REE Geochemistry of Sulfides from the Huize Zn-Pb Ore Field, Yunnan Province: Implication for the Sources of Ore-forming Metals

REE abundances in sulfides from the Huize Zn-Pb ore field were determined with the ICPMS after preconcentration. The REE abundances in 26 sulfide samples （including pyrite, galena and sphalerite） are very low, with the ~REE ranging from 1.6×10^-9 to 166.8×10^-9. Their LREE/HREE ratios range from 7.6 to 98, showing LREE enrichment relatively. The JEu values are below 1, indicating that they were deposited from an Eu-depleted and reducing fluid-system. Similar to the ore-hosting carbonate strata, calcite separates from carbonate veinlets filling in the fractures or faults crosscutting the carbonate strata also show clear Eu-depletion. This indicates that the carbonate veinlets and their parent fluid was possibly sourced from the strata and inherited the REE geochemical features of the strata. Therefore, REE-geochemical characteristics of both the sulfides and calcites, which were deposited from an ore-forming hydrothermal system, are similar to those of carbonate strata, and strongly suggest that the ore metals were mainly sourced from carbonate strata.

Ore-forming fluid characteristics and ore-forming materials source of the Tudimiaogou – Yindongshan lead-zinc polymetallic orefield, west Henan

1 Introduction The Tudimiaogou-Yindongshan lead-zinc polymetallic orefield is located in the Tudimiaogou-Weimoshi lead and zinc silver polymetallic metallogenic belt.The belt is an important part of southwestern Henan lead and zinc

Rare Earth Elements Geochemistry of Laowan Gold Deposit in Henan Province: Trace to Source of Ore-Forming Materials

The compositions of REE in quartz and pyrite from the main stage of the Laowan gold deposit in Henan Province and that in quartz from Laowan granite were determined by inductively coupled plasma-mass-spectrometry （ICP-MS） to trace the source of ore-forming materials. Meanwhile, the REE compositions of the deposit ore, granite and metamorphic wall rock were also considered for comparative studies in detail. The range of ∑REE of quartz and pyrite from the deposit ores is 4.18 × 10^-6- 30.91 × 10^-6, the average of ∑REE is 13.39 × 10^-6, and the average of ∑REE of quartz in the Laowan granite is 6.68 × 10^-6. There is no distinct difference of REE parameters between the deposit ore quartz and granite quartz. The quartz in gold deposit has the same REE particular parameters as quartzes from Laowan granite, such as δEu, δCe, （La/Yb）N and （La/Sm）N, partition degree of LREE to HREE, especially, the chondrite-normalized REE patterns, but no similarity to those from metamorphic wall rock, which shows that ore-forming hydrothermal fluid is mainly the fluid coming from the Laowan granite magma, rather than metamorphic fluid. Meanwhile, comparison studies on REE features between minerals from the deposit ores and related geological bodies in the deposit show that REE characteristics of minerals can serve as an indicator of ore-forming fluid properties and sources, while the REE characteristics of the bulk samples （such as deposit ores, granites and wall rocks） can not trace the source of the ore-forming materials exactly.

Ore-forming mechanism of Xiajinbao gold deposit in Pingquan, Hebei based on fluid inclusions and stable isotopes

The Xiajinbao gold deposit is located in Yong’an-Xiayingfang-Maojiagou polymetallic metallogenic belt,which is animportant metallogenic belt in North China block.In this paper,we present a detailed study on fluid inclusions and stable isotopes ofthe Xiajinbao gold deposit,Hebei Province,China,aiming at discussing the ore source,evolution of ore-forming fluid andore-forming mechanism of the deposit.The macroscopic geological characteristics,S and Pb isotopic analysis results show that thesource of ore-forming materials is mainly from granitic magma,and subordinately from country rocks.H and O isotopic compositionfeatures indicate that the ore-forming fluid is mainly derived from magmatic water.Fluid inclusion characteristics show that theore-forming fluid experienced boiling during the early mineralization stage,which led to the precipitation of gold.Fluid mixingdominated the precipitation of the ore-forming materials during the middle and late stages.The gold precipitation was caused bywater/rock reaction throughout the whole ore-forming process.

