Geology and mineralization of the Tiegelongnan supergiant porphyry-epithermal Cu(Au, Ag) deposit(10 Mt) in western Tibet, China: A review

The Tiegelongnan Cu(Au,Ag)deposit in central Tibet contains more than 10 Mt of copper ranking 29 th in the world.It is characterized by typical porphyry-epithermal alteration and mineralization.In order to improve the understanding of porphyry-epithermal copper deposit in Tibet,new zircon U-Pb age and sulfur isotope data along with published data in the Tiegelongnan are presented to investigate the formation and preservation mechanism.Ore-related intrusive rocks in the Tiegelongnan including Early Cretaceous(about 120 Ma)granodiorite porphyry and diorite porphyry are closely related to the northward subduction of Bangongco-Nujiang ocean.Sulfur mainly comes from deep magma,and ore-forming fluid is affected by both magmatic and meteoric water.The metallogenic setting of Tiegelongnan is consistent with those of Andean porphyry copper deposits in South America.The cover of the Meiriqiecuo Formation volcanic rocks,Lhasa-Qiangtang collision and India-Eurasian collision have significance in the preservation and uplift of the deposit.The formation,preservation and discovery of Tiegelongnan play an important role in exploration of ancient porphyry-epithermal deposits in Tibet.

Chronology of the Tungsten Deposits in Southern Jiangxi Province, and Episodes and Zonation of the Regional W-Sn Mineralization-Evidence from High-precision Zircon U-Pb, Molybdenite Re-Os and Muscovite Ar-Ar Ages

Previous studies have obtained some petrogenetic and metallogenic chronological data with SHRIMP （sensitive high-resolution ion microprobe） zircon U-Pb, zircon LA-ICPMS （laser-ablation-inductively coupled plasma mass spectroscopy） U-Pb, molybdenite Re-Os isochron and muscovite Ar-Ar methods in southern Jiangxi Province and its adjacent areas. Based on these, the purpose of this paper is to study the petrogenetic and metallogenic ages and their time gap for different genetic types of W-Sn deposits, and thus to research their numerous episodes, zonal arrangement and their geodynamic background. The result shows that the large-scale W-Sn mineralization in southern Jiangxi Province occurred in the middle to late Jurassic （170-150 Ma）, the skarn W-Sn-polymetallic deposits formed much earlier （170-161 Ma）, and all of the wolframite-quartz vein type, greisen type, altered granite type and fractured zone type tungsten deposits formed in the late Jurassic （160-150 Ma）. In one ore field or ore district, greisen type tungsten deposits formed earlier than quartz vein type ones hosted in the endoor exo-contact zone; and quartz vein type hosted in the endocontact zone formed earlier than that of exocontact zone. There is no significant time difference between tungstentin mineralization and its intimately associated parent granite emplacement （1-6 Ma）. They all formed in the same rock-forming and ore-forming system and under the same geodynamic setting. Regionally, rock-forming and ore-forming processes of the W-Sn deposits in the Nanling region （include southern Jiangxi Province, southern Hunan Province, northern Guangdong Province and eastern Guangxi Zhuang Autonomous Region） exhibit numerous episodes. The mineralization in the Nanling region mainly occurred at （240-210） Ma, （170-150） Ma and （130-90） Ma. The tungsten-tin deposits in this region are centered by the largest scale in southern Jiangxi Province and southern Hunan Province, and become small in the east, west, south and north directions. This displays a zonal arrangement and temporal and spatial distribution regularity. Integrated with the latest research results, it is concluded that the W-Sn mineralization in southern Jiangxi Province and its adjacent areas corresponds to the second large-scale mineralization in South China. The Indosinian W-Sn mineralization formed under the extensional tectonic regime between collisional compressional stages, while the Yanshanian large-scale petrogenetic and metallogenic processes occurred in the Jurassic intraplate extensional geodynamic setting of lithosphere extension.

