安徽铜陵新桥铜-金矿床的He、Ar同位素组成及其意义

对安徽铜陵新桥铜 金矿床层状矿体和块状矿体的黄铁矿进行了流体包裹体的He、Ar同位素研究。结果表明,成矿流体的N(40Ar)/N(36Ar)≈238～293,N(3He)/N(4He)≈1 03～1 23Ra,与大气饱和水(包括大气降水和海水)的特征值N(3He)/N(4He)=1Ra,N(40Ar)/N(36Ar)=295 5非常接近,表明成矿流体含大气降水和海水,这与野外地质特征也相符合,反映了成矿流体来自海底喷流(热水)沉积作用过程,这一认识为该区铜 金矿床可能的海底热液喷流成因提供了新的证据。     

新疆阿合奇县布隆石英重晶石脉型金矿地质特征和硫、氦、氩同位素研究

位于新疆西南天山阿合奇县的布隆金矿赋存于上泥盆统细碎屑岩中,金矿体受层间缓倾斜破碎带控制,矿区内发育重晶石脉、石英大脉、石英重晶石脉,但金矿体只产于石英重晶石脉中,为一种比较少见的石英重晶石脉型金矿床。矿石中黄铁矿的 δ~(34)S 值变化于14.6‰～19.2‰,重晶石的 δ~(34)S 值介于35.0‰～39.6‰,反映硫来自于地层。黄铁矿流体包裹体的~3He/~4He 比值为0.24～0.82 R/Ra,趋近于地壳特征值。~(40)Ar/~(36)Ar=338～471,略高于大气氩的同位素组成。~(40)Ar/~4He 比值0.015～0.412,平均为0.153,与地壳~(40)Ar/~4He 比值(0.156)一致。成矿流体的He、Ar 同位素组成特征反映了成矿流体主要来源于地壳。     

新疆准噶尔北缘索尔库都克铜钼矿氦-氩同位素组成及地质意义

索尔库都克铜钼矿床位于准噶尔北缘,矿体呈似层状、透镜状、脉状产于中泥盆世北塔山组安山岩和矽卡岩中。采用稀有气体同位素质谱法,对矿床中绿帘石矽卡岩、安山岩和矿石3种产状的黄铁矿中流体包裹体氦和氩同位素组成进行测试分析。测试结果显示,黄铁矿中流体包裹体的4He含量为(0.882 1~13.341 0)×10-8cm3STP/g,3He/4He为0.88~1.76 Ra(Ra为大气中的3He/4He,Ra=1.4×10-6),幔源He占13.27%~26.93%,表明成矿流体中氦主要来源于地壳。40Ar含量为(4.237 6~13.970)×10-8cm3STP/g,40Ar/36Ar为301.07~331.55,40Ar*含量占1.71%~10.87%,表明成矿流体中Ar主要来源于大气降水。3种产状的黄铁矿中氦、氩同位素组成及特点相似,结合矿床流体包裹体和稳定同位素研究,认为成矿流体来源于壳-幔相互作用的岩浆流体和大气降水,矿床的形成与安山岩和矽卡岩关系密切,暗示矿床成因为矽卡岩型。     

陕西柞山地区穆家庄铜矿床成矿流体来源的氦氩氢氧同位素示踪

最近,在秦岭柞山地区泥盆系中又发现了穆家庄铜矿,矿体明显受层间破碎带控制,矿石主要产在铁白云石-石英脉中,其后生成矿现象非常明显.文章利用的黄铁矿流体包裹体He-Ar同位素和氢氧同位素,来探讨这类矿床的成矿流体的来源.穆家庄铜矿床矿石矿物黄铁矿流体包裹体的3He/4He比值为0.322～0.889R/Ra,小于1.0R/Ra.3He/4He比值远远低于地幔流体的比值,与地壳流体的比值在相同的数量级上.穆家庄铜矿成矿流体的40Ar/36Ar比值为377～569,平均470,显然偏离大气氩的同位素组成.穆家庄铜矿成矿流体的40Ar/4He比值为0.09～0.23,平均值为0.164.很显然,该矿床的成矿流体的40Ar/4He比值接近地壳.根据以上分析,柞山地区的穆家庄铜矿床的成矿流体是壳源的.氢氧同位素分析表明穆家庄铜矿的氢氧同位素则落入原生岩浆水范围内,表明穆家庄铜矿的成矿流体为岩浆水.综合对比分析后认为,穆家庄铜矿的成矿流体是由壳源岩浆驱动并参与的岩浆流体提供的.     

