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1.
江西省武功山地区浒坑钨矿床辉钼矿Re-Os年龄及其地质意义 总被引:7,自引:0,他引:7
浒坑钨矿床是位于江西省中部武功山成矿带的大型石英脉型黑钨矿床。为了确定该矿床的成矿时代,笔者选取了浒坑含钨石英脉中与黑钨矿共生的辉钼矿进行了高精度Re-Os同位素定年,并获得5个辉钼矿样品的Re-Os等时线年龄和模式加权平均年龄分别为150.2±2.2Ma和149.82±0.92Ma。测年数据表明浒坑钨矿床的成矿时代为150Ma左右,是华南地区中生代大规模成岩成矿作用高峰期的产物。辉钼矿含铼较低,表明成矿物质可能为地壳来源,与形成浒坑花岗岩体的燕山期重熔S型花岗岩岩浆活动有关。该矿床形成于燕山期岩石圈伸展减薄环境。 相似文献
2.
赣南崇义地区淘锡坑钨矿的地质特征与成矿时代 总被引:55,自引:0,他引:55
江西省崇义县淘锡坑钨矿区位于南岭东西向构造带东段与武夷山北东-北北东向构造带南段的复合部位,是九龙脑-淘锡坑矿田的一个重要矿区,属于以石英脉型黑钨矿为主的钨多金属矿床.矿脉穿切于震旦系中,成矿主要受北西向断裂控制,成因与燕山期岩浆作用有关.选取含矿石英脉中与黑钨矿共生的辉钼矿进行Re-Os等时线年龄的测定,得到辉钼矿的等时线年龄为154 4Ma±3.8Ma,黑钨矿的模式年龄为164.0Ma±2.7Ma,表明该矿床形成于燕山早期. 相似文献
3.
湘西大溶溪钨矿床中辉钼矿Re-Os同位素定年及其地质意义 总被引:9,自引:2,他引:7
湘西大溶溪钨矿床,为雪峰隆起区内的一个中型白钨矿矿床。文章对该矿床中穿插钨矿体的含辉钼矿石英脉进行了Re-Os同位素年代学研究。分析结果显示,该矿中辉钼矿的Re-Os同位素模式年龄为217.0~221.1 Ma,平均为(219.0±1.2) Ma,其对应的等时线年龄为(223.3±3.9) Ma,揭示其形成于晚三叠世。这些年龄数据与矿区内大神山花岗岩的侵位时间〔(224.3±1.0) Ma〕基本吻合,表明该区含辉钼矿石英脉的形成与花岗岩的侵位具有密切的时、空联系。考虑到该区钨矿体的形成时间介于花岗岩和含辉钼矿石英脉之间,因此,推断大溶溪钨矿床形成于223 Ma左右。该研究成果,不仅为湘西雪峰隆起区存在多期次的钨成矿事件提供了可靠证据,同时又进一步证实了华南地区确实存在一次区域性的与印支期花岗岩有关的成矿作用。 相似文献
4.
《华南地质与矿产》2015,(4)
雅山钨矿(W-Mo)和下桐岭钨钼铋铍矿(W-Mo-Bi-Be)是江西武功山地区典型的石英脉型钨矿床,二者的成矿元素组合略有差异,但二者的成矿时代是否存在差异尚不十分清楚。为了确定二者成矿年代,通过选取雅山钨矿和下桐岭钨矿石英脉中与黑钨矿伴生的辉钼矿进行了Re-Os同位素定年,获得了雅山钨矿3个辉钼矿Re-Os同位素等时线年龄和模式加权平均年龄分别为156.0±2.8 Ma和156.0±2.4 Ma;下桐岭钨矿4个辉钼矿Re-Os同位素等时线年龄和模式加权平均年龄分别为156.4±8.7 Ma和156.1±2.1 Ma;在误差范围内,说明二者的成矿时代基本一致。研究表明,雅山钨矿和下桐岭钨矿床与武功山地区浒坑钨矿成矿年代一致,与华南地区大规模钨锡成矿作用的时代基本一致(170~150 Ma),均形成于晚侏罗世。 相似文献
5.