Zircon U-Pb-Hf Isotopic Systematics and Geochemistry of the Granites in the Wurinitu Molybdenum Deposit, Inner Mongolia, China： Implications for Tectonic Setting and Genetic Type of Mineralization

The Wurinitu Mo deposit is one of the newly found molybdenum deposits in the southwestern part of the late Paleozoic–Mesozoic Erenhot–Dong-Ujimqin metallogenic belt （S-EDMB）, Inner Mongolia, China. In the present study, the mineralization age of the Wurinitu deposit is constrained to 137.3 ± 1.3 to 131.9 ± 1.5 Ma based on a combination of the laser ablation–inductively coupled plasma–mass spectrometry （LA–ICP–MS） zircon U–Pb dating of the mineralization related fine-grained monzonitic granite and the post-mineralization granite porphyry. The results of zircon Lu–Hf isotopes, combined with the geochemical characteristics of the granites in the S-EDMB, suggest that the Wurinitu Mo deposit was formed in an extensional environment in relation to the subduction of the Paleo-Pacific plate in late Mesozoic. The Wurinitu deposit shares similarities with the classical Climax-type porphyry molybdenum deposits in tectonic setting, mineral assemblages, and metal zonation.

Evolution of the magmatic–hydrothermal system and formation of the giant Zhuxi W–Cu deposit in South China

The Zhuxi deposit is a recently discovered W–Cu deposit located in the Jiangnan porphyry–skarn W belt in South China. The deposit has a resource of 3.44 million tonnes of WO3, making it the largest on Earth,however its origin and the evolution of its magmatic–hydrothermal system remain unclear, largely because alteration–mineralization types in this giant deposit have been less well-studied, apart from a study of the calcic skarn orebodies. The different types of mineralization can be classified into magnesian skarn, calcic skarn, and scheelite–quartz–muscovite(SQM) vein types. Field investigations and mineralogical analyses show that the magnesian skarn hosted by dolomitic limestone is characterized by garnet of the grossular–pyralspite(pyrope, almandine, and spessartine) series, diopside, serpentine,and Mg-rich chlorite. The calcic skarn hosted by limestone is characterized by garnet of the grossular–andradite series, hedenbergite, wollastonite, epidote, and Fe-rich chlorite. The SQM veins host highgrade W–Cu mineralization and have overprinted the magnesian and calcic skarn orebodies. Scheelite is intergrown with hydrous silicates in the retrograde skarn, or occurs with quartz, chalcopyrite, sulfide minerals, fluorite, and muscovite in the SQM veins.Fluid inclusion investigations of the gangue and ore minerals revealed the evolution of the ore-forming fluids, which involved:(1) melt and coexisting high–moderate-salinity, high-temperature, high-pressure(>450 ℃and >1.68 kbar), methane-bearing aqueous fluids that were trapped in prograde skarn minerals;(2) moderate–low-salinity, moderate-temperature, moderate-pressure(~210–300 ℃and ~0.64 kbar),methane-rich aqueous fluids that formed the retrograde skarn-type W orebodies;(3) low-salinity,moderate–low-temperature, moderate-pressure(~150–240 ℃and ~0.56 kbar), methane-rich aqueous fluids that formed the quartz–sulfide Cu(–W) orebodies in skarn;(4) moderate–low-salinity,moderate-temperature, low-pressure(~150–250 ℃and ~0.34 kbar) alkanes-dominated aqueous fluids in the SQM vein stage, which led to the formation of high-grade W–Cu orebodies. The S–Pb isotopic compositions of the sulfides suggest that the ore-forming materials were mainly derived from magma generated by crustal anatexis, with minor addition of a mantle component. The H–O isotopic compositions of quartz and scheelite indicate that the ore-forming fluids originated mainly from magmatic water with later addition of meteoric water. The C–O isotopic compositions of calcite indicate that the ore-forming fluid was originally derived from granitic magma, and then mixed with reduced fluid exsolved from local carbonate strata. Depressurization and resultant fluid boiling were key to precipitation of W in the retrograde skarn stage. Mixing of residual fluid with meteoric water led to a decrease in fluid salinity and Cu(–W) mineralization in the quartz–sulfide stage in skarn. The high-grade W–Cu mineralization in the SQM veins formed by multiple mechanisms, including fracturing, and fluid immiscibility, boiling, and mixing.