新疆阿尔泰阿舍勒VHMS型铜锌矿床成矿流体 的氦—氩同位素示踪

阿舍勒大型铜锌矿是我国典型的海相火山岩块状硫化物(VHMS)型矿床,赋存于阿舍勒盆地早—中泥盆世阿舍勒组海相火山—沉积岩系中。1号主矿体呈似层状或大透镜体状,矿石呈块状、浸染状、条带状、层纹状、细脉状。本文对块状、浸染状、条带状矿石的黄铁矿中流体包裹体He和Ar同位素进行了研究。黄铁矿中流体包裹体的4He含量为(64.5~173.0)×10-7cm3STP/g,n(3He)/n(4He)值为(0.1358~0.379)Ra,幔源He的含量为1.79%~5.55%,表明成矿流体中He主要来源于地壳。40Ar含量为(0.318~4.69)×10-7cm3STP/g,n(40Ar)/n(36Ar)值变化于389.1~9425,40Ar*含量为24.06%~96.89%,表明成矿流体中存在含有放射性成因Ar的海水加入。结合矿床的氢、氧、硫同位素特征,认为成矿流体来源为海水和幔源岩浆热液。     

云南兰坪盆地西缘脉状铜矿床富CO_2流体来源的He和Ar同位素证据

兰坪盆地西缘广泛发育大量沉积岩容矿脉状铜矿床,这些脉状铜矿床的成矿流体以普遍存在大量富CO2流体包裹体为特征,这在整个兰坪盆地是十分罕见的,显著区别于盆地流体成矿系统主导成矿的Pb-Zn矿床。为探明这种富CO2流体的来源,本文首次报道了盆地西缘2个代表性脉状铜矿床(连城、金满)主成矿阶段形成的黄铜矿、黄铁矿的He和Ar同位素组成的研究结果。结果表明,2个矿床不同样品流体包裹体中3He/4He比值变化较小,介于0.01~0.07 Ra之间,明显区别于幔源氦的3He/4He特征值(6~9 Ra),而与壳源氦的3He/4He特征值(0.01~0.05 Ra)极其一致;40Ar/36Ar比值变化较大,介于305~1142之间,明显高于大气中的40Ar/36Ar比值(295.5)。结合矿床地质、流体包裹体及H、O同位素地球化学特征,认为兰坪盆地西缘脉状铜矿床中富CO2的成矿流体以混有少量饱和大气水的地壳流体为主,没有明显的幔源流体参与。     

赣南淘锡坑钨矿床He-Ar同位素地球化学研究

华南石英脉型黑钨矿的形成一直被认为是与地壳沉积物质重熔形成的S型花岗岩有关。然而,近年来对南岭中生代成岩成矿机制的研究发现,地幔组分可能参与了钨、锡成矿作用。本文对淘锡坑石英脉型钨多金属矿床与黑钨矿共生的黄铁矿和毒砂中流体包裹体的He、Ar同位素进行了研究。结果显示,上述矿物中流体包裹体的~3He/~4He值为0. 37～2. 11Ra(Ra为空气的~3He/~4He值,1Ra=1. 39×10~(-6)),介于地幔与地壳的~3He/~4He值之间;~(40)Ar/~(36)Ar值为309. 5～383. 6,平均335. 4,略高于大气的~(40)Ar/~(36)Ar比值(295. 5)。研究表明,成矿流体具有壳-幔两端元混合的特征。其中,地壳端元的流体为经过地下循环的低温饱和大气水,地幔端元的流体为矿区隐伏花岗岩体成岩过程中分异出的岩浆流体。结合前人研究成果,认为该矿床的形成与华南中生代燕山期发生的软流圈上涌、岩石圈减薄、地壳伸展等地球动力学作用有密切联系。这种动力学过程为地幔组分带来的热引起地壳沉积物质重熔形成钨多金属成矿花岗岩浆提供了条件。     