湘西大溶溪钨矿床,为雪峰隆起区内的一个中型白钨矿矿床。文章对该矿床中穿插钨矿体的含辉钼矿石英脉进行了Re-Os同位素年代学研究。分析结果显示,该矿中辉钼矿的Re-Os同位素模式年龄为217.0~221.1 Ma,平均为(219.0±1.2)Ma,其对应的等时线年龄为(223.3±3.9)Ma,揭示其形成于晚三叠世。这些年龄数据与矿区内大神山花岗岩的侵位时间〔(224.3±1.0)Ma〕基本吻合,表明该区含辉钼矿石英脉的形成与花岗岩的侵位具有密切的时、空联系。考虑到该区钨矿体的形成时间介于花岗岩和含辉钼矿石英脉之间,因此,推断大溶溪钨矿床形成于223 Ma左右。该研究成果,不仅为湘西雪峰隆起区存在多期次的钨成矿事件提供了可靠证据,同时又进一步证实了华南地区确实存在一次区域性的与印支期花岗岩有关的成矿作用。 相似文献
6.
赣南樟东坑钨矿具有典型的"上脉(黑钨矿石英脉)下体(蚀变细粒花岗岩)"和"上钨下钼"矿化模式, 为了弄清黑钨矿石英脉与蚀变细粒岩体型矿化之间在成矿时间上的关系, 对产于该矿细粒花岗岩中的辉钼矿和石英脉中的辉钼矿分别进行了Re-Os同位素定年. 测试结果为: 细粒花岗岩中的3件辉钼矿样品Re-Os等时线年龄为155.4±2.1 Ma(MSWD=1.12), 模式年龄154.9±2.6 Ma~156.5 ± 2.6 Ma, 加权平均年龄155.5±1.4 Ma(MSWD=0.44);而石英脉中5件辉钼矿样品的Re-Os等时线年龄为154.6±1.7 Ma(MSWD=0.030), 模式年龄变化范围为154.2±2.3 Ma~154.7±2.7 Ma, 加权平均年龄为154.29±0.98 Ma(MSWD=0.045). 上述结果表明, 花岗岩体型矿化与石英脉型矿化的年龄在误差范围内高度一致, 从而证明了岩体中的钼钨矿化与石英脉中的钨钼矿化为同一次岩浆热液矿化事件的产物. 相似文献
7.
赣南樟东坑钨矿具有典型的"上脉(黑钨矿石英脉)下体(蚀变细粒花岗岩)"和"上钨下钼"矿化模式,为了弄清黑钨矿石英脉与蚀变细粒岩体型矿化之间在成矿时间上的关系,对产于该矿细粒花岗岩中的辉钼矿和石英脉中的辉钼矿分别进行了Re-Os同位素定年.测试结果为:细粒花岗岩中的3件辉钼矿样品Re-Os等时线年龄为155.4±2.1Ma(MSWD=1.12),模式年龄154.9±2.6Ma~156.5±2.6Ma,加权平均年龄155.5±1.4Ma(MSWD=0.44);而石英脉中5件辉钼矿样品的Re-Os等时线年龄为154.6±1.7Ma(MSWD=0.030),模式年龄变化范围为154.2±2.3Ma~154.7±2.7Ma,加权平均年龄为154.29±0.98Ma(MSWD=0.045).上述结果表明,花岗岩体型矿化与石英脉型矿化的年龄在误差范围内高度一致,从而证明了岩体中的钼钨矿化与石英脉中的钨钼矿化为同一次岩浆热液矿化事件的产物. 相似文献
8.
赣南崇义—大余—上犹矿集区不同类型含矿石英中白云母40Ar/39Ar年龄及其地质意义 总被引:14,自引:0,他引:14
崇义—大余—上犹矿集区是世界著名的黑钨矿床集中区,本文选择钨锡多金属硫化物石英脉型(柯树岭和漂塘矿床)和锡钨石英脉型(仙鹅塘矿床)3个矿床石英中的白云母开展40Ar/39Ar年代学研究,测得坪年龄分别是:钨锡多金属硫化物石英脉型是 158.9 ± 1.4 Ma(漂塘)、158.8 ± 1.2 Ma(柯树岭);钨锡石英脉型的是231.4 ± 2.4 Ma(仙鹅塘),在反等时线图上,其对应的截距年龄分别是158.8 ± 1.6 Ma、158.7 ± 1.9Ma和232.5 ± 2.4 Ma。由此表明,在崇余犹矿集区内存在两个不同成矿时期,即以黑钨矿为主的多金属硫化物石英脉型矿床形成于中侏罗世,集中于160~150Ma之间,与南岭地区钨锡矿床的主成矿期是一致的;而以锡石为主的,并含有大量白钨矿的石英脉型矿床可形成于印支期 相似文献
9.