Giant Mineral Deposits and Their Geodynamic Setting in the Lanping Basin, Yunnan, China

There are giant mineral deposits, including the Jinding Zn-Pb and Baiyangping Ag-Co-Cu, and otherimportant mineral deposits (e.g., Baiyangchang Ag-Cu, Jinman Cu deposits, etc.) in the Lanping Mesozoic-Cenozoic Basin, Yunnan Province, China. The tabular ore-bodies and some veins hosted in terrestrial clastic rocks of the Mesozoic-Cenozoic age and no outcropping of igneous rocks in the giant deposits lead to the proposal of syngenetic origin, but the giant mineral deposits are not stratabound (e.g. MVT, sandstone- and Sedex-type). They formed in a continental red basin with intense crust movement. The mineralization is controlled by structures and lithology and occurs in different strata, and no sedimentary nature and no exhalative sediments are identified in the deposits. The deposits show some relations with organic matter (now asphalt and petroleum) and evaporates (gypsum). The middle-low-temperature (mainly 110℃ to 280℃) mineralization took place at a depth of about 0.9 km to 3.1 km during the early Himalayan (58 to 67 Ma). The salinity of ore-forming fluids is surprisingly low (1.6% to 18.0 wt% (NaCl)eq). Affected by the collision of the Indian and Eurasian plates, the mantle is disturbed under the Lanping Basin. The large-scale mineralization is closely linked with the geodynamics of the crust movement, the mantle and mantle-flux upwelling and igneous activity. Giant mineral deposits and their geodynamic setting are unique in the Lanping Basin.

Integration of Deep-time Digital Data for Mapping Clusters of Porphyry Copper Mineral Deposits

1 Introduction PCDs are generated in continental arcs in response to plate converging processes(subduction and collision)(Hou et al.,2009;Richards,2013).It is generally accepted that the formation of PCDs is associated with igneous activities either originating from lower crust or upper mantle,with contributions of crusts during the evolution of continental lithosphere.

Large clusters of gold deposits and large-scale metallogenesis in the Jiaodong Peninsula, Eastern China

The Jiaodong Peninsula is the largest repository of gold in China based on the production in history. It covers less than 0.2% of China's territory, but production of gold accounts for about one fourth of the whole country. Thus, the Jiaodong Peninsula is a typical area or case of large-scale metallogenesis and a large clusters of mineral deposits in China. It is characterized by the large clusters of gold deposits in large scale, high reserve and short mineralizing stage. In this study, we suggest that the eastern boundary of the large clusters of gold deposits is as same as that of North China Block, the gold deposits are hosted by Archean metamorphic rocks or Mesozoic granites, and the age of gold mineralization is 121.6 to 122.7 Ma. Gold and related ore-forming materials are derived from multisources, i.e. Archean metamorphic rocks, granites and intermediate-mafic dikes, especially, intermediate-mafic dikes and calc-alkaline granites. The metallogenic geodynamic process is constrained by the tectonic evolution of eastern North China Block during Late Mesozoic, and it is the result of the interaction between mantle and crust as the boundary plates are playing role on the block.

