滇东南老君山矿集区马卡钨铍稀有金属矿床花岗岩年代学归属

滇东南地区处于扬子板块和华夏板块交汇处,该区地质活动频繁、成矿条件优越,分布有个旧岩体、薄竹山岩体、老君山岩体,并伴随形成了以个旧锡矿床、白牛厂银多金属矿床、都龙锡锌矿床为代表的大型-超大型矿床,构成了我国重要的滇东南钨锡多金属成矿带。马卡钨铍多金属矿床分布于老君山岩体北缘,位于重要的滇东南成矿带上,该矿床与区内的马卡花岗岩成因上具有密切联系。本文通过对马卡花岗岩LA-ICP-MS锆石U-Pb同位素年代学开展了系统研究,探讨了该花岗岩的形成年龄、物质来源等。结果显示,马卡花岗岩年龄位于400～415 Ma之间,表明其形成于加里东期,应归属于加里东期的南温河系列花岗岩系列,而不是燕山期老君山花岗岩的组成部分。马卡花岗岩具有高硅(w（SiO₂）=72.47%～74.63%)、高碱(w（Na₂O+K₂O）=7.02%～7.79%)、高钾(w（K₂O）>w（Na₂O）)、强过铝质(I_A/I_CNK>1.11)等特征,Y、Th与Rb演...     

赣南隆坪萤石矿床成矿时代及成因初探：来自萤石Sm-Nd测年及黑云母电子探针的证据

隆坪萤石矿床是赣南已探明的大型单一萤石矿床，矿体产于永丰复式岩体外接触带北东向硅化破碎带中。文章首次 采用Sm-Nd等时线法对隆坪萤石矿进行测年和稀土元素分析，并对永丰复式岩体中黑云母矿物成分进行了系统的测试；获 得了隆坪萤石矿的成矿年龄为158±3 Ma，与永丰复式岩体的成岩时代基本一致，表明该矿床萤石成矿作用与晚侏罗世岩浆 活动关系密切。隆坪萤石矿中萤石轻稀土元素略富集，重稀土相对平坦，具微弱Ce正异常（δCe=1.08~1.11，平均1.09） 和 微弱Eu负异常（δEu=0.91~0.98，平均0.95），指示了萤石矿床的成矿流体经历了相对较高的温度。黑云母电子探针分析结 果证实永丰复式岩体形成于相对高温、低压和高氧逸度的环境，岩浆起源于古老地壳物质的部分熔融，岩浆结晶分异晚阶 段岩浆期后热液富含F等挥发分。隆坪萤石矿床形成于晚侏罗世，成因类型为岩浆期后热液充填型。     

赣南隆坪萤石矿床成矿时代及成因初探:来自萤石Sm-Nd测年及黑云母电子探针的证据

隆坪萤石矿床是赣南已探明的大型单一萤石矿床,矿体产于永丰复式岩体外接触带北东向硅化破碎带中。文章首次 采用Sm-Nd等时线法对隆坪萤石矿进行测年和稀土元素分析,并对永丰复式岩体中黑云母矿物成分进行了系统的测试;获 得了隆坪萤石矿的成矿年龄为158±3 Ma,与永丰复式岩体的成岩时代基本一致,表明该矿床萤石成矿作用与晚侏罗世岩浆 活动关系密切。隆坪萤石矿中萤石轻稀土元素略富集,重稀土相对平坦,具微弱Ce正异常（δCe=1.08~1.11,平均1.09） 和 微弱Eu负异常（δEu=0.91~0.98,平均0.95）,指示了萤石矿床的成矿流体经历了相对较高的温度。黑云母电子探针分析结 果证实永丰复式岩体形成于相对高温、低压和高氧逸度的环境,岩浆起源于古老地壳物质的部分熔融,岩浆结晶分异晚阶 段岩浆期后热液富含F等挥发分。隆坪萤石矿床形成于晚侏罗世,成因类型为岩浆期后热液充填型。     