Rare Earth Element Geochemistry Characteristics of Laowan Gold Deposit in Henan Province: Trace to Source of Ore-Forming Materials

The compositions of REE in quartz and pyrite from main mineralized stage of the Laowan gold deposit in Henan province and that of quartz from Laowan granite were determined by Inductively Coupled Plasma-Mass-Spectrometry （ICP-MS）. The REE of deposit ore of the Laowan gold deposit, wall-rock and Laowan granite also were studied to trace the source of metallogenic materials in Laowan gold deposit in detail. The range of ∑ REE in quartz and pyrite from gold deposit is 4.18 × 10^-6 - 30.91 × 10^-6, average of 13.39 × 10^-6, 6.68 × 10^-6 of the Laowan granite quartz, obviously lower to REE concentration of deposit, granite and wall-rock. The value of （La/ Yb）N and （La/Sm）N of ore minerals from the gold deposit is 13.23 and 4.17 respectively. The differences in REE parameters, such as δEu, δCe and diffusion degree in REE from light to heavy, among deposit ore minerals and granite mineral are weak. Especially, there are no differences between the chondrite-normalised REE curves of minerals from gold deposit and those of quartzs in Laowan granite, no similarity to wall-rock＇, which shows that ore-forming hydrothermal fluid mainly came from magma fluid resulting from the Laowan granite magma, metamorphic fluid in few. The results also show that REE characteristics of ore minerals in deposit are effective for disclosing oreforming fluid quality comparing with deposit ore＇REE compositions.

Genesis, metallogenic model, and prospecting prediction of the Nibao gold deposit in the Guizhou Province, China

Southwestern Guizhou province is one of China’s most important distribution areas of Carlin-type gold deposits. The Nibao deposit is a typical gold deposit in southwestern Guizhou. To elucidate the genesis of the Nibao gold deposit, establish a metallogenic model, and guide prospecting prediction, we systematically collected previously reported geological, geochemical, and dating data and discussed the genesis of the Nibao gold deposit,based on which we proposed the metallogenic model.Earlier works show that the Nibao anticline, F1 fault, and its hanging wall dragged anticline(Erlongqiangbao anticline) were formed before or simultaneously with gold mineralization, while F2, F3, and F4 faults postdate gold mineralization. Regional geophysical data showed extensive low resistivity anomaly areas near the SBT(the product of tectonic slippage and hydrothermal alteration)between the P2/P3 and the strata of the Longtan Formation in the SSE direction of Nibao anticline in the lower plate of F1 and hanging wall dragged anticline(Erlongqiangbao anticline), and the anomaly areas are distributed within the influence range of anticlines. Simultaneously, soil and structural geochemistry show that F1, Nibao anticline,Erlongqiangbao anticline, and their transition areas all show good metallogenic elements(Au, As, and S) assemblage anomalies, with good metallogenic space and prospecting possibilities. There are five main hypotheses about the source of ore-forming fluids and Au in the Nibao gold deposit:(1) related to the Emeishan mantle plume activity;(2) source from the Emeishan basalt;(3) metamorphic fluid mineralization;(4) basin fluid mineralization;(5) related to deep concealed magmatic rocks;of these, the mainstream understanding is the fifth speculation. It is acknowledged that the ore-forming fluids are hydrothermal fluids with medium–low temperature, high pressure, medium–low salinity, low density, low oxygen fugacity, weak acidity, weak reduction, and rich in CO_(2)and CH_(4). The fluid pressure is 2–96.54 MPa, corresponding to depths of 0.23–3.64 km. The dating results show that the metallogenic age is ~141 Ma, the extensional tectonic environment related to the westward subduction of the Pacific Plate. Based on the above explanation, the genetic model related to deep concealed magmatic rocks of the Nibao gold deposit is established, and favorable prospecting areas are outlined;this is of great significance for regional mineral exploration and studying the genesis of gold deposits.