赣南兴国县张家地钼钨矿床成岩成矿时代及地质意义

地处EW向南岭成矿带和NE向武夷山成矿带叠置部位的赣南兴国-宁都钨锡矿集区产有多处不同矿化类型的钨锡多金属矿床,但总体研究程度较低。本文基于详细野外地质调查,重点开展了张家地钼钨矿床的高精度成岩成矿年代学研究,并探讨了区域钨锡矿床成岩成矿时空分布及地球动力学背景。张家地钼钨矿化产于花岗岩与震旦纪浅变质细碎屑岩的内、外接触带,包括石英脉型（王泥排矿段）和云英岩型（刘家庄矿段）两种矿化类型。利用SHRIMP锆石U-Pb法,获得张家地钼钨矿区似斑状中细粒黑云母花岗岩的年龄为154.1±1.8Ma;利用辉钼矿Re-Os法,获得王泥排矿段石英脉型矿体的辉钼矿Re-Os等时线年龄为158.4±3.1Ma、加权平均年龄为157.7±1.4Ma,刘家庄矿段云英岩型矿体的辉钼矿Re-Os等时线年龄为161.9±3.2Ma、加权平均年龄为157.9±1.6Ma,厘定矿床成岩成矿时代为晚侏罗世,对应于华南中生代第二次大规模成矿作用。石英脉型和云英岩型矿体中辉钼矿的铼含量均较低（9.58×10-6～22.65×10-6）,表明成矿物质以壳源为主;综合分析区域最新年代学数据资料,表明钨锡矿床成岩成矿具多期性,主要集中在240～210Ma、170～150Ma和130～90Ma,以赣南和湘南为中心,钨锡矿床向四周成矿年龄均呈变小趋势。燕山期钨锡大规模成岩成矿作用主要形成于华南中生代岩石圈伸展-减薄时期的侏罗纪板内拉张的地球动力学背景。

埃达克质岩的金属成矿作用

介绍了"埃达克质岩"的术语、与成矿有关的埃达克质岩的分布、成矿背景,讨论了埃达克质岩有利于成矿的控制因素。"埃达克质岩"是指那些具有与俯冲洋壳熔融形成的"埃达克岩"类似地球化学特征,如SiO2≥56%,Al2O3≥15%,亏损Y(≤18×10-6)和重稀土元素(如Yb≤1.9×10-6),高Sr(很少样品的Sr含量低于400×10-6),无-正Eu,Sr异常,贫高场强元素等,但可以形成于不同构造背景并可有不同成因的岩浆岩。埃达克质岩具有重要的金属成矿意义,其有利成矿背景主要包括岛弧、大陆板内伸展和大陆活动碰撞造山带环境。世界上许多(包括三个最大的)斑岩铜矿都与埃达克质斑岩密切共生,因此埃达克质岩的成矿潜力巨大。在岛弧和大陆板内伸展环境中,来自俯冲玄武质洋壳或洋壳沉积物或拆沉的大陆地壳产生的熔体或释放的超临界流体与地幔的相互作用,一方面可能导致熔体被地幔橄榄岩混染,另一方面可能导致高Fe2O3含量的熔体或超临界流体对地幔的交代作用,地幔氧逸度升高,地幔金属硫化物被氧化分解,有利于铜、金等的矿化。

哀牢山造山带金矿成矿时序及其动力学背景探讨

哀牢山金矿带是我国最重要的喜马拉雅期造山型金矿带,形成于三江特提斯复合造山过程中。论文基于对哀牢山造山带金矿成矿作用的同位素定年结果,探讨了成矿年代学与构造-热事件的关系,厘定了其相关的地球动力学背景。已获得的最老成矿年龄集中于海西期,但过剩氩的存在导致视年龄值偏离真实成矿年龄,而最小视年龄(345.2±16Ma)与区域蛇绿岩的形成同时;含镍金黄铁矿硅质岩的含金量可能与热水沉积有关,其地球动力学环境对应于海底扩张和初始洋盆的形成。印支期是区域主碰撞造山高峰期,也是大规模岩浆活动与Cu-Ni-Pt-Pd硫化物矿床、VMS型Cu-Pb-Zn矿床及斑岩型Cu-Au矿床成矿集中期,其中老王寨金矿含金黄铁矿的Re-Os等时线年龄为229±38Ma。燕山期成矿年龄数据分散于180Ma、135Ma、110Ma和90Ma左右等多个时段,其中最晚时段年龄谱的最小视年龄值(91±1Ma)可能代表了一次较为重要的构造动力体制转换,该期(约90～70Ma)的区域成岩成矿(斑岩及斑岩型Cu-Mo-W-Au矿床)规模较大,表明增生造山→碰撞造山构造体制转换在研究区存在重要的成岩成矿响应。喜马拉雅期可能经历了早(63.09～61.55Ma)、主(36.10～33.76Ma)和晚(30.80～26.40Ma)三期金矿成矿-热事件,分别受控于印度-亚洲大陆碰撞早期的强烈汇聚挤压、早-晚期转换构造动力学体制,并可能受青藏高原物质东向逃逸和软流圈脉动隆起的联合制约,金矿大规模成矿作用与构造动力体制转换过程中的壳幔物质强烈交换与构造变形密切相关。