萤石Sm—Nd同位素体系对晴隆锑矿床成矿时代和物源的制约

本文首次对黔西南晴隆锑矿床的萤石进行Sm-Nd同位素研究,来探讨该矿床的形成时间和成矿物源.研究表明,该矿主成矿期的萤石构成两组等时线,其对应的等时线年龄分别为148±8 Ma和142±16 Ma,显示该矿床的成矿作用发生在晚侏罗世.本次测定的成矿年龄数据远小于峨眉山玄武岩的成岩年龄,暗示该矿床与该区二叠纪的火山作用没有直接的成因联系.计算表明,在晴隆锑矿床成矿时(142 Ma),两组萤石的εNd(t)值分别为-5.72～-5.81和-3.81～-3.88,远小于峨眉山玄武岩的相应值(0.40～3.27);两组萤石初始Nd同位素组成的差异,暗示其Nd的来源存在不均一性,这很可能与萤石沉淀环境围岩的局部差异有关.在εSr(t)-εNd(t)图解中,萤石明显分布在与赋矿围岩不同的区域,暗示该矿的成矿物质主要是来自外部(可能是下伏老地层或基底),而不是赋矿的峨眉山玄武岩和茅口组灰岩,因此,该矿并非是前人认定的"原地改造成矿".     

闽中梅仙矿集区丁家山铅锌矿床成矿时代厘定及成矿物质来源: 来自闪锌矿Rb-Sr同位素的证据

丁家山铅锌矿床位于闽中梅仙矿集区西南部, 矿体多呈层状、似层状和透镜状, 产于中—新元古界马面山群龙北溪组的绿片岩和大理岩中。为查明该矿床的成矿时代, 对该矿床中的主要矿石矿物闪锌矿开展了Rb-Sr同位素测年。8件闪锌矿样品构成的等时线年龄为143.1±3.2Ma(MSWD=1.7), 表明该矿床形成于燕山中期晚侏罗世。闪锌矿的锶同位素(初始比值为0.71434±0.00036)及前人的硫、铅同位素研究成果共同指示, 丁家山矿床的成矿物质可能主要来源于下地壳的深源岩浆。综合分析认为, 丁家山矿床形成于古太平洋板块向欧亚大陆板块俯冲-消减后的伸展引张环境背景下, 是晚侏罗世到早白垩世期间的花岗岩体与中—新元古界的大理岩经接触交代后的矽卡岩型矿床。作为梅仙矿集区的典型铅锌矿床, 丁家山矿床的成矿时代对区内其他铅锌矿床的成矿时代具有一定约束意义。     

湘西沃溪金锑钨矿床燕山期幕式成矿作用：来自原位白钨矿U-Pb定年与黄铁矿元素-同位素的约束

沃溪矿床位于江南造山带中段,是一座同时具有金、锑、钨大规模成矿的大型金矿,近年的研究揭示其主要形成于燕山期,但该矿的成矿物质源区及矿床成因尚存争议。基于此,本文利用SEM、EPMA、LA-MC-IF-ICP-MS等原位分析技术,对该矿床多世代黄铁矿的结构、成分及同位素组成和成矿期白钨矿的U-Pb年代学进行了研究。在沃溪矿床中,识别出3个世代5种类型黄铁矿(Py),即成矿前Py1,成矿第二阶段Py2和第三阶段的Py3a、Py3b和Py3c。黄铁矿微区成分及围岩蚀变特征指示,成矿期Au、As和Cu耦合,Au主要以固溶体(Au⁺)的形式存在于Py3b的晶格中;As^-取代S^-进入黄铁矿是促进晶格金富集的主要因素;而强烈的水-岩反应是导致成矿期热液黄铁矿Co/Ni<1的原因。黄铁矿的原位微量元素和S-Pb同位素组成(δ³⁴S_V-CDT值：Py2为-4.33‰～-1.61‰,Py3a为-6.36‰～3.59‰,Py3b为-4.36‰～3.59‰,Py3c为-2.21‰～-0.65‰;...     

