Re–Os dating of molybdenite and in-situ Pb isotopes of sulfides from the Lamo Zn–Cu deposit in the Dachang tin-polymetallic ore field, Guangxi, China

The Dachang tin-polymetallic district, Guangxi,China, is one of the largest tin ore fields in the world. Both cassiterite-sulfide and Zn–Cu skarn mineralization are hosted in the Mid-Upper Devonian carbonate-rich sediments adjacent to the underlying Cretaceous Longxianggai granite(91–97 Ma). The Lamo Zn–Cu deposit is a typical skarn deposit in the district and occurs at the contact zone between the Upper Devonian limestone and the granite.The ore minerals mainly consist of sphalerite, arsenopyrite,pyrrhotite, galena, chalcopyrite, and minor molybdenite.However, the age of mineralization and source of the metals are not well constrained. In this study, we use the molybdenite Re–Os dating method and in-situ Pb isotopes of sulfides from the Lamo deposit for the first time in order to directly determine the age of mineralization and the tracing source of metals. Six molybdenite samples yielded a more accurate Re–Os isochron age of 90.0 ± 1.1 Ma(MSWD = 0.72), which is much younger than the reported garnet Sm–Nd isochron age of 95 ± 11 Ma and quartz fluid inclusions Rb–Sr isochron age of 99 ± 6 Ma. This age is also interpreted as the age of Zn–Cu skarn mineralization in the Dachang district. Further, in this study we found that in-situ Pb isotopes of sulfides from the Lamo deposit and feldspars in the district's biotite granite and granitic porphyry dikes have a narrow range and an overlap of Pb isotopic compositions(^(206) Pb/^(204) Pb =18.417–18.594,^(207) Pb/^(204) Pb = 15.641–15.746, and^(208) Pb/^(204) Pb = 38.791–39.073), suggesting that the metals were mainly sourced from Cretaceous granitic magma.

LA-ICP-MS Zircon U-Pb Dating of Intermediate-Acidic Intrusive Rocks and Molybdenite Re-Os Dating from the Bangpu Mo (Cu) Deposit, Tibet and its Geological Implication

The multi-stage intrusions of intermediate-acid magma occur in the Bangpu mining district, the petrogenic ages of which have been identified. The times and sequences of their emplacement have been collated and stipulated in detail in this paper by using the laser ablation-inductively coupled plasma-mass spectrometry （LA-ICP-MS） zircon U-Pb dating method. The ages of biotite monzogranite that were formed before mineralization in the southwest of this mining district are 70±1 Ma （mean square of weighted deviates （MSWD） =9.5, n=8） and 60.60±0.31 Ma （MSWD=3.8, n=16）, which belong to the late Cretaceous-early Paleocene in age. That means, they are products of an early tectonicmagmatic event of the collision between the Indian and Asian continentals. The ages of ore-bearing monzogranite porphyry and ore-bearing diorite porphyrite are 16.23±0.19 Ma （MSWD=2.0, n=26） and 15.16±0.09 Ma （MSWD=3.9, n=5） separately, which belong to the middle Miocene in age; namely, they are products of the Gangdese post-collision extensional stage when crust-mantle materials melted and mixed as well as magmatic intrusion simultaneously occurred. Some zircons with ages of 203.6±2.2 Ma （MSWD=1.18, n=7） were captured in the ore-bearing diorite porphyrite, which shows that there had been tectono-magmatic events in the late Triassic-early Jurassic. Molybdenum （copper） ore-bodies produced in the monzogranite porphyry and copper （molybdenum） ore-bodies produced in the diorite porphyrite are the main ore types in this ore deposit. The model ages of Re-Os isotopic dating for the 11 molybdenite are 13.97-15.84 Ma, while isochron ages are 14.09±0.49 Ma （MSWD=26）. The isochron ages of seven molybdenite from molybdenum （copper） ore with monzogranite porphyry type are 14.11±0.31 Ma （MSWD=5.2）. There is great error in the isochron ages of four molybdenite from copper （molybdenum） ore with diorite porphyrite type, and their weighted average model ages of 14.6±1.2 Ma （MSWD=41）, which generally represent the mineralization age. The results about the Re-Os isotopic dating of molybdenite in the ore of different types have limited exactly that, the minerlazation age of this ore deposits is about 14.09 Ma, which belongs to the middle Miocene mineralization. The Bangpu deposit has a uniform metallogenic dynamics background with the porphyry type and skarn-type deposits such as Jiama, Qulong and others.