粤北诸广南部铀矿田流体包裹体的氦氩同位素组成及成矿流体来源示踪

粤北诸广南部铀矿田是我国重要的花岗岩型铀矿产地之一,有关诸广南部花岗岩型铀矿田的成因,多年来一直存在较大的争议。本文以诸广南部铀矿田典型铀矿床成矿期萤石、方解石和黄铁矿中流体包裹体为测试对象,研究了成矿流体的He、Ar同位素地球化学。研究表明,萤石流体包裹体的~3He/~4He比值为0. 021～0. 186Ra,~(40) Ar/~(36)比值为298. 4～2515. 7;方解石流体包裹体的3He/4He比值为0. 027～0. 209Ra,~(40) Ar/~(36)比值为295. 9～327. 2;黄铁矿流体包裹体的3He/4He比值为0. 021～1. 543Ra,~(40) Ar/~(36)比值为326. 9～1735. 1; He-Ar同位素系统显示成矿流体的3He/4He比值略高于地壳氦同位素特征值(0. 01～0. 05Ra),但低于幔源氦同位素特征值(6～9Ra),~(40) Ar/~(36)比值接近或高于大气氩的同位素组成(~(40) Ar/~(36)=295. 5),成矿流体为壳-幔混合来源。结合H-O、He-Ar、C和Sr等多元同位素证据表明,成矿流体由两个端元组成:一是含有一定放射性成因Ar的大气降水的地壳流体,二是含幔源He的地幔流体。进一步研究表明,受NNW向断裂控制的棉花坑、书楼丘、长排等铀矿床受地幔流体影响比较大,而受NE向断裂控制的蕉坪、东坑、烟筒岭铀矿床受大气降水影响比较大。     

The C-O and Zn isotopic compositions of the Laochang Ag-Pb-Zn ore bodies in the Changning-Menglian suture zone,and its geological implicationsSCIEI北大核心CSCD

老厂矿床是昌宁-孟连缝合带内唯一大型矿床,本文报道了老厂矿床Ag-Pb-Zn矿体中Ⅰ号矿体群下部块状矿体和上部网脉状矿体的方解石C-O同位素组成,以及Ⅰ、Ⅱ、Ⅳ三个矿体群内闪锌矿的Zn同位素组成。Ⅰ号矿体群下部块状矿体和上部网脉状矿体方解石δ¹³C_PDB的范围分别为-6.17‰～2.71‰和-2.18‰～3.87‰,δ¹⁸O_PDB的范围分别为-19.57‰～-17.23‰和-22.10‰～-16.21‰;计算获得对应成矿流体的δ¹³C_CO2为-6.16‰～1.53‰和-2.39‰～6.43‰,δ¹⁸O_H2O分别为1.62‰～7.62‰和4.36‰～16.92‰,通过与岩浆CO₂(δ¹³C=-2‰～-8‰)和围岩灰岩(δ¹³C=-1.6‰～4.0‰)的δ¹³C值相比较,指示块状矿体成矿流体中的碳主要来自岩浆,网脉状矿体成矿流体中...     