广东河台金矿硫化物地球化学特征及地质意义

河台金矿是广东省最大的金矿,被认为是典型的剪切带型金矿。尽管矿床产于云开群变质岩中,但是在产出时间和空间展布上又与云楼岗和伍村岩体有密切关系,再加上成矿的多阶段性,导致对成矿流体及物质来源一直存在争议。河台金矿的金主要以自然金形式产出,与黄铁矿、黄铜矿、磁黄铁矿等矿石矿物紧密共生。本文对河台金矿田热液成矿期金-硫化物阶段的黄铁矿、磁黄铁矿进行了微量元素和Sr-Nd同位素分析,以进一步示踪成矿流体及物质来源。两种硫化物Co/Ni比值为0.36~3.33,显示主要为热液成因。Hf/Sm、Nb/La、Th/La值<1,暗示成矿热液是以富Cl–的流体为主;Y/Ho比值为12.0~33.0,与糜棱岩有明显区别;(^(87)Sr/^(86)Sr)i值为0.707078~0.713545,εNd(t)为–19.36~–15.12,位于华夏板块元古代基底和EM1富集地幔之间。这些特征暗示成矿流体的多源性。黄铁矿ΣLREE/ΣHREE值介于5.53~15.4,在球粒陨石标准化图中呈明显右倾,δEu值为0.48~0.75,具有明显的Eu负异常,与糜棱岩特征相似,暗示成矿物质主要来自围岩。结合前人年代学研究结果,推测印支期在混合岩化和韧性剪切作用下,变质流体将云开群中的成矿物质运移到剪切带中,使Au初步富集;燕山期地壳深部华夏板块中—古元古代基底重熔产生的岩浆流体混入少量地幔流体,为剪切带中成矿物质发生活化迁移提供载体和动力,并在局部再次富集形成工业矿体。

ON ORE SOURCE AND ORE-FORMING FLUID OF DONGCHUAN-YIMEN TYPE COPPER DEPOSITS

The macroscopic and microscopic studies (in mineral inclusions, stable isotopes, traceelements, etc.) on the Donchuan-Yimen type copper deposits show that the ore material deriv-ed from host rocks and their underlying beds, and Bi, Pb, Zn probably did from deep frac-tures. The ore-forming fluid is hot brine in nature, and the water in it is probably stratumwater in origin. The sulphur derived from bacteria reducing of sulphate in sea water. Thecarbon derived from marine carbonate. The organic carbon plays an important role in themetallogenesis. In the Kangdian Axis, two deep fractures controlled the sedimentation of thecupriferous algal reef carbonate formation. They were ore-, heat-, brine-conducting tectonicsand led to the formation and transformation of many copper ore beds.

Source and Evolution of the Ore-Forming Fluids of Carlin-Type Gold Deposit in the Youjiang Basin,South China:Evidences from Solute Data of Fluid Inclusion Extracts

The source and evolution of ore-forming fluids is important to understand the genesis of Carlin-type gold deposit.Constraints on the source and evolution of ore fluid components by the con-ventional geochemical methods have long been a challenge due to the very fine-grained nature and complex textures of hydrothermal minerals in these deposits.In this study,we present the crush-leach analyzed solute data of fluid inclusion extracts within quartz,calcite,realgar,and fluorite from the Shuiyindong,Nibao,and Yata gold deposits in the Youjiang Basin,providing new insights into the source and evolution of ore-forming fluids.The results show that the high molar Cl/Br ratios up to 2508 in fluid inclusion extracts are indicative of a contribution of magmatic hydrothermal fluids.Flu-ids mixing between basinal and magmatic-hydrothermal fluids are evident on the plots of Cl/Br versus Na/K ratios,showing that ore-stage milky quartz near the magmatic-hydrothermal fluids reflects magma origin of the ore-forming fluids,whereas late ore-stage drusy quartz and realgar near the de-fined basinal fluids suggest the later input of basinal fluids in late-ore stage.Although the predominate-ly host rocks in Shuiyindong,Nibao and Yata gold deposit are bioclastic limestone,sedimentary tuff,and calcareous siltstone,respectively,the solute data of fluid inclusion extracts records they underwent the similar fluid-rocks reactions between the Na-rich magmatic hydrothermal fluids and the Ca-and Mg-rich host rocks.This study highlights the solute data of fluid inclusion extracts obtained by crush-leach analyses have the potential to fingerprint the source and evolution of ore-forming fluids of the Carlin-type gold deposit.