LA-ICP-MS Zircon U-Pb Geochronology of the Fine-grained Granite and Molybdenite Re-Os Dating in the Wurinitu Molybdenum Deposit,Inner Mongolia,China

The Wurinitu molybdenum deposit,located in Honggor,Sonid Left Banner of Inner Mongolia,China,is recently discovered and is considered to be associated with a concealed fine-grained granite impregnated with molybdenite.The wall rocks are composed of Variscan porphyritic-like biotite granite and the Lower Ordovician Wubin'aobao Formation.LA-ICP-MS zircon U-Pb dating of the fine-grained granite reveals two stages of zircons,one were formed at 181.7±7.4 Ma and the other at 133.6±3.3 Ma.The latter age is believed to be the formation age of the fine-grained granite,while the former may reflect the age of inherited zircons,based on the morphological study of the zircon and regional geological setting.The Re-Os model age of molybdenite is 142.2±2.5 Ma,which is older than the diagenetic age of the fine-grained granite.Therefore the authors believe that the metallogenic age of the Wurinitu molybdenum deposit should be nearly 133.6±3.3 Ma or slightly later,i.e.,Early Cretaceous.Combined with regional geological background research,it is speculated that the molybdenum deposits were formed at the late Yanshanian orogenic cycle in the Hingganling-Mongolian orogenic belt,belonging to the relaxation epoch posterior to the compression and was associated with the closure of the Mongolia-Okhotsk Sea.

A Study of the Rhenium-Osmium Geochronometry of Molybdenites

This study deals with the first application of the isotope dilution - inductively coupled plasma mass spectrometry in the rhenium-osmium geochronometry in China. The chemical separation procedure included decomposition of samples by means of alkali fusion, extraction of rhenium by acetone and extraction of osmium by distillation. The recovery of both elements in the entire process was more than 90% . The blanks of analyses were 0.07 ng for rhenium and 0.01 ng for 187Os. The mineralization ages of molybdenites from four molybdenum deposits in China were determined by using this method, with a precision (2σ)of about ±3% . These results agree satisfactorily with their geological backgrounds. The Re-Os method can directly determine ages of metal deposits and reflect the true ages more reliably than other dating methods that only determine the ages of country rocks from which mineralization ages are inferred. As many hydrothermal sulphide deposits usually contain molybdenites, this method has bright prospects of wide application.

Timing of carbonatite-hosted U-polymetallic mineralization in the supergiant Huayangchuan deposit,Qinling Orogen:Constraints from titanite U-Pb and molybdenite Re-Os dating

The newly-discovered supergiant Huayangchuan uranium(U)-polymetallic(Sr,Se,REEs,Ba,Nb and Pb)deposit is located in the Qinling Orogen,central China.The deposit underwent multistage mineralization,with the main carbonatite ore stage being the most important for the U,Nb,REE,Sr and Ba endowments.According to the mineral assemblages,the main carbonatite ore stage can be divided into three substages,i.e.,sulfate(Ba-Sr),alkali-rich U and REE-U mineralization.Main-stage titanite from the Huayangchuan igneous carbonatite are rich in high field strength elements(HFSEs,e.g.,Zr,Nb and REEs),and show clear elemental substitutions(e.g.,Ti vs.Nb+Fe+Al and Ca+Ti vs.Fe+Al+REE).High-precision LA-ICP-MS titanite dating yielded a U-Pb age of 209.0±2.9 Ma,which represents the mainstage mineralization age at Huayangchuan,and is coeval with the local carbonatite dyke intrusion.This mineralization age is further constrained by the Re-Os dating of molybdenite from the Huayangchuan carbonatite,which yielded a weighted mean age of 196.8±2.4 Ma.Molybdenite Re contents(337.55-392.75 ppm)and C-OSr-Nd-Pb isotopic evidence of the Huayangchuan carbonatite both suggest a mantle origin for the carbonatite.Our study supports that the Late Triassic carbonatite magmatism was responsible for the world-class U-Mo-REE mineralization in the Qinling Orogen,and that the regional magmatism and ore formation was likely caused by the closure of the Mianlue ocean and the subsequent North China-South China continent-continent collision.