赣南兴国县张家地钼钨矿床成岩成矿时代及地质意义 总被引:1,自引:0,他引:1
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。 相似文献
10.
粤西大金山钨锡多金属矿床地质特征及成岩成矿年代学研究 总被引:3,自引:2,他引:1
粤西大金山钨锡多金属矿是一个近年新发现的与花岗岩有关的石英脉型钨锡多金属矿,目前估算的资源量已达中型,并具有大型矿床的找矿潜力。矿体形态简单,主要以石英脉的形式产出,由石英脉、云英岩脉和多金属硫化物石英脉等组成。钨锡多金属矿化的主要类型为细脉状和网脉状,围岩蚀变主要有硅化、云英岩化和绿泥石化等。本文在详细介绍矿床地质特征的基础上,对矿床进行了成岩成矿年代学研究。采用LA-MC-ICP-MS锆石U-Pb测年技术,得到了花岗岩的成岩年龄:中细粒黑云母花岗岩形成于82.89±0.35Ma~85.6±0.52Ma,似斑状黑云母花岗岩形成于75.01±0.16Ma~84.17±0.34Ma。通过对与中细粒黑云母花岗岩有关的5件石英脉型辉钼矿进行Re-Os同位素分析,获得其模式年龄为80.07±1.19Ma~84.93±1.42Ma。以上年代学测试结果说明大金山钨锡多金属矿成岩成矿时代为晚白垩世,成岩成矿作用基本同时。本文认为大金山钨锡多金属矿成岩成矿作用发生在华南晚中生代岩石圈拉张-伸展的构造背景下,是华南晚中生代大规模成岩成矿作用的产物。 相似文献
11.
The Hukeng tungsten deposit, located in the Wugongshan area in central part of Jiangxi province, South China, is a large-scale quartz-vein wolframite deposit. It is hosted in the Hukeng granitic intrusion. Based on the mineral assemblage and crosscutting relationship of the veins, three mineralization stages are identified, including: (1) quartz–wolframite stage, (2) quartz–fluorite–wolframite stage, and (3) quartz–pyrite–sphalerite–wolframite stage.The homogenization temperatures of fluid inclusions in vein quartz vary from 220 to 320 °C, and the salinities are from 0 to 10 wt.% NaCl equiv.; corresponding densities range from 0.7 to 1 g/cm3. These features indicated that the ore-forming fluids in the Hukeng tungsten deposit have medium temperature, low density and low salinity.The δ18OSMOW values of quartz range from 10.8‰ to 14.4‰, with corresponding δ18Ofluid values of 3.7‰ to 7.7‰, and δD values of fluid inclusions of between ? 70‰ and ? 55‰. The combined isotopic data indicate that the ore-forming fluids of the Hukeng tungsten deposit were mainly derived from magmatic water, with some minor input from meteoric water.We have carried out molybdenite Re–Os and muscovite 40Ar/39Ar dating to constrain the timing of mineralization. Re–Os dating of six molybdenite samples yielded model ages ranging from 149.1 ± 2.0 to 150.7 ± 3.7 Ma, with an average of 150.0 Ma. The Re–Os analyses give a well-defined 187Re/187Os isochron with an age of 150.2 ± 2.2 Ma (MSWD = 0.60). Hydrothermal muscovite yields a plateau 40Ar/39Ar age of 147.2 ± 1.4 Ma. 40Ar/39Ar age is in good agreement with the Re–Os age. These ages show that the timing of tungsten mineralization occurred at about 150 Ma. Our new data, when combined with published geochronological results from the other major deposits in this region, suggest that widespread W mineralization occurred in the Late Jurassic throughout South China. 相似文献
12.