鄂东南地区Cu-Au-Mo-(W)矿床的成矿时代及其成矿地球动力学背景探讨：辉钼矿Re-Os同位素年龄

鄂东南地区Cu-Au-Mo-(W)矿床是长江中下游地区金属成矿带的重要组成部分。本文利用Re-Os同位素定年方法对该地区5个典型矿床(丰山洞铜钼金银多金属矿床、阮家湾钨铜钼矿床、千家湾铜金矿床、铜绿山铜铁金钼多金属矿床和铜山口铜钼矿床)进行了成矿时代的研究,获得其辉钼矿Re-Os同位素年龄分别为(144.0±2.1)Ma、(143.6±1.7)Ma、(137.7±1.7)Ma、(137.8±1.7)~(138.1±1.8)Ma和(143.5±1.7)~(142.3±1.8)Ma,代表各矿床的成矿时代。研究结果表明,鄂东南矿集区内的Cu-Au-Mo-(W)矿床与铜陵、安庆、九瑞矿集区内的矿床几乎是同时形成的,成矿时代可能主要集中于(140±5)Ma,相当于晚侏罗世-早白垩世。在综合已有的岩石学、地球化学和地球物理学资料的基础上,笔者认为,这一成矿事件的深部动力学过程可能是处于中国东部南北向印支期构造域向北东向古太平洋构造域大转折的背景下,与软流圈上涌和玄武质岩浆底侵而导致壳幔同熔有关。     

南秦岭香沟金钨矿白钨矿原位微区分析及方解石Sm-Nd同位素定年：对钨成矿过程的限定

陕西省山阳县香沟钨矿是近年来南秦岭地质勘查新发现的钨矿化地段之一。本文开展了白钨矿电子探针、LA-ICP-Ms和共生方解石的Sm-Nd同位素测年,研究结果显示：香沟白钨矿成矿过程至少可划分为两个阶段,由早阶段韵律环带白钨矿至晚阶段集合体状白钨矿,白钨矿经历了多次迁移;白钨矿具有高F、含微量Au元素的特征,稀土总量较高（ΣREE+Y含量介于5.44×10^-6~382.67×10^-6,平均为95.48×10^-6）,其稀土配分型式为无MREE富集的平坦型,与Ghaderi等人划分的白钨矿Ⅱ型稀土配分型式总体类似,负铕异常,利用白钨矿La-Ce-Y三角图解,结合地质事实,判断香沟钨矿属于石英脉型钨矿;结合共生方解石Sm-Nd同位素年龄195 Ma,认为南秦岭香沟钨矿是印支末期深部隐伏岩浆-热液活动的结果。     

Re-Os同位素定年对岩浆型Cu-Ni硫化物矿床成矿时代的制约

Re-Os同位素体系被认为是岩浆Cu-Ni硫化物矿床直接定年的有力工具。通过研究世界级典型岩浆Cu-Ni硫化物矿床的Re-Os等时线表面年龄,发现有时能得到成矿年龄,有时得到与成矿年龄不一致的表面年龄或根本得不到Re-Os等时线,还有时同一矿床的不同类型矿石给出不同的Re-Os等时线表面年龄。文章介绍了能够解释上述现象的理论模型。模型预测对与基性-超基性岩共生的Cu-Ni硫化物矿床,除一些特殊情况外,块状矿石可得到有地质意义的Re-Os等时线年龄,浸染状矿石常得到没有地质意义的假等时线;而浸染状矿石常得到有地质意义的Os同位素初始比值,而块状矿石给出的"Os同位素表面初始比值"往往没有地质意义。因此,建议在应用Re-Os同位素体系定年时要结合矿床类型、矿石类型以及成矿过程等因素综合考虑;对Re-Os数据的科学合理解释同样需要从矿床学和同位素地球化学的基本原理出发,结合矿床的实际情况,进行深入分析研究。     

陕西省凤太矿集区二里河铅锌矿床的成矿时代: 来自闪锌矿Rb-Sr同位素年龄的证据

八方山-二里河铅锌矿床位于陕西凤县-太白(简称凤太)矿集区西北部,矿体主要产于中泥盆统古道岭组与上泥盆统星红铺组接触带中,受NWW向八方山-二里河背斜控制。本次工作对二里河铅锌矿床主成矿阶段的闪锌矿进行了Rb-Sr同位素测年研究,获得了等时线年龄为220.7±7.3Ma,表明矿床形成于晚三叠世,该年龄对于整个凤太矿集区的铅锌成矿时代具有同样约束意义。闪锌矿的⁸⁷Sr/⁸⁶Sr_i值为0.714145±0.000031,指示成矿物质可能主要来源于大陆壳。结合前人的研究成果分析认为,二里河铅锌矿床是凤太矿集区在印支期区域性强烈的构造-岩浆-成矿作用过程中的产物。     