湘南中生代花岗质岩石成岩成矿的时限

位于南岭中段的湘南地区,中生代花岗质岩石广泛分布;该区W、Sn、Pb、Zn、Mo、Bi等金属矿床密集产出,很多钨、锡矿床达到大型、超大型规模,且找矿潜力巨大,构成一个世界级的有色金属矿集区。最近大量的同位素年代学研究表明,南岭中段钨、锡、铅锌等金属的成矿是一个爆发性、区域性的地质事件,成矿时间高度集中,成矿时限主要在150～160 Ma之间,与该区主要花岗岩的成岩时间相当吻合;对单个钨、锡矿床而言,其矿区的成岩、成矿存在着一种准同期性,即成矿与矿区花岗岩的成岩基本上是同时的、或稍晚于花岗岩的成岩作用。因此,该区中生代的花岗岩与钨锡成矿作用具有明显的时、空联系。南岭中段花岗岩大规模的侵入和钨、锡等金属的爆发性成矿均形成于一种岩石圈伸展减薄、地壳拉张的构造环境,可能与华南中生代第二幕岩石圈伸展事件密切相关。

会泽超大型铅锌矿床成矿时代研究

云南会泽超大型铅锌矿床由麒麟厂和矿山厂两个独立的铅锌矿床组成。利用两组同源矿物组合Rb Sr等时线方法测定了麒麟厂6号矿体的成矿时代,测定结果分别为(225 1±2 9)Ma和(225 9±3 1)Ma,根据已知的分布于该矿床北部和西南部分布的峨眉山玄武岩成岩时代为250Ma左右,有多个火山喷发旋回,显示多期次的喷发活动,认为川—滇—黔成矿区内铅锌成矿作用与峨眉山玄武岩岩浆活动存在成因联系。

兰坪金顶大规模成矿的流体过程——不同矿化阶段流体包裹体微量元素约束

金顶矿床是世界上形成时代最新且唯一的陆相沉积岩容矿的超大型铅锌矿床,受人关注。金顶矿石中矿物的交生关系表明内生流体成矿经历了石英-闪锌矿-方铅矿、闪锌矿-方铅矿-天青石、方铅矿-方解石-天青石-石膏三个矿化阶段,黄铁矿在各矿化阶段中均有形成,不同世代矿物从产状、结构、组合关系等得以区分;矿物流体包裹体中包括REE在内的几十种微量元素的配分曲线和含量分布不因寄主矿物种类而明显变化,不同矿化阶段矿物流体包裹体微量元素组成是大规模成矿流体过程的重要约束;大规模成矿从第1到第3矿化阶段,内生成矿流体∑REE逐步升高(1．34×10^(-9)～6．28×10^(-9)～297．03×10^(-9)),轻重REE分异越趋显著,系统从还原性演化为氧化性,微量元素组合趋于复杂,流体中成矿元素(Zn 13．594×10^(-9)～29331．810×10^(-9))不断富集(Zn依次是中国陆壳的0．16×10^(-3)～0．20×10^(-3)倍、0．041～0．193倍、0．028～0．341倍);早—中阶段的流体成矿可能是快速的,中—晚阶段趋缓;深、浅部两种不同性质流体混合可能是流体大规模成矿的基本过程。

华南铀矿床研究若干进展

华南是我国主要铀矿产区之一。根据赋矿围岩的不同,通常将华南广泛分布的铀矿床划分为花岗岩型、火山岩型和碳硅泥岩型等三种主要类型。本文在以往研究的基础上,总结了近年华南铀矿研究取得的若干进展。例如,沥青铀矿微区原位定年研究不断深入,获得一批较精确的成矿年龄;通过精细矿物学研究,发现了零价铀和高铀酸钙[(CaU^6+) O4]等以往在自然界少见的铀矿物;揭示华南不同类型的铀矿床是受白垩-古近纪岩石圈伸展事件统一控制并具有密切内在联系的有机整体;攻深找盲取得新突破,发现了新的成矿元素组合并预示了深部找矿的重要潜力。本专辑报道了近年华南铀矿研究的部分新进展,包括15篇文章,主要涉及这些铀矿床的地质地球化学特征、成矿时代、成矿过程、成矿动力学背景和找矿潜力等。