Molybdenite Re-Os,titanite and garnet U-Pb dating of the Magushan skarn Cu-Mo deposit,Xuancheng district,Middle-Lower Yangtze River Metallogenic Belt

The Magushan skarn Cu-Mo deposit is a representative example of the skarn mineralization occurring within the Xuancheng ore district of the Middle-Lower Yangtze River Metallogenic Belt of eastern China.The precise age of an ore deposit is important for understanding the timing of mineralization relative to other geological events in a region and to fully place the formation of a mineral deposit within the geological context of other processes that occur within the study area.Here,we present new molybdenite Re-Os and titanite and andradite garnet U-Pb ages for the Magushan deposit and use these data to outline possible approaches for identifying genetic relationships in geologically complex areas.The spatial and paragenetic relationships between the intrusions,alteration,and mineralization within the study area indicates that the formation of the Magushan deposit is genetically associated with the porphyritic granodiorite.However,this is not always the case,as some areas contain complexly zoned plutons with multiple phases of intrusion or mineralization may be distal from or may not have any clear spatial relationship to a pluton.This means that it may not be possible to determine whether the mineralization formed as a result of single or multiple magmatic/hydrothermal events.As such,the approaches presented in this study provide an approach that allows the identification of any geochronological relationships between mineralization and intrusive events in areas more complex than the study area.Previously published zircon U-Pb data for the mineralization-related porphyritic granodiorite in this area yielded an age of 134.2±1.2 Ma(MSWD=1.4)whereas the Re-Os dating of molybdenite from the study area yielded an isochron age of 137.7±2.5 Ma(MSWD=0.43).The timing of the mineralizing event in the study area was further examined by the dating of magmatic accessory titanite and skarn-related andradite garnet,yielding U-Pb ages of 136.3±2.5 Ma(MSWD=3.2)and 135.9±2.7 Ma(MSWD=2.5),respectively.The dating of magmatic and hydrothermal activity within the Magushan area yields ages around 136 Ma,strongly suggesting that the mineralization in this area formed as a result of the emplacement of the intrusion.The dates presented in this study also provide the first indication of the timing of mineralization within the Xuancheng district.providing evidence of a close genetic relationship between the formation of the mineralization within the Xuancheng district and the Early Cretaceous magmatism that occurred in this area.This in turn suggests that other Early Cretaceous intrusive rocks within this region are likely to be associated with mineralization and should be considered highly prospective for future mineral exploration.This study also indicates that the dating of garnet and titanite can also provide reliable geochronological data and evidence of the timing of mineralization and magmatism,respectively,in areas lacking other dateable minerals(e.g.,molybdenite)or where the relationship between mineralization and magmatism is unclear,for example in areas with multiple stages of magmatism,with complexly zoned plutons,and with distal skarn mineralization.