Rb-Sr isotopic dating of sphalerite from the giant Huize Zn-Pb ore field,Yunnan Province,Southwestern China

The giant Huize Zn-Pb ore field in Yunnan Province, southwestern China, comprises the Qilinchang and Kuangshanchang deposits. The deposits are large in scale (more than 5 Mt of Zn and Pb) and high in grade (average grade of total Zn and Pb is 30%). Reported in this paper are the results of Rb-Sr isotopic dating of sphalerite from this ore field. Two precise ages (223.5±3.9 Ma and 226±6.4 Ma) have been obtained from two isochrons. These two ages are close to the reported ages of native copper mineralizations...     

云南武定迤纳厂铁-铜-金-稀土矿床成矿物质来源——来自矿床地质与S、Pb、H、O同位素的制约

武定迤纳厂铁铜金稀土矿位于我国云南省中部,扬子板块西缘,康滇地轴云南段。根据矿物组合、围岩蚀变和矿化特征等方面的差异,可将其蚀变矿物组合划分为铁稀土长石硅酸盐组合和铜金石英碳酸盐组合两类,前者发生在矿化中前期,后者发生于矿化后期。铁铜稀土长石硅酸盐组合又可划分为磁铁矿钠长石稀土组合和黄铜矿钾长石石榴子石黑云母组合。分别对黄铜矿钾长石石榴子石黑云母组合中的黄铜矿、萤石,铜金石英碳酸盐组合中的黄铜矿、萤石、石英、方解石开展了S、Pb、H、O同位素的示踪研究。两组黄铜矿的δ34SCDT(‰)值变化范围为-0.44‰~+4.07‰,集中于0值附近,说明其具有单一岩浆来源。后一组黄铜矿单矿物的δ34SCDT(‰)值稍高于前一组合。第一组黄铜矿的Pb同位素组成较为均一,206Pb/204Pb比值范围为37.684~51.112,207Pb/204Pb比值范围为16.939~17.875,208Pb/204Pb比值范围为40.116~41.984,表明其来源单一;而第二组黄铜矿的Pb同位素组成则相对分散且具线性趋势,206Pb/204Pb比值范围为19.523~356.740,207Pb/204Pb比值范围为15.853~41.182,208Pb/204Pb比值范围为39.411~42.010,表明其为混合来源。前一组合中的萤石单矿物δ18OV-SMOW值介于+9.30‰~+10.80‰之间,δDV-SMOW值介于-63.20‰~-80.20‰之间,表明其更具岩浆水性质;后一组合中的石英单矿物δ18OV-SMOW值介于+15.20‰~+18.10‰之间,δDV-SMOW值介于-47.70‰~-91.20‰之间;方解石单矿物δ18OV-SMOW值介于+17.00‰~+19.60‰之间,δDV-SMOW值介于-66.10‰~-98.20‰之间,表明其更具有变质水的特征。     

Evolution of the Yunkai Terrane, South China: Evidence from SHRIMP zircon U–Pb dating, geochemistry and Nd isotope