下庄铀矿田337矿床成矿机理及动力学背景

长期以来人们一直认为337铀矿床是下庄铀矿田成矿年龄最早、成矿温度相对较高、矿岩时差小的岩浆热液型铀矿床的代表。据作者及其他研究者近年来对该矿田及矿床开展的岩体成岩年龄、岩体蚀变年龄、岩体的主量和微量元素组成及同位素等的综合研究揭示：与337铀矿床成矿关系最为密切的帽峰岩体单颗粒锆石测试的成岩年龄为206～238．2Ma，而岩体中次生白云母的^40Ar／^39Ar法坪年龄变化于131～136Ma之间，后者与该矿床主要铀矿化年龄130．3～138Ma相近；在贵东花岗质杂岩体中，Al2O3／TiO2含量比值表明帽峰岩体可能是源区熔融温度最低的岩体，帽峰岩体还是稀土总量最低且是唯一显示较典型“四分组效应”的岩体，同时还具有变化的δ^18O值和最低的（^87Sr／^86Sr）i值。上述研究结果说明337铀矿床的形成过程和动力学背景可能是：印支主碰撞晚期或后碰撞阶段本区富铀地层发生部分熔融作用形成了富铀的强过铝质花岗岩帽峰岩体，燕山晚期（140Ma以后）大陆拉张背景下多期次基性脉岩侵入，带来高热和矿化剂CO2，并驱动大规模流体运动，活化和萃取了富铀花岗岩中的铀，在不同部位（裂隙发育地段或在基性脉岩与花岗岩的接触部位）沉淀形成铀矿体（床），337铀矿床是本区第1期铀成矿作用的典型代表。

宁芜和庐枞火山岩盆地玢岩铁矿矿床地球化学特征及其成矿动力学背景探讨

玢岩铁矿是我国铁矿的一个重要成矿类型,宁芜和庐枞火山岩盆地是长江中下游地区玢岩铁矿的主要矿集区。对宁芜和庐枞盆地的构造分析结果表明,NNE向断裂和NW向断裂控制了区内的岩浆活动,断裂的交汇部位往往是玢岩铁矿产出的有利空间。综合对比了宁芜和庐枞地区玢岩铁矿成矿岩体的主量元素、稀土元素以及铅同位素特征,表明其具有相似的地球化学特征和共同的物质来源。稀土元素特征表明两盆地玢岩铁矿的成矿物质主要来源于地幔或下地壳;Pb同位素特征则进一步说明其与EM-Ⅱ型富集地幔具有密切关系。宁芜和庐枞盆地在燕山期受太平洋板块俯冲作用的影响,成矿作用受岩浆活动所控制。两盆地玢岩铁矿成矿作用的差异,可能是由于其受地壳物质混染程度不同所致。

利用Q型聚类分析研究鄂尔多斯盆地多种能源矿产间的关系

为揭示鄂尔多斯盆地多种能源矿产间的关系,根据盆地石油、油气伴生水以及煤、煤层夹矸、铀矿及围岩样品的氯仿沥青中57种元素的分析结果,进行了Q型聚类分析。结果表明:侏罗系下统延安组石油、侏罗系中统直罗组石油与三叠系延长组石油有相近的成因特征;三叠系延长组石油沥青、三叠系延长组含油砂岩沥青与侏罗系中统直罗组石油沥青具有类似的成因特征;神木侏罗系下统延安组煤沥青、东胜侏罗系中统直罗组煤沥青、铜川陈家山侏罗系下统延安组煤层石油以及铜川陈家山侏罗系下统延安组煤沥青成因特征相近;铜川陈家山侏罗系下统延安组煤层石油沥青可能与准格尔黑岱沟石炭二叠系煤沥青具有成因上的联系;侏罗系下统延安组石油沥青与放射性铀矿的形成具有密切关系;天然气的物质来源复杂,且与石油和煤的进一步演化有一定关系。鄂尔多斯盆地多种能源矿产成因较复杂、相互间关系密切,且具有多源性成藏(矿)特征。

