Study on the Metallogenic Chronology of the Gold Deposits in Jiaoliao Area

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Study on the Metallogenic Geochronology of the Jinchanggouliang Gold Deposit in Inner Mongolia

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Dual-source Metallogenic Mechanis: the Evidence from Magmatic Rocks in Eastern Guizhou

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Study on Iron-Copper-Gold Mineralization in the Truong Son Metallogenic Belt,Laos-Vietnam

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Geochemical Characteristics and Genesis of the Metallogenic Rocks in the Chagande’ersi Molybdenum Deposit in Wulatehouqi, Inner Mongolia

Geochemical characteristics of the Chagande’ersi molybdenum deposit in Inner Mongolia and its genesis were analyzed in this study using rock mineralography and rock geochemical testing. The mineralized country rocks of the Chagande’ersi molybdenum deposit consist mainly of medium-to fine-grained monzogranite,medium-to fine-grained rich-K granite,with minor fine-grained K-feldspar granite veins and quartz veins.The rocks are characterized by high silica,rich alkali,high potassium,which are favorable factors for molybdenum mineralization.The rocks have the Rittmann index ranging from 1.329 to 1.961,an average Na₂O+K₂O value of 7.41,and Al₂O₃/（CaO+Na₂O+K₂O）>1,suggesting that the rocks belong to the high-K calc-alkaline peraluminous granite.The typical rock samples are enriched in Rb,Th,K and light rare earth elements,depleted in Sr,Ba,Nb,P and Ti, and these features are similar to that of the melt granite resulting from collision of plate margins.TheδEu of the rocks falls the zone between the crust granite and crust-mantle granite,and are close to that of the crust granite;（La/Lu）_N indicates the formation environment of granite is a continental margin setting.The Nb/Ta ratios are close to that of the average crust（10）;the Zr/Hf ratios of monzogranite are partly below the mean mantle（34-60）,while the Zr/Hf ratio of K-feldspar granite are close to the mean value in the crust.Comprehensive analyses show that the granite in this area formed during the transition period between tectonic collision and post-collision.During the plate collision and orogeny,the crust and mantle material were mixed physically,remelting into lava and then crystal fractionation,finally gave rise to the formation of the rock body in this area.This has close spatial and temporal relation with the molybdenum mineralization.     

The Mineralization and Metallogenic Process of the Orogenic Gold Deposits in Ailaoshan, Yunnan

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“Structure-Lithologic-Fluid” Metallogenic Coupling of the Wuzhishan Lead-Zinc Deposit in Puding, Guizhou Province

<正>1 Introduction The Wuzhishan lead-zinc ore-concentrated area in Puding is located in the east of the Sichuan,Guizhou and Yunnan lead-zinc metallogenic domain,with the Youjiang-Nanpan River metallogenic province to the     

Geological Fluid Mapping in the Tongling Area： Implications for the Paleozoic Submarine Hydrothermal System in the Middle-Lower Yangtze Metallogenic Belt, East China