Re-Os Isotopic Age of Molybdenite of the Jingren Deposit and its Mineralogical Significance of Magnetite,Pyrite and Chalcopyrite

The Jingren deposit is part of the Qimantage metallogenic belt within the eastern Kunlun orogenic belt,the largest metallogenic belt in Qinghai Province,northwestern China.Exploration data show that the metal resources of the Jingren deposit are greater than 93000 t in a mining area of 76.15 km2,which indicates significant exploration potential in the near future.Three W–E-trending faults,F1-3,dominate the extension of the mineralization zone,which consists of chalcopyrite,pyrite,magnetite,galena,sphalerite,and molybdenite as well as bismuth-bearing minerals.The deposit contains a large amount of late Triassic intrusive rocks,however,previous research did not reach a consensus on the timing or the origin of the mineralization owing to a lack of geochronological data and poor exposure conditions.In the present study,Re-Os isotopic dating from six molybdenite samples collected from a borehole of the granodiorite in the Jingren deposit using negative thermal ionization mass spectrometry(NTIMS)showed 187 Re and 187 Os concentrations of 0.26–4.40 ppm and 1.03–16.46 ppb,respectively,with an initial 187 Os/188 Os value of 0.06±0.19.This proves that the Jingren deposit has a metallogenic age of(225±4)Ma and is the product of united mineralization of the Qimantage metallogenic belt and that the Jingren deposit might actually be an Indosinian metallogeny.In addition,the Re content of these samples,at 0.42 ppm to 7.00 ppm shows that the mineralization was derived mainly from a crustal source.Furthermore,electron probe microanalysis(EPMA)conducted on chalcopyrite obtained from 22 metallic mineral samples revealed(Fe+Cu)/S ratios of 1.801–1.947 with an average of 1.852,which is lower than the ideal value(1.875).Besides,the main ore body formed in a relatively higher temperature environment than the surrounding rocks in the Jingren deposit.These data indicate that the Jingren deposit formed in a metallogenic environment at lower temperature.Moreover,according to the TiO_(2)-Al_(2)O_(3)-(MgO+MnO)and TiO_(2)-Al_(2)O_(3)-MgO genetic classification diagram for magnetite,the Jingren deposit most likely belongs to the skarn family.In addition,the Co-Ni-As genetic classification diagram of the pyrite indicates sedimentary and skarn genetic characteristics.

湖北蕲春烈马咀花岗岩成因及与钼成矿的关系

湖北蕲春烈马咀钼矿位于大别山南坡,已探明的大型钼矿鲜有报道,对该矿区的深入研究甚少,缺少对成岩成矿时代、成因和构造背景的准确厘定。对烈马咀钼矿及与成矿有关的花岗岩进行了岩相学、岩石地球化学研究和Re−Os同位素测年。结果表明:与成矿有关的岩石为斑状二长花岗岩或二长花岗斑岩,矿区成矿规模小,矿石为浸染状或细脉浸染状展布;辉钼矿等时线年龄为119±8 Ma,年龄加权平均值为118.9±0.98 Ma,指示烈马咀钼矿为早白垩世热液产物;岩石地球化学数据表明其为高硅、高钾钙碱性系列A型花岗岩;稀土元素的总含量高,轻稀土元素含量相对富集,重稀土元素含量相对亏损。烈马咀钼矿区与成矿有关的岩石形成于大别造山带伸展环境,与燕山晚期岩石圈减薄有关。

腾冲地块晚白垩世小龙河花岗岩年龄及其成矿意义

为厘定腾冲地块晚白垩世构造岩浆活动和花岗岩成矿意义,对小龙河花岗岩开展全岩地球化学、年龄和锶-钕-铅同位素研究。小龙河花岗岩由细粒淡色二长花岗岩和似斑状黑云母二长花岗岩组成,锆石U-Pb年龄数据指示它们的岩浆结晶年龄分别为67.0±1.0 Ma和68.5±1.6 Ma,辉钼矿Re-Os模式年龄分别为67.15±0.99 Ma和69.02±1.22 Ma,同为晚白垩世构造岩浆活动产物。锶-钕-铅同位素与主量和微量元素特征表明,细粒淡色二长花岗岩为S型花岗岩((^(87)Sr/^(86)Sr)_(i)=0.757~0.763);ε_(Nd)(t)=-8.89~-8.99,岩浆起源于中元古代(TDM2=1.59~1.60 Ga)上地壳富粘土硬砂岩部分熔融,其与小龙河锡-钨多金属矿床形成密切相关;似斑状黑云母二长花岗岩为I型花岗岩((^(87)Sr/^(86)Sr)_(i)=0.711,ε_(Nd)(t)=-8.72~-9.16),岩浆起源于中元古代(TDM2=1.58~1.62 Ga)下地壳富粘土硬砂岩重熔。腾冲地块晚白垩世小龙河花岗岩及其锡-钨矿化是中特提斯班公-怒江洋闭合后腾冲地块与保山地块碰撞-后碰撞阶段引发的岩浆活动与热液作用的产物。