秦岭凤太矿集区喷流沉积型铅锌矿床S、Pb同位素地球化学特征

凤太矿集区位于秦岭泥盆系铅锌等多金属成矿带的中段，铅锌矿床主要产于中泥盆统古道岭组和上泥盆统星红铺组之间的硅质岩中。对区内三个典型铅锌矿床中S、Pb同位素组成研究表明，铅硐山、八方山、银母寺3个铅锌矿床金属硫化物的δ34S值变化范围较小，均不超过10‰。区内硫化物的δ34S值总体变化于4.3‰-13.2‰，指示S主要来自海水硫酸盐的还原作用。3个矿床矿石矿物的Pb同位素中206Pb/204Pb变化于17.775-18.180，207Pb/204Pb变化于15.457-15.805，208Pb/204Pb变化于37.977-38.670。各个矿床之间Pb同位素组成均有较大的重叠，暗示3个铅锌矿床具有相似的铅源。通过Pb同位素构造模式图解以及Δβ-Δγ分类图解分析表明，矿石铅来源于早古生代中期到末期扬子板块向华北板块之下俯冲以及晚古生代扬子板块、秦岭微板块向华北板块俯冲的历程中。

滇西北兰坪盆地金顶超大型矿床有机岩相学和地球化学

云南兰坪金顶矿床是世界上形成时代最新且唯一陆相沉积岩容矿的超大型铅锌矿床,也是中国目前最大的铅锌矿床,有机物质在金属成矿中可能发挥重要作用,受人关注。矿石及矿化岩石中产有包括干酪根、轻油、烃类气、重油、沥青及方解石中石油、甲烷包裹体等多种形式、产状和成熟度的有机物质,油气显示突出,古油气藏遗迹明显,是金顶古油气藏在铅锌成矿过程中热成熟、裂解和被改造、破坏不同阶段的产物。有机物质的氯仿沥青'A'变化大(72×10^(-6)～395415.42×10^(-6))。'A'的族组分中,总烃(58.47%)大于'非烃+沥青烯'(41.53%),饱和烃/芳香烃比值大于1,具Ⅰ型有机母质特征。有机转化率(A/C=0.5%～7.2%)较矿床外围岩石低,有机热成熟度高。矿石及矿化岩石中有机质的饱和烃包括正构烷烃、Pr、Ph和iC_(18)等化合物,碳数分布介于C_(10)～C_(34)之间,C_(21+22)/C_(28+29)=0.78～3.582,Pr/C_(17)=0.25～0.646,Ph/C_(18)=0.39～1.57,有机母质为海相菌藻类。有机质中检测出萘、菲、三芳甾烷、联苯、荧蒽等芳香烃类化合物,菲系列化合物最为明显,MPI_1 =0.215～0.434,MPI_2=0.252～0.588,菌藻等有机母质发育在高盐度还原沉积环境,烃源岩主要是三叠系残留海相碳质泥岩和泥灰岩。伴随金顶局部穹隆过程,很可能在金顶穹隆中形成油气藏,它是矿区铅锌快速大规模集中成矿的重要还原剂之一。

浅议大规模成矿作用与大型矿集区

本文系统地阐述了大规模或大爆发成矿作用现象、特点和出现的某些规律。阐述大规模成矿作用发生必须具有特殊的构造环境， 巨量的成矿物质供给， 持续的能量系统， 优越的输运通道和适宜的堆积空间。大规模成矿作用在空间上表现为非均一性， 在成矿区带中绝大多数矿床基本上仅出现于几个空间比较小的大型矿集区内。本文提出研究大型矿集区必须着眼于大尺度（ 成矿大环境） ， 切入中尺度（ 大型矿集区） ， 地质、地球化学和地球物理多学科交叉， 理清成矿过程， 建立成矿模型， 进而有效地提取找矿信息，