德兴金山金矿床成矿流体来源:小尺度构造和同位素地球化学证据

德兴金山金矿床位于扬子板块和华南克拉通之间的江南造山带东段赣东北深大断裂带的次级剪切带中,是一个与韧-脆性剪切带有关的超大型金矿床.金山金矿床的矿石类型包括蚀变岩型和含金石英脉型,均为与断裂(或者裂隙)充填有关的不同尺度石英脉系统.纹层状和透镜状含金石英脉结构表明金山金矿床的成矿作用是同构造的,金的矿化与递进变形作用密切相关,变形过程中产生的变质流体参与了成矿作用.石英-钠长石-铁白云石-黄铁矿蚀变带中与金共生的黄铁矿流体包裹体的3He/4He比值为0.13～0.24 Ra,40Ar/36Ar比值变化范围为575～1 090,说明成矿流体主要以地壳端员的流体为主,有很少量的地幔流体参与.铁白云石的碳、氧同位素值分别变化于-5.0‰～-4.2‰和4.4‰～8.0‰之间,与世界上大多数脉状金矿床的碳、氧同位素值基本一致.含金石英脉中石英的氧同位素变化于12.4‰～15.3‰之间,其中的流体包裹体氢同位素值变化于-62‰～-73‰.根据这些同位素地球化学数据,结合金山金矿床小尺度地质构造特征,笔者认为金山金矿的成矿流体主要为变质流体,并有少量地幔流体和大气降水的参与.金山金矿形成于地体碰撞过程中的转换压缩汇聚构造背景中.     

黑矿型矿床成矿物质来源：日本上向黑矿铼—锇和氦同位素证据

上向黑矿（Uwamuki Kuroko)是日本最典型的黑矿型矿床，它形成于日本岛弧中新世矢折岛弧裂谷环境，产于双峰式岩石组合的长英质火山岩系中。矿床由下部筒状硅矿带和上部块状黑矿带构成，后者显示典型的上黑（黑矿）下黄（黄矿）金属分带。为探索研究长期争议的成矿物质来源，系统测定了矿石和主岩的Os,He同位素组成。含矿流纹岩系的R／RA值介于0．93－1．14间，证实该岩浆可能主要来源于陆壳重熔。上向黑矿的上部块状黑矿矿石具较高的^187Os/^188Os值（2．246－7．608），反映矿石Os主体来源于壳源沉积物或矿区基底岩系；下部脉状－网脉状硅矿、块状黄矿和少量黑矿则具低^187Os/^188Os值（0．423－0．793），证实矿石Os具两源性，估计幔源物质贡献约57％－89％，壳源物质贡献约11％－43％。此外，在上部块状黑矿带内部，矿石 ^187Os/^188O显示清楚的垂向韵律性变化，揭示了成矿流体及成矿物质的周期性混合，据此，本文提出了一个新的两阶段成矿模式。     

安徽新桥矿床矿相学与Fe同位素特征及其对矿床成因的制约

对安徽新桥矿床进行系统的野外地质调查和矿相学研究发现,层状矿体中的胶状黄铁矿交代矽卡岩磁铁矿矿体,为探讨层状硫化物矿床是早期沉积成因还是岩浆热液成因提供了新的地质约束。对铜陵矿集区内的新桥矿床层状菱铁矿矿体和凤凰山矽卡岩型矿体中的菱铁矿开展了Fe同位素组成的对比研究,结果显示：新桥矿床菱铁矿与典型低温热液脉型矿床和沉积铁矿中的菱铁矿在Fe同位素组成特征上有所不同,而与凤凰山矽卡岩型矿床中的菱铁矿更为接近;新桥矿床中胶状黄铁矿和菱铁矿相对于磁铁矿富集Fe的轻同位素,表明磁铁矿不是过去认为的由胶状黄铁矿和菱铁矿矿胚层经热液改造形成,而是与典型的岩浆热液有关。新桥矿区层状硫化物矿体和矽卡岩型矿体中,近岩体矽卡岩和最早形成的金属矿物磁铁矿比岩体更为富集Fe的轻同位素,而赋矿围岩比岩体更为富集Fe的重同位素。同时,不同矿化阶段形成的含铁矿物和不同空间位置的硫化物中的Fe同位素组成呈现出时空分带现象,Fe同位素组成的时空演化特征与流体出溶、流体演化非常一致,并且符合同位素分馏的基本理论,表明层状硫化物矿体和矽卡岩型矿体具有相同的成矿物质来源,为同一流体体系演化的产物。新桥矿区岩相学的研究结果和Fe同位素组成特征均表明,新桥层状硫化物矿床不是海西期喷流沉积成矿作用的产物,而是燕山期热液成矿作用的产物,为一个典型的热液成因矿床。     