HUANG Fan FENG Chengyou CHEN Yuchuan YING Lijuan CHEN Zhenghui ZENG Zailin QU Wenjun 《《地质学报》英文版》2011,85(6):1434-1447
The Huangsha-Tieshanlong quartz-vein tungsten polymetallic ore deposit, located in the northern Pangushan-Tieshanlong tungsten ore field in eastern Ganxian-Yudu prospecting areas of the Yushan metallogenic belt, is a well-known tungsten deposit in southern Jiangxi province, China. SHRIMP-determined dating of zircons from the Tieshanlong granite yields ages of 168.1±2.1 Ma (n=11, MSWD=1.3). Rhenium and osmium isotopic dating of molybdenite from the Huangsha quartz-vein tungsten deposit determined by ICP-MS yields a weighted average ages of 153±3 Ma and model ages of 150.2±2.1 Ma – 155.4±2.3 Ma. The age of the Huangsha tungsten deposit is 10 to 15 Ma later than the Tieshanlong granite, which shows that there might have been another early Late Jurassic magmatic activity between 150 and 160 Ma, a process which is closely related with tungsten mineralization in this area. The Tieshanlong granite, the Huangsha tungsten deposit and the Pangushan-Tieshanlong ore field were all formed around 150–170 Ma, belonging to products of a Mesozoic second large-scale mineralization. According to the collected molybdenite Re-Os dating results in southern Jiangxi province, the timescale of the associated molybdenum mineralization is 2–6 Ma in the tungsten deposit and the timescale of independent molybdenum mineralization is 1–4 Ma, implying the complexity of tungsten mineralization. Times of molybdenum mineralization are mainly concentrated in the Yanshanian, which includes three stages of 133~135 Ma, 150–162 Ma, and 166–170 Ma, respectively. The 150–162 Ma-stage is in accordance with ages of large-scale W-Sn mineralization, which is mainly molybdenum mineralization characterized by associated molybdenum mineralization with development of an even greater-intensity independent molybdenum mineralization. Independent molybdenum mineralization occurred before and after large-scale W-Sn mineralization, which indicates that favorable prospecting period for molybdenum may be in Cretaceous and early late Jurassic. 相似文献
13.
《Resource Geology》2018,68(4):337-351
The Bayinsukhtu tungsten deposit is a newly discovered quartz‐vein tungsten deposit in the Xing'an–Mongolia Orogenic Belt (XMOB) in southern Mongolia, hosted by the Bayinsukhtu granite porphyry. The granite porphyry is located mainly south of the study area, over 3 km2. The rock consists of quartz and feldspar phenocrysts in a fine‐grained matrix, also mainly composed of feldspar and quartz. The granite porphyry samples demonstrate high SiO2 and high alkalinity. All samples also straddle the high‐potassium calc‐alkaline series. In a plot of the molar ratios of A/NK versus A/CNK, the granites are metaluminous. The chondrite‐normalized REE patterns are characterized by large negative Eu anomalies and fractionated LREEs. The U–Pb age of zircons from the granite porphyry is 298.8 ± 1.8 Ma, and the Sm–Nd age of the five wolframite samples from the tungsten deposit is 303 ± 19 Ma. The cooling age of the granite porphyry and tungsten mineralization is within the error of measurement and is of the Late Carboniferous age. Geological and geochronological evidence shows that the tungsten mineralization and the granite porphyry at Bayinsukhtu are genetically closely related and that they are results of Carboniferous magmatism. Their tectonic setting is related to the accretion of the Central Asian Orogenic Belt during the late Paleozoic era. 相似文献
14.