内蒙古赤峰双尖子山银多金属矿床成矿流体来源及金属沉淀机制探讨

双尖子山超大型银多金属矿床是大兴安岭成矿带最具代表性的热液型银矿床,也是目前亚洲最大银矿。该矿床热液作用可划分为Ⅰ、Ⅱ两期,第Ⅰ期又可划分三个成矿阶段,依次为成矿阶段(Ⅰ-1)(主要为黄铁矿+方铅矿+闪锌矿+银矿物+石英组合,分布在北西走向矿脉)→成矿阶段(Ⅰ-2)(主要为方铅矿+银矿物+闪锌矿+石英+方解石组合,分布在北北东走向矿脉)→成矿阶段(Ⅰ-3)(含金石英+方解石脉组合,分布在近东西走向矿脉)。第Ⅱ期为胶结硫化物脉的无矿石英脉,主要是石英+少量方解石组合。该矿床流体包裹体以L型和V型为主,总体属于中低温-低盐度流体。成矿阶段(Ⅰ-1)流体包裹体均一温度介于171℃~280℃之间,平均228℃,盐度介于0.53%~12.73%(NaCleqv)之间,平均3.48%(NaCleqv);成矿阶段(Ⅰ-2)流体包裹体均一温度介于109.3℃~258.0℃之间,平均193.3℃,盐度介于0.18%~22.38%(NaCleqv)之间,平均4.20%(NaCleqv);第Ⅱ期热液流体包裹体均一温度介于238.7℃~362.9℃之间,平均275.9℃,盐度介于0.35%~2.24%(NaCleqv)之间,平均1.05%(NaCleqv)。方解石δ13C介于-11‰^-7.4‰,δ18OSMOW介于1‰~4.5‰;石英和方解石δDH2O变化于-145‰^-65‰,δ18OH2O变化于-12.5‰~4.6‰,表明流体为岩浆水和大气降水的混合来源;金属硫化物40Ar/36Ar值介于294.75~303.92,3He/4He值介于0.25~0.81Ra,显示壳源流体特征。双尖子山矿床成矿流体具有脉冲式活动、多阶段演化和多来源特点,成矿流体具有从相对的高温高盐度向低温低盐度演化规律。岩浆水与循环大气降水的混合作用可能是本矿床金属沉淀的主要机制。双尖子山矿床属于与壳源岩浆活动有关的中浅成-中低温热液型银多金属矿床。

扬子陆块北缘马元铅锌矿床成矿物质来源探讨:来自C、O、H、S、Pb、Sr同位素地球化学的证据

呈层状、似层状产于震旦系灯影组角砾状白云岩层间构造带中的马元铅锌矿床是近年来在扬子陆块北缘铅锌找矿的新突破。文章通过碳、氧、氢、硫、铅和锶同位素地球化学特征研究,探讨了成矿流体和成矿金属来源。研究结果表明：矿石中热液脉石矿物的δ13CPDB为-4.24‰~0.93‰,δ18OSMOW为15.92‰~23.24‰,表明成矿流体中的CO2为震旦系碳酸盐岩的溶解成因。矿石中硫化物的δ34S变化于12.94‰~19.4‰之间;硫酸盐矿物的δ34S为32.2‰~33.48‰,表明还原硫主要来自地层中海相硫酸盐的还原。矿石硫化物的铅同位素组成均一,206Pb/204Pb、207Pb/204Pb和208Pb/204Pb分别为17.62~18.02、15.49~15.63和37.57~38.35,成矿金属可能主要来源于震旦系—志留系。脉石矿物石英流体包裹体的δDFI为-92‰和-113‰,如果取成矿温度200℃,根据δ18O石英值计算的相应流体包裹体的δ18O水为6.03‰~12.73‰,推测成矿流体可能起源于大气降水为主的盆地卤水,或为其他来源的流体与有机质反应形成。成矿流体87Sr/86Sr为0.70967~0.71146,高于赋矿围岩震旦系灯影组白云岩锶同位素比值（0.70890~0.70945）,表明成矿流体流经了古生代地层（及基底）,并与其中具有高锶同位素比值的碎屑岩、页岩和泥岩等进行了水岩反应及同位素交换。