内蒙古乌尔根东部斑岩型钼矿床成矿期次

内蒙古额尔古纳市乌尔根东部斑岩型钼矿床位于大兴安岭北段,通过野外实际调查和矿相学研究发现,该矿床存在2类明显不同的辉钼矿。结合电子探针、Re-Os同位素测试和流体包裹体测试,发现2类辉钼矿在主量元素S、Mo组成和微量元素组合上均存在着明显不同。辉钼矿存在2组年龄:1组为136.4 Ma;另1组为146.0 Ma。综合分析认为,乌尔根东部钼矿床形成于晚侏罗—早白垩世,矿床存在2次沸腾作用,导致辉钼矿经历2次成矿,矿床存在着2期辉钼矿矿化。

南秦岭冷水沟铜钼金矿床年代学及其地质意义

冷水沟铜钼金矿床位于南秦岭山阳—柞水矿集区内,是南秦岭晚中生代斑岩-矽卡岩型铜(钼)矿床的代表性矿床之一。冷水沟矿区内除斑岩-矽卡岩型铜钼矿体外,还发育构造蚀变岩型金矿体,但对于铜钼矿化与金矿化之间是否存在成因联系一直存在疑惑。本次通过对斑岩-矽卡岩型铜钼矿体中辉钼矿与构造蚀变岩型金矿体中蚀变钾长石和绢云母分别进行Re-Os和^(40)Ar-^(39)Ar定年,以期能够通过成矿年代学研究来厘定两者之间的成因联系。测试结果显示,斑岩-矽卡岩型铜钼矿体的辉钼矿Re-Os等时线年龄为(147.4±8.4)Ma,构造蚀变岩型金矿体中蚀变钾长石和绢云母^(40)Ar-^(39)Ar年龄约为144 Ma,两者在误差范围内一致,说明铜钼矿体和金矿体均形成于晚侏罗世—早白垩世,是同一成矿作用的产物,并与区域内晚侏罗世—早白垩世岩浆岩具有密切的成因联系。结合区域构造演化特征,本次研究结果显示冷水沟铜钼金矿床形成于晚中生代秦岭造山带构造体制转变的动力学背景。同时,冷水沟地区金矿成矿时代的限定也表明南秦岭地区存在晚侏罗世—早白垩世金矿成矿作用。