The Yunkai Terrane is one of the most important pre-Devonian areas of metamorphosed supracrustal and granitic basement rocks in the Cathaysia Block of South China. The supracrustal rocks are mainly schist, slate and phyllite, with local paragneiss, granulite, amphibolite and marble, with metamorphic grades ranging from greenschist to granulite facies. Largely on the basis of metamorphic grade, they were previously divided into the Palaeo- to Mesoproterozoic Gaozhou Complex, the early Neoproterozoic Yunkai ‘Group’ and early Palaeozoic sediments. Granitic rocks were considered to be Meso- and Neoproterozoic, or early Palaeozoic in age. In this study, four meta-sedimentary rock samples, two each from the Yunkai ‘Group’ and Gaozhou Complex, together with three granite samples, record metamorphic and magmatic zircon ages of 443–430 Ma (Silurian), with many inherited and detrital zircons with the ages mainly ranging from 1.1 to 0.8 Ga, although zircons with Archaean and Palaeoproterozoic ages have also been identified in several of the samples. A high-grade sillimanite–garnet–cordierite gneiss contains 242 Ma metamorphic zircons, as well as 440 Ma ones. Three of the meta-sedimentary rocks show large variations in major element compositions, but have similar REE patterns, and have t_DM model ages of 2.17–1.91 Ga and ε_Nd (440 Ma) values of −13.4 to −10.0. Granites range in composition from monzogranite to syenogranite and record t_DM model ages of 2.13–1.42 Ga and ε_Nd (440 Ma) values of −8.4 to −1.2. It is concluded that the Yunkai ‘Group’ and Gaozhou Complex formed coevally in the late Neoproterozoic to early Palaeozoic, probably at the same time as weakly to un-metamorphosed early Palaeozoic sediments in the area. Based on the detrital zircon population, the source area contained Meso- to Neoproterozoic rocks, with some Archaean material. Palaeozoic tectonothermal events and zircon growth in the Yunkai Terrane can be correlated with events of similar age and character known throughout the Cathaysia Block. The lack of evidence for Palaeo- and Mesoproterozoic rocks at Yunkai, as stated in earlier publications, means that revision of the basement geology of Cathaysia is necessary.     

Mineralization age and sources of ore‐forming material of the Nanmushu Zn‐Pb deposit in the Micangshan Tectonic Belt at the northern margin of the Yangtze Craton,China: Constraints from Rb‐Sr dating and Sr‐Pb isotopes

The Nanmushu Zn‐Pb deposit, hosted by the Neoproterozoic Dengying Formation dolostone, is located in the eastern part of the Micangshan tectonic belt at the northern margin of the Yangtze Craton, China. This study involves a systematic field investigation, detailed mineralogical study, and Rb‐Sr and Pb isotopic analyses of the deposit. The results of Rb‐Sr isotopic dating of coexisting sphalerite and galena yield an isochron age of 486.7 ± 3.1 Ma, indicating the deposit was formed during the Late Cambrian to Early Ordovician. This mineralization age is interpreted to be related to the timing of destruction of the paleo‐oil reservoir in the Micangshan tectonic belt. All initial ⁸⁷Sr/⁸⁶Sr ratios of sphalerite and galena (0.70955–0.71212) fall into the range of the Mesoproterozoic Huodiya Group basement rocks (0.70877–0.71997) and Dengying Formation sandstone (0.70927–0.71282), which are significantly higher than those of Cambrian Guojiaba Formation limestone (0.70750–0.70980), Cambrian Guojiaba Formation carbonaceous slate (0.70766–0.71012), and Neoproterozoic Dengying Formation dolostone (0.70835–0.70876). Such Sr isotope signatures suggest that the ore strontium was mainly derived from a mixed source, and both of the Huodiya Group basement rocks and Dengying Formation sandstone were involved in ore formation. Both sphalerite and galena are characterized by an upper‐crustal source of lead (²⁰⁶Pb/²⁰⁴Pb = 17.849–18.022, ²⁰⁷Pb/²⁰⁴Pb = 15.604–15.809, and ²⁰⁸Pb/²⁰⁴Pb = 37.735–38.402), and their Pb isotopes are higher than, but partly overlap with, those of the Huodiya Group basement rocks, but differ from those of the Guojiaba and Dengying Formations. This suggests that the lead also originated from a mixed source, and the Huodiya Group basement rocks played a significant role. The Sr and Pb isotopic results suggest that the Huodiya Group basement rocks were one of the most important sources of metallogenic material. The geological and geochemical characteristics show that the Nanmushu Zn‐Pb deposit is similar to typical Mississippi Valley type, and the fluid mixing may be a reasonable metallogenic mechanism for Nanmushu Zn‐Pb deposit.