He–Ar Isotope Composition of Pyrite and Wolframite in the Tieshanlong Tungsten Deposit,Jiangxi, China: Implications for Fluid Evolution

The Tieshanlong tungsten‐polymetallic deposit is a large wolframite deposit of quartz vein type located in southern Jiangxi, South China. It is genetically related to a high‐K S‐type granite. Seven pyrite and two wolframite samples, selected for He and Ar isotope analyses, yielded ³He/⁴He values of 0.04–0.98 Ra, ⁴⁰Ar/³⁶Ar ratios of 293.5–368.0, and ³⁸Ar/³⁶Ar ratios of 0.176–0.193. These data indicate that the ore‐forming fluids associated with the deposit did not result from a simple mixing of the crustal‐ and mantle‐derived end‐member fluids, but that primeval meteoric fluids were also involved in the generation of the associated granitic magma by partial melting of crustal metasedimentary rocks. Further investigations show that only minimal He from the mantle was added during generation of the associated granitic magma. It is postulated that boiling and second mixing with “new” meteoric fluids took place during migration of magmatic‐hydrothermal fluids into wall‐rock fractures, resulting in a drastic decrease of their metal transport capacity, which triggered the tungsten‐polymetallic mineralization.     

内蒙古白乃庙铜-金-钼矿床成矿机制——来自流体包裹体和He-Ar同位素的证据

白乃庙铜-金-钼矿是华北板块北缘中段一个重要矿床,其矿化特征既显示斑岩型蚀变特征,同时又表现出明显的后期造山作用改造的特点。本次研究通过系统的流体包裹体显微测温、激光拉曼和气液相色谱分析揭示其成矿流体为中—低温、中低盐度的CO_2(CO)-H_2O-CH_4(C_2H_2+C_2H_4)-NaCl-CaCl_2体系,流体混合作用和CO_2逃逸为成矿主要因素。富还原性流体的存在可能促使气相流体携带大量的Cu、Au等成矿元素迁移至较远点的白乃庙群地层,沿着片理或裂隙沉淀成矿。对不同成矿阶段矿石中黄铁矿的He-Ar同位素组成测试结果显示白乃庙矿床黄铁矿流体包裹体的~3He/~4He比值在0.06~0.71Ra之间,~(40)Ar/~(36)Ar比值为375.5~1436.3,指示成矿体系由不同性质和组成的两个端元流体混合而成,即混入了类似于MORB型地幔端元的高温高盐度流体和富含地壳放射成因氦但具有空气氩同位素组成特征的低温大气降水。白乃庙矿床属受后期造山作用改造的斑岩型铜-金-钼矿床,形成于古亚洲洋板块持续向南俯冲背景。     

首钢秘鲁铁矿马尔科纳矿区9-10号矿体地质特征及成矿模式

秘鲁马尔科纳铁矿位于南美安第斯山金属成矿带中。9-10号矿体赋存在志留-泥盆系马尔科纳组角岩中,MINA9、MINA10两个矿体实为同一矿体,只是被后期安山玢岩脉切割分成为两段。矿体呈层状、似层状产出,走向上连续,由一个主矿体组成,地表出露主矿体长1 450m,平均宽度100m。西部矿体走向近EW,倾向NW,倾角较缓;东部矿体走向NEE,倾角中等,围岩为角岩。矿体沿走向厚度稳定,9号矿体沿倾向矿体变薄,10号矿体沿倾向矿体增厚;由于后期氧化作用,铁矿体具有明显的垂直分带特点,由上到下分为氧化带、过渡带和原生带。综合矿物学和Ar同位素地质年代学研究结果,铁矿床主要形成于侏罗纪—早白垩世,成矿分为7个成矿阶段,中-晚侏罗世(171~156 Ma)的磁铁矿阶段、磁铁矿-硫化物阶段和多金属硫化物阶段是马尔科纳铁矿的主要成矿期;早白垩世(110~101 Ma)出现脉状铁-铜-硫化物叠加矿化阶段。马尔科纳铁矿的成矿模式:板块的碰撞-俯冲,造成强烈的幔源岩浆活动,形成大规模火山喷发和高钾钙碱性岩的侵位,火山(岩浆)期后的含矿流体沿NEE向断裂侵位,磁铁矿聚集矿化,形成马尔科纳铁矿的主矿体;主成矿期后又弱的叠加矿化,与中基性岩脉和断裂一起改造、破坏了先期阶段的矿体。     