The Tongling area is one of the 7 ore-cluster areas in the Middle-Lower Yangtze metallogenic belt,East China,and has tectonically undergone a long-term geologic history from the late Paleozoic continental rifting,through the Middle Triassic continent-continent collision to the Jurassic-Cretaceous intracontinental tectono-magmatic activation.The Carboniferous sedimentary-exhalative processes in the area produced widespread massive sulfides with ages of 303-321 Ma,which partly formed massive pyrite-Cu deposits,but mostly provided significant sulfur and metals to the skarn Cu mineralization associated with the Yanshanian felsic intrusions. To understand the Carboniferous submarine hydrothermal system,an area of about 1046 km~2 was chosen to carry out the geological fluid mapping.Associated with massive sulfide formation,footwall sequences 948 m to 1146m thick,composed of the Lower Silurian-Upper Devonian sandstone,siltstone and thin-layered shale,were widely altered.This hydrothermal alteration is interpreted to reflect large- scale hydrothermal fluid flow associated with the late Paleozoic crustal rifting and subsidence.Three hydrothermal alteration types,i.e.,deep-level semiconformable silicification(S_1),fracture-controlled quartz-sericite-pyrite alteration(S_(2-3)),and upper-level sub-discordant quartz-sericite-chlorite alteration(D_3),were developed to form distinct zones in the mapped area.About 50-m thick semiconformable silicification zones are located at～1-km depth below massive sulfides and developed between an impermeable shale caprock(S_1)and the underlying Ordovician unaltered limestone. Comparisons with modern geothermal systems suggest that the alteration zones record a sub-seafloor aquifer with the most productive hydrothermal fluid flow.Fracture-controlled quartz-sericite-pyrite alteration formed transgressive zones,which downward crosscut the semiconformable alteration zones, and upwards grade into sub-discordant alteration zones that enveloped no economic stringer- stockwork zones beneath massive sulfides.This transgressive zone likely marks an upflow path of high- flux fluids from the hydrothermal aquifer.Lateral zonation of the sub-discordant alteration zones and their relationship to overlying massive sulfide lenses suggest lateral flows and diffusive discharging of the hydrothermal fluids in a permeable sandstone sequence.Three large-sized,14 middle-small massive sulfide deposits,and 40 massive sulfide sites have been mapped in detail.They show regional strata- bound characters and two major styles,i.e.,the layered sheet plus strata-bound stringer-style and the mound-style.Associated exhalite and chemical sedimentary rock suites include(1)anhydrite-barite,(2) jasper-chert,(3)Mg-rich mudstone-pyrite shale,(4)barite lens,(5)siderite-Fe-bearing dolomite,and (6)Mn-rich shale-mudstone,which usually comprise three sulfide-exhalite cyclic units in the area. The spatial distribution of these alteration zones(minerals)and associated massive sulfides and exhalites,and regional variation inδ~(34)S of hydrothermal pyrite and inδ~(18)O-δ~(34)C of hanging wall carbonates,suggest three WNW-extending domains of fluid flow,controlled by the basement faults and syn-depositional faults.Each fluid domain appears to have at least two upflow zones,with estimated even spacing of about 5-8 km in the mapped area.The repeated appearance of sulfide-sulfate or sulfide-carbonate rhythmic units in the area suggests episodically venting of fluids through the upflow conduits by breaking the overlying seals of the hydrothermal aquifer.     

Molybdenum Polymetallic Metallogenic Regularity and Metallogenic Prediction of the Jinduicheng-Huang Longpu Mineral Field,Shanxi Provice

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Analysis of Ore-controlling Factors of the Nongruri Gold Deposit in Gangdese Metallogenic Belt, Tibet

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Establishment of research methodology and workflow for the occurrence state of the critical metal cobalt in ore: A case study of the Longqiao cobalt -rich skarn iron deposit in the Luzhong BasinSCIEI北大核心CSCD

关键金属钴的赋存状态是研究关键金属成矿作用的核心问题之一。由于含钴矿物粒度较小,难以在矿床尺度查明关键金属矿物的种类、含量、粒度、分布特征以及与其他矿石矿物和脉石矿物的共生关系,因此亟需建立一套成本低且效率高的钴赋存状态研究流程。本次工作以龙桥铁矿床为例,建立了新的采样与制样流程,提高了样品的代表性,并大幅缩短了样品前处理与制样的时间。通过综合矿物分析技术(TIMA)分析,查明了不同钴含量的三类矿石样品中矿物的含量,在6个实验矿石样品中寻找到了辉砷钴矿、铁硫砷钴矿和硫铜钴矿三种钴矿物共753颗,并使用扫描电镜和能谱分析(SEM-EDS)对钴矿物进行了核验与半定量分析。最后,在同一个树脂靶上利用激光剥蚀-等离子体质谱仪(LA-ICP-MS)对磁铁矿和黄铁矿进行了原位点分析,进一步查明了样品中钴的赋存状态。本次研究建立了关键金属钴在矿石中赋存状态的研究方法和技术流程,具有制样简单便捷、分析时间短、分析费用低和分析精度高等诸多优点,为矿床尺度上关键金属空间分布规律和赋存状态研究提供了可靠的技术支撑。     

Chalcopyrite Intergrowths in sphalerite in the Meixian Lead—Zine Deposit,Fujian Province and their Metallogenic Significance

Ore textures and electron microprobe analyses show that in addition to highly scattered blebs in sphalerite grains,intergrown chalcopyrite also occurs as rods,myrmekites and lamellae aligned along cleavages and twin boundaries of the host sphalerite.The majority of the intergrowths could have been formed by replacement of sphalerite by chalcopyrite,albeit part of them may have resulted from exsolution,Not only copper,but also iron were introduced into the sphalerite by replacive fluids.While the front of the replacing fluid was moving forward through a sulphide orebody,Zn and Pb were dissolved and Cu was precipitated,resulting in zonal refining of the sulphide ores,The remobilized zinc and lead were precipitated at favourable sites with changed physico-chemical conditions .This is a possible mechanism for the formation of copper-poor zinc and lead ores above or lateral to the copper orebodies in some of the massive sulphide deposits reworked and overprinted by late-stage granites and their hydrothermal fluids.     