内蒙古东七一山花岗质杂岩的形成演化及对成矿的贡献:年代学及地球化学证据

内蒙古东七一山钨多金属矿位于北山造山带东段,是一个以钨为主,共伴生锡、钼、铷、铍、铌、钽、铁和萤石的综合型矿床。本次工作对含矿花岗质杂岩开展了岩石学、地球化学、锆石U-Pb及辉钼矿Re-Os年代学研究。富W-Sn-Mo花岗岩岩性为细粒似斑状二长花岗岩、中细粒似斑状二长花岗岩、花岗斑岩,结晶年龄分别为220.6±1.6Ma、220.4±1.3Ma和220.0±1.1Ma。富Rb-Be-Nb-Ta花岗岩岩性为中粗粒钠长石化似斑状二长花岗岩,结晶年龄为219.9±1.9Ma。辉钼矿Re-Os定年获得加权平均年龄为211±1Ma(MSWD=0.83),说明成岩成矿发生在晚三叠世。含矿花岗质杂岩均具有高硅、富碱、贫铁镁钙特征,为高钾钙碱性花岗岩。其中,富W-Sn-Mo花岗岩为准铝质-过铝质花岗岩;而富Rb-Be-Nb-Ta花岗岩为强过铝质花岗岩。杂岩体轻重稀土具一定分馏,呈现显著的负Eu异常,均富集Rb、K、U、Ta,强烈亏损Ba、Nb、Sr、P、Ti、Zr、Hf。与富W-Sn-Mo花岗岩相比,富Rb-Be-Nb-Ta花岗岩具更低的稀土总量,更显著的Eu负异常,并显示微弱的稀土四分组效应,更高的Li、Ta含量,更低的P、Ti、Zr、Hf、W、Mo、Bi含量。时空关系和地球化学特征表明,杂岩体为同一次岩浆活动不同演化阶段的产物,均经历了较高程度的结晶分异和较强的熔体-流体相互作用。相比而言,富Rb-Be-Nb-Ta花岗岩比富W-Sn-Mo花岗岩结晶分异程度更高,熔体-流体作用更强,花岗质岩浆的高程度分离结晶和熔体-流体相互作用是形成该杂岩体并促使成矿的重要控制因素。

海南岛石门山钼多金属矿床年代学、源区特征及其岩浆氧逸度对成矿作用的启示

石门山钼(铅‒锌‒银)多金属矿床为中等规模(金属Mo=1万吨)、高品位(Mo=0.17%)的斑岩型矿床,位于海南岛西南部近东西向九所‒陵水断裂带北西侧的千家复式岩体内,赋矿岩石主要为黑云二长花岗岩和云英岩,矿石类型主要为石英脉型和云英岩型。为了精确厘定该矿床的年代学格架,进一步了解岩石源区特征和成岩成矿的物理化学条件,对采自矿区内的黑云二长花岗岩进行了LA-ICP-MS锆石U-Pb定年,获得^(206)Pb/^(238)U加权平均年龄为94.5±1.6 Ma(MSWD=3.7,n=16),同时分别获得1件石英脉型和云英岩型辉钼矿Re-Os同位素模式年龄为77.9±0.6 Ma、89.6±2.4 Ma。结合已报道的年代学数据,发现该矿床具有明显的两个钼成矿期,分别为89~90 Ma和78~80 Ma,均为晚白垩世早期的产物,且成岩与早期成矿时差接近,具有同源的可能性;黑云二长花岗岩锆石ε_(Hf)(t)值为−10.20~−2.52,二阶段地壳模式年龄t_(DM2)峰值为1.4~1.5 Ga,表明其主要来源于中元古代下地壳的重熔,该时期可能是海南岛钼矿床赋矿花岗质围岩源区的主要形成时期。两种方法计算的全岩锆饱和温度分别为729~785℃(平均753℃)、679~744℃(平均700℃),锆石Ti温度为604~760℃(平均676℃),反映其源区很可能经历了富水条件下的熔融过程。锆石氧逸度计算结果表明其源区处于较强的氧化环境,有利于该矿床的形成。

Re-Os isotope dating of molybdenites in the Huang-shaping Pb-Zn-W-Mo polymetallic deposit, Hunan Province, South China and its geological significance

The large-scale Huangshaping Pb-Zn-W-Mo polymetallic deposit is located in the central Nanling min- eralization zone, South China. Six molybdenite samples from the Huangshaping deposit were selected for Re-Os isotope measurement in order to define the mineralization age of the deposit. It yields a Re-Os isochron age of 154.8±1.9 Ma (2σ ), which is in accordance with the Re-Os model ages of 150.9― 156.9 Ma. This age is about 7 Ma younger than their host granite porphyry, which was dated as 161.6±1.1 Ma by zircon U-Pb method using LA-ICPMS. All these ages demonstrate that the Huang- shaping granite and related Pb-Zn-W-Mo deposit occurred in the middle Yanshanian period, when many other granitoid and related ore deposits emplaced and formed, e.g. the Qitianling granite and Furong tin deposit, the Qianlishan granite and giant Shizhuyuan W-Sn-Mo-Bi deposit and Jinchuantang Sn-Bi deposit in the nearby area. They constitute the main part of the magmatic-metallogenic belt of southern Hunan, and represent the large-scale metallogeny in middle Yanshanian in the area. The lower rhenium content in molybdenite of Huangshaping deposit suggests that the ore-forming material was mainly of crust origin.

