chemical composition (both qualitative and quantitative). Along with the above minerals, the ores contain high-Hg gold, hessite, argyrodite, canfieldite, orthite, fluorapatite, and arsenopyrite. At the sites with strongly rejuvenated rocks, the ores are strongly enriched in Au, Ag, Hg, Cu, Pb, Zn, Ge, Se, La, Ce, Nd, S, and F and also contain Te and Bi. The hypothesis is put forward that the late silver ores belong to the Ag-complex-metal association widespread in the Omsukchan ore district. A close relationship between the ores of different types and their zonal spatial distribution have been established. In the central part of the Rogovik deposit, epithermal Au-Ag ores are widespread in the upper horizons, Ag ores are localized in the middle horizons, and rejuvenated polyassociation Au-Ag ores occur at the sites (mostly deep-seated) with ore-bearing structures of different ages. 相似文献
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在胶东莱州吴一村地区完成的3266.06 m深钻,是目前焦家金成矿带最深见矿钻孔,研究钻孔揭露的深部矿石中金矿物及黄铁矿微量元素特征,对探讨深部成矿作用演化具有重要意义。笔者采取深钻中2420~3206 m垂深的岩(矿)芯样品进行了详细的岩相学和矿相学研究,结合扫描电镜和电子探针微区分析,研究了矿石中金矿物的赋存状态和成分。对不同成矿阶段形成的黄铁矿进行了LA-ICPMS微量元素分析。研究结果表明,深部矿石中载金矿物主要为黄铁矿,其次为石英、黄铜矿、方铅矿,可见金主要以自然金和银金矿的形式存在,以晶隙金和裂隙金为主,其次为包体金。与浅部金矿床比较,深部金的成色较高。黄铁矿分为6种类型,第Ⅰ成矿阶段形成富Co型黄铁矿Py1,第Ⅱ成矿阶段形成富Ni型黄铁矿Py2a和Py2b,第Ⅲ成矿阶段形成富Au、As型黄铁矿Py3a和富Au、Ag、Pb、Bi型黄铁矿Py3b,第Ⅳ成矿阶段形成贫微量元素黄铁矿Py4。其中,Py1和Py2a发生强烈破碎,裂隙表面对热液中的Au络合物产生吸附作用,对金沉淀富集起重要作用。黄铁矿中Co、Ni、As等微量元素主要以类质同象形式赋存,而Au、Ag、Cu、Pb、Zn、Bi等主要以纳米级、微米级矿物包体形式赋存。Pb+Bi、Cu+Pb+Zn、Te+Bi与Au+Ag呈明显正相关,而Au与As相关性较差。黄铁矿中Co、Ni含量较低,而Au+Ag+As或Au+Ag+Pb+Bi+Cu含量较高指示成矿有利。另外,黄铁矿中Co、Ni含量较高,并且破碎强烈,成矿相关元素含量较高也指示成矿有利。 相似文献
18.
五台山—恒山绿岩带Au、Ag、Cu矿床可分为二大类型:(1)再生型金银铜矿,产在包括岩浆岩在内的各类岩石断裂构造中,与岩浆期后热液有关;(2)变生型金银铜矿,产于各类变质岩中,具有层控特征(即绿岩型金矿)。在地球化学特征上,再生型矿床与变生型矿床相比,矿体及围岩中Mo、Ag、Pb、Zn、Cd等成矿及伴生元素明显富集;K2O、Rb、Sr、Ba、Th、U也明显富集,是后期岩浆热液作用的结果;Hg、F的明显富集则与后期构造活动有关;Zn/Cd比值较低,说明受到后期岩浆侵入影响;Th/U比值低,可能指示富钙的酸性岩环境。再生型Au矿化的元素组合为Cd、As、Ni、Ag、Sb、Au、Hg(Bi),再生型Ag矿化的元素组合为As、Sb、Ag、Cd、Cu、Ni(Mo、Pb、Zn、Bi),变生型Au矿化的元素组合较简单,只为Au、Hg、As或Au、Cu。上述地球化学特征不仅可以有效地区分矿化类型,而且可以作为地球化学找矿和评价的指标 相似文献
19.
A. V. Volkov V. Yu. Prokofiev E. E. Tyukova V. A. Sidorov K. Yu. Murashov N. V. Sidorova M. A. Zemskova 《Geology of Ore Deposits》2017,59(2):112-130
This paper is focused on the new data for geology, mineralogy, and geochemistry of stockworks consisting of steep and gentle quartz veins and veinlets forming a complex multilevel structure at the Rodion deposit. These stockworks range from 25 to 150 m in thickness. Average gold grade is 1.8 g/t. Ore minerals pyrite, arsenopyrite, chalcopyrite, sphalerite, galena, and native gold are predominantly concentrated on the vein and veinlet walls. Thermal metamorphism caused by the intrusion of the Ulakhan granodiorite pluton is the important singularity of the deposit. The deposit ore is enriched in chalcophile microelements Au, Ag, As, Sb, Cu, Pb, Zn, and Bi as compared to the average composition of the upper crust and hosting Permian sequences. The enrichment factors range from a few to hundreds of times. Bi, W, Pb, Ag, and Na2O are positively correlated between each other and with Au. The highest correlation coefficient 0.59 is between Au and Bi. Au is negatively correlated with Ba, Li, Co, Ni, Mn, Ti, and Be. The stockwork ores were formed involving homogeneous low-saline (9.4–4.3 wt % NaCl equiv) substantially aqueous bicarbonate-chloride fluid at 275–330°C and 300–1840 bar fluid pressure. Fluid has a high concentration of CO2 (up to 349 g/kg of water) and is reductive (СО2/СН4 = 17–37.3). Na and Ca are the major cations in the fluid, whereas K and Mg are minor. In addition, many microelements were detected in the fluid: As, Li, Rb, Cs, Mo, Ag, Sb, Cu, Zn, Cd, Pb, U, Ga, Ge, Ti, Mn, Fe, Co, Ni, V, Cr, Y, Zr, Sn, Ba, W, Au, Hg, and REE. The results obtained are consistent with the metamorphic–magmatic formation model of orogenic gold–quartz deposits within the Yana–Kolyma belt. 相似文献
20.
《Russian Geology and Geophysics》2014,55(2):252-258
The mineral and geochemical compositions of noble-metal (first of all, gold) deposits of the Fennoscandian, Siberian, and Northeast Asian orogenic belts are considered. These deposits are of several types: Au (disseminated Au–sulfide and Au–quartz), Au–Bi, Au–Ag, Au–Sb, Ag–Sb, Au–Sb–Hg, and Ag–Hg. They formed in different geodynamic settings as a result of the active motion of crustal tectonic blocks of different nature. Subduction processes (both at the front and at the rear of continent-marginal and island-arc magmatic arcs) resulted in Au–Ag, Ag–Sb, Ag–Hg, Au–Sb–Hg, and Au–Bi deposits. Collision events gave rise to Au and Au–Bi deposits. Intraplate continental rifting and formation of orogenic belts along the boundaries of block (plate) sliding led to the origin of Au and Au–Bi ores in association with Au–Ag, Au–Sb–Hg, and complex ores. In all cases, the formation of noble-metal mineralization was accompanied by magmatism of different types and metamorphism. Because of this diversity of ores, there is no single concept of the genesis of noble-metal mineralization. Several competing models of genesis exist: hydrothermal-metamorphic, pluton-metamorphic, plutonic, activity of mantle fluid flows, and multistage concentration during the crust–mantle interaction with the leading role of sedimentary complexes. 相似文献