Composite Metallogenic Systems in the Weihai Area of Shandong and Evolution of Continental Dynamic Regimes

Based on 9 sheets of 1：50,000-scale regional geological survey and guided by the theory of metallogenic systems and integrated analyses of the structural and metallogenic features, this paper hereby puts forward the composite metallogenic systems of the Weihai area, Shandong Province, aiming at solving the problems on the origins and ore-controlling structures of the numerous deposits in the area. Its scientific significance is reflected in the following three aspects： （1） The basic features of the composite metallogenic systems can be recognized, which consist of two types： the Proterozoic metamorphic-hydrothermal metallogenic system and the Mesozoic magmatic-hydrothermal metallogenic system （i.e. the Indosinian-early Yanshanian contact metasomatic metallogenic series and the mid-late Yanshanian magmatic-hydrothermal metallogenic series）. The two series display arcuate and NW-right lateral arrangements and a N-S parallel zonal distribution respectively, with the corresponding mineral assemblages being Au＋Ag＋Pb＋Zn, etc.; and Cu＋Mo＋Fe, Au＋Ag＋Cu＋Pb- Zn＋Mo＋Co-Ni＋sulfides＋silicides＋K-feldspar, etc. （2） The composite metallogenic systems may be used to interpret the complicated genetic relations of the deposits. Through analyses of the relations between the three main metallogenic intervals and their corresponding source rock series （the Jingshan and Rongcheng groups; the Wendong super-unit and the early-middle Yanshanian Weideshan super-unit; and the mid-late Yanshanian Weideshan and Laoshan super-units） as well as a case study of the Fanjiabu gold deposit, we have distinguished the consanguinity between the contact metasomatic （skarn-type） metallogenic series and the magmatic-hydrothermal metallogenic series as well as the noncognate superposition between the two and the metamorphic-hydrothermal metallogenic system. （3） The composite metallogenic systems are easily related to the evolution of continental dynamic regimes. The formation of the metamorphic-hydrothermal metallogenic system has undergone transformations of three different types of tectono-dynamic regimes from extension→compression→ shearing; that of the contact metasomatic （skarn-type） metallogenic system from compression→extension→compression; and that of the magmatic-hydrothermal metallogenic system from extension →subductive compression of the Pacific Plate. The evolutions of the three types are all attributed to the opening-closing or divergence-convergence of the paleocontinent, and all their mineralization corresponds to the interval of transformation from the end of convergence to early integration of the Weihai paleocontinent. All these will benefit our deeper study of the dynamics of continental metallogenic processes.     

Geochemical Constraints on Genesis of the Xinqiao Cu-Au-S-Fe Deposit in the Tongling Ore-Cluster Field, Middle-Lower Yangtze Metallogenic Belt

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Metallogenic Response of Ailaoshan Gold Belt in Indosinian Orogeny

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Overview of Metallogenic Regularity of Copper in Northwest China

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Discussion on the Geological Characteristics and Metallogenic Mechanism of the Gold and Silver Deposits in the Linjiasandaogou-Xiaotongjiapuzi Ore-Concentrated Area, Eastern Liaoning

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The Role of Evaporites in the Genesis of the Jinshandian Skarn Fe Deposit in the Edong District, Middle–Lower Yangtze River Metallogenic Belt, China

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The Yanshannian Porphyry Mo-Pollymetallic Metallogenic Belt on the Western Margin of Yangtze Craton in Southwest China

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Discrimination Study on Fluid—Rock Interaction Between Metallogenic and Non—Metallogenic Sections in a Shear Zone

Discriminations in a local chemical,fluidal,mechanical and thermal processes in a shear zone will lead to metallogenic differentiation in a local section.This paper,based on the general geological setting of the Shibangou gold deposit in Xixia,Henan,deals with petrological and petrochemical samples of altered rocks in the metallogenic section and of mylonites in the non-metallogenic section of a selected shear zone.The discriminations in fluid-rock interaction and petrological mass balance between altered rocks near the orebody and mylonites in the shear zone are discussed as well.The results show that the petrological volume of altered rocks in the metallogenic section of the shear zone is almost always dilatant and the mylonite volume in the non-metallogenic section is almost always lost.Major elements in altered rocks from the metallogenic section and in mylonites from the non-metallogenic section always show a tendency of being enriched and depleted,respectively.Fluid-rock ratios in the mylonites(Nu=93.68-468.40)are larger than those of the altered rocks(NC(Ⅳ）^s=36.11-216.67).The gain and loss of major and trace elements from the altered rocks and mylonites in the shear zone are a composite process to be imported and exported by percolating fluids as well as of the loss and dilatancy of rock volume.