内蒙古扎拉格阿木铜多金属矿床硫化物Re-Os年龄及其地质意义

内蒙古扎拉格阿木铜多金属矿床是近年来在大兴安岭中南段西坡发现的一处中型铜多金属矿床。矿床产出于花岗闪长岩体与中二叠统哲斯组外接触带,矿体分布受北东向断裂构造控制。本文运用Re-Os同位素定年法对主成矿阶段形成的辉钼矿和毒砂开展了成矿年龄测定,获得1件辉钼矿Re-Os模式年龄为141.81±0.84 Ma,3件毒砂Re-Os模式年龄分别为138.1±0.9、140.8±7.7和141.2±2.1 Ma,等时线年龄为137.7±1.7 Ma;4件样品的加权平均年龄为140.2±3.3 Ma。结果表明,该矿床形成于早白垩世,为燕山晚期构造-岩浆-成矿作用耦合的产物。扎拉格阿木铜多金属矿床成矿年龄的首次厘定,对该区铜多金属矿的勘查和矿床成因研究具有指示意义。

小秦岭金(钼)矿床辉钼矿铼-锇定年及其地质意义

最近在河南灵宝小秦岭地区大湖金矿及其附近的泉家峪含金石英脉中发现了具有工业价值的钼矿化。为了研究小秦岭金矿集中区钼矿的成矿时代,笔者选取大湖金(钼)矿床及泉家峪石英脉型金钼矿体中的辉钼矿进行了Re-Os法同位素定年,在大湖钼金矿石中获得3个辉钼矿样品的Re-Os模式年龄,分别为(223.0±2.8)Ma、(223.7±2.6)Ma和(232.9±2.7)Ma;泉家峪钼金矿石中2个辉钼矿样品的Re-Os模式年龄分别为(129.1±1.6)Ma和(130.8±1.5)Ma。这些年龄数据表明,该区的成矿作用不仅发生于燕山期,而且还发生在印支期。与金堆城、黄龙铺等典型钼矿床不同,大湖和泉家峪矿床中辉钼矿含铼很低,可能表明它们的成矿物质来自壳源。

西藏工布江达地区亚贵拉铅锌钼矿床辉钼矿Re-Os测年及其地质意义

为确定念青唐古拉成矿带斑岩型矿床的成矿时间,对亚贵拉铅锌钼多金属矿集区斑岩钼矿的5件辉钼矿样品进行了Re-Os同位素分析,所获辉钼矿模式年龄在(64.27±0.90)～(65.97±1.13)Ma范围内,等时线年龄为(65.0±1.9)Ma(MSWD=3.2)。亚贵拉辉钼矿属主碰撞期成矿,成矿与短期内大规模的岩浆活动有关,暗示念青唐古拉—冈底斯地区存在大规模的主碰撞期成矿作用。