东天山黄土坡铜锌矿床成矿流体的氦-氩同位素示踪

黄土坡铜锌矿床是东天山卡拉塔格地区一中型海相火山岩型块状硫化物（VHMS）矿床,赋存于早志留世海相火山-沉积岩系中。矿体产于酸性火山角砾岩与凝灰岩之间,主矿体呈厚大的扁豆状,矿石主要呈块状、浸染状、条带状和网脉状构造。本文报道了黄土坡铜锌矿床成矿流体的氦和氩同位素组成,黄铁矿流体包裹体的³He 含量低,介于0.039×10^-12 cm³ STP/g～0.64×10^-12 cm³ STP/g,n（³He）/n（⁴He）值为 0.11～0.94 Ra,介于壳源He与幔源He之间。⁴⁰Ar 含量变化于 3.49×10^-8cm³ STP/g～34.25×10^-8 cm³ STP/g 之间,n（⁴⁰Ar）/n（³⁶Ar）介于301.40～425.98 之间。成矿流体中有幔源 He（1.71%～10.97%）和放射性成因 Ar（⁴⁰Ar*含量为1.96%～30.63%）。结合矿床包裹体及 H-O-S 同位素特征,认为幔源流体和富放射性成因He 和Ar 的海水参与了成矿。     

Noble Gas and Stable Isotopic Constraints on the Origin of the Ag–Cu Polymetallic Ore Deposits in the Baiyangping Area,Yunnan Province,SW China

The Lanping basin, Yunnan province, SW China, is located at the juncture of the Eurasian and Indian Plates in the eastern part of the Tibetan Plateau. The Lanping basin, in the Sanjiang Tethyan metallogenic province, is a significant Cu–Ag–Zn–Pb mineralized belt in China that includes the largest sandstone‐hosted Zn–Pb deposit in the world, the Jinding deposit, as well as several Ag–Cu deposits (the Baiyangping and Jinman deposits). These deposits, with total reserves of over 16.0 Mt Pb + Zn, 0.6 Mt Cu, and 7,000 t Ag, are mainly hosted in Meso‐Cenozoic clastic rocks and are dominantly controlled by two Cenozoic thrust systems developed in the western and eastern segments of the basin. The Baiyangping, Babaoshan, and Hetaoqing ore deposits are representative of the epithermal base metal deposits in the Lanping basin. The microthermometric data show that the ore‐forming fluids for these deposits were low temperature (110–180 °C) and had bimodal distribution of salinity at moderate and mid to high salinities (approximately 2–8 wt.% and 18–26 wt.% NaCl equivalent). The C and O isotope data indicate that the ore‐forming fluids were related to hot basin brines. We present new He and Ar isotope data on volatiles released from fluid inclusions contained in sulfides and in barite in these three deposits. ³He/⁴He ratios of the ore‐forming fluids are 0.01 to 0.14 R/Ra with a mean of 0.07 Ra (where R is the ³He/⁴He ratio and Ra is the ratio for atmospheric helium). This mean value is intermediate to typical ³He/⁴He ratios for the crust (R/Ra = 0.01 to 0.05) and the ratio for air‐saturated water (R/Ra = 1). The mean ratio is also significantly lower than the ratios found for mantle‐derived fluids (R/Ra = 6 to 9). The ⁴⁰Ar/³⁶Ar ratios of the ore‐forming fluids range from 298 to 382 with a mean of 323. This value is slightly higher than that for the air‐saturated water (295.5). The ³He/⁴He ratios of fluids from the fluid inclusions imply that the ore‐forming fluid for the Baiyangping, Babaoshan, and Hetaoqing deposits was derived from the crust and that any mantle‐derived He was negligible. The content of the radiogenic Ar ranges between 0.2 to 20.4%, and the proportion of air‐derived ⁴⁰Ar averages 94.1%. This indicates that atmospheric Ar was important in the formation of these deposits but that some radiogenic ⁴⁰Ar was derived from crustal rocks. Based on these observations coupled with other geochemical evidence, we suggest that the ore‐forming fluids responsible for the formation of the Ag–Cu–Pb–Zn polymetallic ore deposits in the Baiyangping area of the Lanping basin were mainly derived from crustal fluids. The fluids may have mixed with some amount of air‐saturated water, but there was no significant involvement of mantle‐derived fluids.     