^40Ar-^39Ar Isotopic Dating of the Xianghualing Sn-polymetallic Orefield in Southern Hunan, China and Its Geological Implications 总被引:3,自引:0,他引:3 
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下载免费PDF全文 YUAN Shun PENG Jiantang SHEN Nengping HU Ruizhong DAI Tongmo State Key Laboratory of Ore Deposit Geochemistry Institute of Geochemistry Chinese Academy of Sciences Guiyang Guizhou Graduate School Chinese Academy of Sciences Beijing Guangzhou Institute of Geochemistry Chinese Academy of Sciences Guangzhou Guangdong 《《地质学报》英文版》2007,81(2):278-286
The Xianghualing Sn-polymetallic orefield in Hunan Province, southern China, is a large-size tin orefield. Although numerous studies have been undertaken on this orefield, its genesis, mineralization age, and tectonic setting are still controversial, mainly because of the lack of reliable geochronological data on tin mineralization. The 40Ar/39Ar stepwise heating dating method was first employed on muscovite from different deposits in this orefield. The muscovite sample from the Xianghualing Sn-polymetallic deposit defines a plateau age of 154.4±1.1 Ma and an isochron age of 151.9±3.0 Ma; muscovite from the Xianghuapu W-polymetallic deposit yields a plateau age of 161.3±1.1 Ma and an isochron age of 160.0±3.2 Ma; muscovite from the Jianfengling greisen-type Sn-polymetallic deposit gives a plateau age of 158.7±1.2 Ma and an isochron age of 160.3±3.2 Ma. The tungsten-tin mineralization ages in the Xianghualing area are therefore restricted within 150-160 Ma. The tungsten -tin mineralization in Xianghualing occurred at the same time as the regional tin-tungsten mineralization including the Furong tin orefield, Shizhuyuan tungsten-tin polymetallic deposit and Yaogangxian tungsten-polymetallic deposit. Thus, the large-scale tungsten-tin metallogenesis in South China occurring at 160-150 Ma. probably is closely related to asthenospheric upwelling and crust-mantle interaction under a geodynamic setting of crustal extension and lithosphere thinning during the transformation of tectonic regimes during the Mid-Late Jurassic. 相似文献
15.
江西岿美山钨矿矿床的成矿年龄及地质特征 总被引:1,自引:0,他引:1
江西省定南县岿美山钨矿区位于南岭东西向构造带东段与武夷山北东-北北东向构造带南段的复合部位,是赣南地区以石英脉型黑钨矿和矽卡岩型白钨矿共生为特征的钨矿床,其是否为南岭地区燕山期的成矿作用,一直没有精确的年代学研究成果。本文采用锆石SHRIMP U-Pb定年和辉钼矿Re-Os同位素定年技术,对岩体年龄和成矿年龄进行了精细的测定,获得成矿黑云母花岗岩体的锆石SHRIMP U-Pb年龄为(157.7±2.7) Ma(n=11,MSWD=1.9),黑钨矿石英脉的辉钼矿Re-Os等时线年龄为(153.7±1.5) Ma(n=5,MSWD=0.16),显示岿美山区是华南地区中生代钨矿大规模成岩成矿作用的产物之一。根据“五层楼+地下室”的找矿模型,并结合矿区的最新找矿线索,研究认为在矿区深部岩体的内外接触带具有存在新矿体的可能性,该区深部具有较大的找矿潜力,同时探索性地提出赣南地区石英脉型钨矿深边部存在矽卡岩型钨矿化的可能,对区域钨矿的深边部找矿工作具有指导意义。 相似文献
16.
福建行洛坑大型钨矿的地质特征、成矿时代及其找矿意义 总被引:24,自引:2,他引:22
行洛坑钨矿是目前福建最大也是武夷山成矿带最大的钨矿,已知储量主要分布于岩体内部,宜归属于斑岩型钨矿范畴。本文通过Re-Os法和Rb-Sr等时线法测定花岗岩体中辉钼矿的Re-Os等时线年龄为156.3±4.8Ma,石英脉中流体包裹体的Rb-Sr等时线年龄为147.5±2.9Ma,表明成矿作用与岩浆岩的形成基本同步,并延续了大约10Ma。因此,行洛坑钨矿虽然属于斑岩型钨钼矿但岩体以外的空间也可能找到石英脉钨矿,而整个武夷山成矿带中生代持续而复杂的成矿历史预示了其良好的找矿前景。 相似文献
17.