湘西花垣铅锌矿田成矿物质来源的C、O、H、S、Pb、Sr同位素制约

花垣地区铅锌矿床有望成为中国最大的铅锌矿床,也是铅锌矿资源储量超过千万吨的世界级超大型矿床之一。文章通过碳、氧、氢、硫、铅和锶同位素地球化学特征研究,探讨了成矿流体和成矿金属来源。测试结果显示,花垣地区铅锌矿床主成矿期方解石样品的δ^(13) CPDB值范围为-2.71‰~1.21‰,δ^(18) OSMOW值范围为16.09‰~22.48‰,该地区铅锌矿床成矿流体中的碳主要来源于海相碳酸盐岩的溶解作用。花垣矿区的围岩的δ^(13) CPDB值范围为0.29‰~1.05‰,δ^(18) OSMOW值范围为21.33‰~23.89‰,为沉积成因海相碳酸盐岩。矿石中硫化物的δ^(34) S变化于24.93‰~34.66‰之间,重晶石δ^(34) S为32.78‰~34.22‰,表明还原硫主要来自地层中海相硫酸盐的还原。矿石硫化物的铅同位素组成均一,^(206)Pb/^(204)Pb、^(207)Pb/^(204)Pb和^(208)Pb/^(204)Pb分别为17.999~18.919、15.554~15.798和38.088~38.576,铅模式年龄为437~534Ma,成矿金属可能主要来源于奥陶系—寒武系。方解石和闪锌矿样品中流体的δD_(SMOW)变化于-91.1‰^-15‰之间,δ^(18) Ofluid变化范围为-4.1‰~8.75‰,矿床成矿流体的主要来源是建造水和大气降水。成矿流体与围岩的水-岩反应是导致该区铅锌矿床中方解石和闪锌矿矿物沉淀结晶的主要机制。成矿流体^(87)Sr/^(86)Sr为0.70906~0.71022,高于赋矿围岩寒武系清虚洞组灰岩锶同位素比值0.70886~0.70921,表明成矿流体流经了清虚洞组下伏地层,并与其中具有高锶同位素比值的碎屑岩、页岩和泥岩等进行了水岩反应及同位素交换。

云南会泽铅锌矿田成矿物质来源:Pb、S、C、H、O、Sr同位素制约

云南会泽铅锌矿田是我国著名的超大型特富铅锌矿田之一,由相距3公里的矿山厂和麒麟厂两个独立的矿床组成,Zn+Pb 金属量超过五百万吨,矿石品位在25%至35%之间。为确定矿床成矿流体和成矿金属来源,本文系统研究了矿床的 Pb、S、C、O、H 和 Sr 同位素组成特征。矿石硫化物的铅同位素组成均一,^(206)Pb/^(204)Pb,^(207)Pb/^(204)Pb 和^(208)Pb/^(104)Pb 的变化范围分别为18.251～18.530,15.663～15.855和38.487～39.433,与围岩碳酸盐岩中浸染状黄铁矿一致,与碳酸盐地层相近,在^(208)Pb/^(204)Pb-^(206)Pb/^(204)Pb 图上显示明显的线性关系,表明铅同位素组成相近的碳酸盐围岩地层提供了成矿物质。矿石硫化物的δ^(34)S 变化范围为10.9‰～17.4‰,多数集中于13‰～17‰,表明还原硫主要来自地层中海相硫酸盐的还原,还原方式为热化学还原,下伏页岩、碎屑岩和泥质岩中的有机质在硫酸盐还原过程中发挥了重要作用。三种不同产状的脉石矿物方解石的碳氧同位素组成均一且没有明显差别,δ^(13)C 变化范围为-2.1‰～-3.5‰,δ^(18)O 为16.8‰～18.6‰。脉石矿物方解石中流体包裹体水的δD_(FI)为-50‰～-60‰,取温度为200℃计算包裹体水的δ^(18)O_(H_2O)值为7.0‰～8.8‰。碳、氧和氢、氧同位素研究结果表明,成矿流体为来自下部上升的变质流体,由于下伏页岩、碎屑岩和泥质岩中有机质的参与,成矿流体具有低的δ^(13)C和δD_(FI)值,在上升过程中与围岩发生了同位素交换。矿石中黄铁矿、闪锌矿和方解石的初始锶同位素组成(^(87)Sr/^(86)Sr)_i值的变化范围为0.714～0.717,赋矿围岩中未蚀变白云岩的初始锶同位素组成(^(87)Sr/^(86)Sr)_i值为0.7083～0.7093,明显低于蚀变白云岩(0.7106),表明成矿流体具有高的(^(87)Sr/^(86)Sr)_i比值。相对围岩碳酸盐岩而言,下伏地层中的页岩、碎屑岩和泥质岩往往具有高得多的^(87)Sr/^(86)Sr,因此,流经或者起源于这些地层的流体具有高的锶同位素比值。