汝城高坳背钨—钼矿区花岗岩锆石U-Pb年龄、Hf同位素及矿石辉钼矿Re-Os年龄

湖南汝城高坳背钨—钼矿床是湘南地区近年发现的远景规模达大型或超大型的黑钨矿石英脉型热液钨—钼矿床,然而对该矿床与成矿有关的花岗岩的成岩年龄和钨—钼成矿年龄还缺乏研究。本文利用锆石SHRIMP U-Pb同位素定年方法对该矿区黑云母二长花岗岩进行了年龄测定,获得其侵位年龄为222.1±2.0Ma,其中还发现其锆石内核含古元古代—新太古代的继承锆石。晚三叠世年龄的锆石具低的εHf(t)值(-4.7～-10.9)和1.6～2.0Ga的Hf同位素两阶段模式年龄,表明它们的岩浆源区主要以华南古元古代基底物质或者更古老的基底物质改造而成。古元古代—新太古代继承锆石中正的εHf(t)值(4.3～8.5)的存在,暗示形成这些古老继承锆石的初始物质中有幔源物质的加入。利用辉钼矿Re-Os等时线法,获得该矿的成矿年龄为157.3±6.6Ma(n=5,MSWD=0.11)。高坳背钨—钼矿区黑云母二长花岗岩锆石年龄、Hf同位素资料和钨钼矿成矿年龄表明,花岗岩中存在古老地壳的残留锆石,说明花岗岩的物质来源可能与华南古老的陆壳基底有关,钨钼矿区黑云母二长花岗岩成岩时代为晚三叠世,而成矿时代为晚侏罗世,推测该矿深部有晚侏罗世的花岗岩存在。这些新的同位素年龄资料为研究华南同类矿床的形成演化与指导区域找矿提供了重要的地球化学依据。

山东孔辛头铜钼矿成矿时代及物质来源:来自黄铜矿、辉钼矿Re-Os同位素证据

孔辛头铜钼矿床产于胶东地区伟德山超单元院格庄二长花岗岩与荆山群大理岩接触带形成的夕卡岩中,主矿体呈透镜状、囊状、脉状产出,受岩体内部裂隙构造控制。分别采用电感耦合等离子体质谱、热表面电离质谱Re-Os同位素测试技术对其中的辉钼矿、黄铜矿、磁铁矿进行了研究。结果显示,辉钼矿Re-Os等时线年龄为117±1 Ma,黄铜矿Re-Os等时线年龄为118.4±3.2 Ma,与区域上尚家庄钼矿床、冷家钼矿床成矿时代一致,几个矿床成因均与伟德山超单元有关,表明了胶东地区存在燕山晚期的钼矿化事件。而磁铁矿Re-Os封闭性较差,无法得到年龄。黄铜矿初始^(187)Os/^(188)Os值为0.32±0.17,表明了孔辛头铜钼矿床金属成矿物质为壳幔混合来源,形成于早白垩世太平洋板块向亚欧大陆俯冲而成的弧后拉张背景之下。

湖南宝山铜-钼多金属矿床成岩成矿的U-Pb和Re-Os同位素定年研究

湖南宝山是一个 Cu-Mo-Pb-Zn-Ag 多金属矿床,成因上与花岗斑岩、花岗闪长斑岩关系密切,矿床以宝岭倒转背斜(宝山中区)为中心,空间上具有明显的蚀变与矿化分带,其中心部位(宝山中区)的矿体产在花岗闪长斑岩(花岗斑岩)的内外接触带,围岩蚀变主要为矽卡岩化,成矿元素组合以 Cu-Mo 为主,而宝山东区、宝山西区及北部的财神庙矿区则主要为产于石炭系碳酸盐岩中的铅锌艰矿化。通过对与成矿作用关系密切的花岗闪长斑岩中锆石 SHRIMP U-Pb 同位素测年,获得了高精度的花岗闪长斑岩的成岩年龄为158±2Ma (MSWD=0.26,Probability=0.61,n=12),与前人(伍光英等,2005)的 SHRIMP 数据合并计算则可得到一个161±1Ma(MswD=0.66,Probability=0.42,n=23)的高精度 U-Pb 和谐年龄。该年龄可以代表宝山矿区中酸性小岩体的成岩年龄。通过对含矿矽卡岩中辉钼矿 Re-Os 同位素测年,获得辉钼矿的成矿年龄为160±2Ma。因此,本文认为宝山矿床成岩与成矿具有同时性,花岗闪长斑岩与宝山矿床的形成有成因联系。通过对区域上已获得的成岩-成矿年龄资料的综合对比分析,表明湘南乃至整个南岭中段地区中生代大规模岩浆作用与成矿第一高峰期为155～165Ma,宝山多金属矿床正是华南这一高峰期的产物。这为进一步研究区域成矿规律提供了重要同位素年代学依据。