内蒙古红花尔基钨钼矿云英岩化白云母Ar-Ar定年及其地质意义 总被引:2,自引:2,他引:0
红花尔基钨多金属矿是近年在大兴安岭中北部地区发现的一处大型钨多金属矿床,主要矿化蚀变为云英岩化、绢英岩化,主要有用金属矿物为白钨矿和辉钼矿,岩体内辉钼矿与白钨矿有上钼下钨的带状分布特点,地质特征显示该矿床为一高温热液型钨(钼)矿床。为准确限定成矿热液活动时间,本文对矿区典型蚀变矿物——云英岩化蚀变带白云母进行Ar-Ar同位素定年,获得Ar-Ar坪年龄为174.4±1.2 Ma,等时线年龄为173.2±4.3 Ma。根据矿区云英岩化带与钨钼矿化带空间上重合和密切共生的关系,可知白云母的形成是与白钨矿、辉钼矿形成同源、同时,且辉钼矿Re-Os年龄(176.8±2.2 Ma)与Ar-Ar年龄在误差范围内具有一致性,该年龄代表了钨钼矿热液成矿时代。结合野外地质特征及锆石U-Pb、辉钼矿Re-Os年龄,进一步限定该矿床成矿时代为早中侏罗世,属燕山期构造岩浆活动的产物。 相似文献
18.
湖南崇阳坪地区石英脉型钨矿床的地质特征、成矿规律及成矿模式 总被引:4,自引:1,他引:3
崇阳坪地区位于南岭西段,区内出露有中华山、崇阳坪、瓦屋塘3个岩体,且在岩体内已发现了初具规模的寨溪山、上茶山、牛角界、沙溪等钨矿床,主要矿化形式为浸染状、细脉状白钨矿、黑钨矿化,常见围岩蚀变有云英岩化、钾长石化、钠长石化、电气石化、绿泥石化等,属于石英脉型钨矿床(主要为白钨矿)。区内崇阳坪岩体LAICP-MS锆石U_Pb年龄为(214.2±1.7)Ma,瓦屋塘岩体年龄为(223.1±2.1)Ma,形成于印支期,研究区内的钨矿(化)体均产于印支期花岗岩体接触带上,空间上与二长花岗岩侵入体关系密切,成矿与成岩基本同时,这填补了华南地区印支期花岗岩不能形成独立钨矿的空白。文章在总结归纳前人研究成果的基础上,结合近年来在该区找矿取得的进展,主要从以上矿床的地质特征入手,总结分析该区钨矿床的成矿规律,并在此基础上初步建立该区石英脉型钨矿床成矿模型。 相似文献
19.
The large Huamei'ao tungsten deposit, with total WO3 reserves of 67,400 tons at an average grade of 1.334% WO3, is located in the convergent zone of the eastern Nanling E–W-trending tectono-magmatic belt and the western Wuyishan NNE–SSW-trending tectono-magmatic belt in southern Jiangxi Province, China. The tungsten mineralization in this deposit is mainly found in quartz–wolframite veins, with most orebodies distributed at the outer contact zone between concealed Late Jurassic granitic stocks and Sinian weakly metamorphosed sandstones and phyllites. Zircons collected from medium- to fine-grained biotite granite in a diamond drill hole at a sea level of ca. − 10 m yield a crystallization age of 159.9 (± 1.2) Ma through laser ablation–multicollector–inductively coupled plasma–mass spectrometry (LA–MC–ICP–MS) U–Pb dating. Molybdenite and muscovite that were both separated from quartz–wolframite veins yield a Re–Os isochron age of 158.5 (± 3.3) Ma and an 40Ar–39Ar weighted plateau age of 157.9 (± 1.1) Ma, respectively. These dates, obtained via three independent geochronological techniques, constrain the ore-forming age of the Huamei'ao deposit and link the genesis of the ore and the underlying granite. Analyses of available high-precision zircon U–Pb, molybdenite Re–Os and muscovite 40Ar–39Ar radiometric ages of major W–Sn deposits in southern Jiangxi Province indicate that there is no significant time interval between W–Sn mineralization and its intimately associated parent granite emplacement (interval of 0–6 Ma). These deposits formed over three intervals during the Mesozoic (240–210, 170–150, and 130–90 Ma), with large-scale W–Sn mineralization occurring mainly between 160 and 150 Ma. The majority of W–Sn deposits in this region are located in southern Jiangxi and southern Hunan provinces. 相似文献