广东圆珠顶斑岩型铜钼矿床成矿物质、成矿流体来源和成矿机理研究

圆珠顶斑岩型铜钼矿床位于钦杭成矿带西南端，是该成矿带近年来发现的又一大型铜钼矿床。文中通过对圆珠顶矿床地质特征的详细剖析并结合H、O、S、Pb等同住素地球化学的研究，对圆珠顶斑岩型铜钼矿床的成矿流体和成矿物质来源进行了初步的讨论。研究结果表明：矿石金属硫化物δ34 S值分布于4．3‰～3．9‰，硫主要来源于岩浆岩；矿石铅同位素组成稳定，为正常普通铅；不同成矿阶段H、O同位素组成变化及流体包裹体研究指示大气降水与含矿岩浆热液混合是金属矿物从成矿流体中沉淀的重要因素。结合成矿动力学背景研究，认为圆珠顶矿床成矿作用与岩浆活动密切相关，矿床成因是由于板块俯冲作用引起的地壳与地幔物质混合。

金属矿床成矿物质来源的几种常用同位素地球化学研究

金属矿床成矿物质来源是矿床地球化学工作者最为关心的问题之一。不同矿床成矿物质来源不同,同种矿床甚至同一矿床成矿物质来源也会有不同。成矿物质来源包括成矿元素和成矿流体两方面,目前常用的研究方法主要是同位素地球化学分析。通过研究六种常用同位素(氢、氧、硫、钕、锶、铅)的组成和演化特征,简述同位素在金属矿床成矿物质来源中的应用及注意事项,为矿床成因、成矿模式等研究工作以及同位素方法的合理运用提供参考。

黔西北赫章天桥铅锌矿床成矿物质来源:S、Pb同位素和REE制约

赫章县天桥铅锌矿床位于扬子准地台西南缘的黔西北铅锌成矿区中部,是本区已发现的96处中、小型矿(床)点的典型代表。天桥铅锌矿床由三个矿体群组成,其金属资源量(Pb+Zn)超过0.2Mt。本文报道了该矿床矿石硫化物的硫和铅同位素组成及其稀土元素组成特征。矿石硫化物δ34SV-CDT值主要集中在8.4‰～14.4‰之间,总体具有δ34Spy>δ34Ssp>δ34Sga特征,表明成矿流体中硫已达到平衡。该矿床成矿流体中δ34S∑S值与不同时代地层中海相硫酸盐δ34S值(15‰)相近,表明成矿流体中硫来源于不同时代地层,为不同时代地层海相硫酸盐热化学还原(TSR)的产物。铅同位素组成相当均一,n(208Pb)/n(204Pb)值为38.875～39.057(平均38.945),n(207Pb)/n(204Pb)值为15.708～15.763(平均15.728),n(206Pb)/n(204Pb)值范围为18.481～18.544(平均18.516),与碳酸盐地层相近,在n(208Pb)/n(204Pb)—n(206Pb)/n(204Pb)和n(207Pb)/n(204Pb)—n(206Pb)/n(204Pb)图,落入碳酸盐地层范围内,表明铅来源于与矿物铅同位素组成相近的各时代碳酸盐地层。硫化物样品具有低ΣREE(<3×10-6)和负的Eu异常(0.13～0.88)特征。在稀土元素球粒陨石标准化配分模式图上,全部样品具有相似特征,且与地层中的黄铁矿(下石炭统大塘组C1d)、地层白云岩及蚀变围岩相比,具有一致的稀土配分模式和Eu负异常特征,表明成矿流体来源围岩及下伏碳酸盐地层。综合S、Pb同位素和REE地球化学特征认为该矿床成矿物质和成矿流体具有多来源特征,各时代地层均不同程度地为成矿提供物质和流体。

云南会泽超大型铅锌矿床成因研究中的几个问题

位于川—滇—黔铅锌多金属成矿域中南部云南会泽超大型铅锌矿床可能是一种新的铅锌矿床类型,该类铅锌矿床明显特征是规模大、品位富、伴生有用元素多,暗示其成矿环境较为特殊。从成矿时代、成矿物质来源、成矿流体来源与演化,以及峨眉山玄武岩与成矿的关系等方面分析了会泽超大型铅锌矿床的研究进展及国内外研究现状,认为矿床成矿时代与西南大面积峨眉山玄武岩成矿时代相近,成矿物质和成矿流体具有"多源性",成矿流体存在均一化过程,区域大规模流体运移在该区铅锌成矿过程中具有重要意义,峨眉山玄武岩岩浆活动与铅锌成矿具有密切的成因联系,矿床可能为"均一化成矿流体贯入成矿"的产物。

贵州从江地虎铜金多金属矿床微量和稀土元素地球化学

贵州从江地虎铜金多金属矿床_T-业矿体产于加车鼻状背斜北东翼，赋矿围岩为新元古界青白口系下江群甲路组浅变质沉积岩。相关分析显示，Mo—Ga—Cd—As—Co－In与Cu—Pb—Zn-Au—Ag相关，表明它们是重要的找矿指示元素；聚类分析表明，Mo与cu相关，暗示Mo具成矿潜力。与黄铜矿共生黄铁矿的Co／Ni值为3．17～26．5，具有热液成因特征，其Y／Ho值（23．4～33．6）与围岩（26．2～31．6）相近，表明围岩可能为成矿提供了部分成矿物质。全部样品均具有轻稀土富集，Eu负异常和弱Ce异常特征。热液黄铁矿和石英与围岩具有相似的REE配分模式，表明REE继承围岩。综合研究认为地虎铜金多金属矿床部分成矿物质源自赋矿地层。

粤北曲仁盆地北缘凡口式MVT铅锌矿床的地球化学特征

粤北曲仁碳酸盐岩盆地北缘聚集的铅锌硫化物矿床地质矿化特征相比于其他MVT矿床,具有成矿特殊性。为了确定该类矿床成矿流体和物质的来源以及成矿作用过程,对研究区矿床地层、断裂构造地球化学特征、稀土元素、硫铅同位素和流体包裹体特征进行系统研究。结果表明:地层、构造以及稀土元素研究结果显示该类铅锌硫化物矿床经历了黄铁矿矿化与铅锌矿化两个成矿作用过程,前者与赋矿层灰岩的物源联系更紧密,后者的成矿金属物质并非直接来自赋矿层灰岩,而是由通过北东、北西向断裂向上运移的盆地深部流体提供,且局部受到中基性岩浆侵入活动轻微改造;矿石及相关地质体同位素地球化学特征显示铅主要来自盆地基底碎屑岩层,部分来自盆地深部壳源重熔型花岗质岩浆,少部分来自盆地碳酸盐岩层,而硫主要为地层硫,小部分为壳源岩浆硫;闪锌矿流体包裹体气液相成分、盐度和温度结果显示铅锌热液成矿期古地热高异常,盆地基底碎屑岩含水系统及燕山期岩浆热液参与铅锌成矿。综合矿床地球化学特征可知,粤北曲仁盆地北缘凡口式MVT铅锌矿床属于两期热液叠加改造热液型铅锌矿床。

铜同位素及其在矿床研究中的应用

随着多接收电感耦合等离子体质谱仪(MC-ICP-MS)在同位素地球化学中的应用,铜同位素在矿床学领域的应用范围逐渐扩大。通过总结已发表的部分地质样品测试数据,大致归纳了各类地质体中铜同位素组成与分布特征,并简要概述了铜同位素可能的分馏机理及过程,其中包括还原过程、沉淀过程、吸附过程、淋滤过程及有机质的影响。重点论述了各类型矿床中铜同位素组成的差异性以及铜同位素在示踪成矿金属来源,推断流体运移与金属沉淀、成矿阶段、成岩成矿环境和在矿床勘探中的应用。