中国SEDEX型矿床成矿流体硼、硅、氦-氩同位素组成研究评述

SEDEX型矿床成矿流体的研究是矿床地球化学研究的重要课题之一。正确识别系统中不同的流体来源及其混合过程,是深刻理解SEDEX型矿床形成演化的关键。系统总结了国内几个典型的SEDEX型矿床同位素研究成果,认为B和Si同位素是根据SEDEX型矿床独特的矿物组合而提出的一种示踪方法,对矿床成因和沉积环境示踪效果理想;He、Ar同位素则因为在地壳和地幔储库中有极不相同的组成,是理想的幔源流体示踪剂。鉴于SEDEX型矿床含有电气石、黄铁矿、硅质岩等特殊的矿物与岩石组合,B、Si、He-Ar同位素可能更适合SEDEX型矿床矿化流体来源研究,并指出其理论发展的薄弱之处。     

江西相山铀矿田深部多金属矿化成矿流体来源:流体包裹体He-Ar同位素证据

江西相山铀矿田西部地区实施的铀矿科学深钻3号孔在深部–700 m发现大量铅锌银多金属矿化脉,垂向上呈"上铀下多金属"的分布特征。本文对深部多金属矿化主成矿阶段的黄铁矿、闪锌矿、方铅矿进行了流体包裹体He和Ar同位素组成测定,结果表明,相山深部多金属矿化主成矿阶段的黄铁矿、闪锌矿和方铅矿具有较一致的He、Ar同位素组成,矿物内流体包裹体的~3He含量范围为4.55×10^–14～1560×10^–14 cm^3·STP/g,~4He含量范围为1.05×10^–7～525×10^–7 cm^3·STP/g,~3 He/~4He为2.98×10^–7～4.96×10^–7,即0.21～0.35 Ra,介于地壳(0.01～0.05 Ra)和饱和大气水(1 Ra)之间,明显低于地幔的~3 He/~4He值(6～9 Ra),⁴⁰Ar浓度为0.969×10^–7～157×10^–7 cm^3·STP/g,⁴⁰Ar/³⁶Ar值为303.7～573.9,略高于饱和大气水的Ar同位素组成,结合矿石和蚀变岩石中Li元素富集特征,本文认为相山西部地区深部多金属成矿流体以地壳流体和大气降水为主,成矿流体富Li元素是He同位素明显高于地壳的原因,可能存在少量幔源流体的加入。另外,通过对比前人研究的该地区铀矿化矿石中黄铁矿He-Ar同位素组成,并结合前人对该地区幔源组分明显参与铀成矿的认识,本文认为多金属矿化和铀矿化成矿流体可能并非同一来源。     

Characteristics of Ore-forming Fluid of the Gaoshan Gold-Silver Deposit in the Longquan Area,Zhejiang Province and its Implications for the Ore Genesis

The Gaoshan gold-silver deposit, located between the Yuyao-Lishui Fault and JiangshanShaoxing fault in Longquan Area, occurs in the Suichang-Longquan gold-silver polymetallic metallogenic belt. This study conducted an investigation for ore-forming fluids using microthermometry, D-O isotope and trace element. The results show that two types of fluid inclusions involved into the formation of the deposit are pure liquid phase and gas-liquid phase aqueous inclusions. The homogenization temperature and salinity of major mineralization phase ranges from 156°C to 236°C(average 200°C) and 0.35% to 8.68%(NaCleqv)(average 3.68%), respectively, indicating that the ore-forming fluid is characteristic of low temperature and low salinity. The oreforming pressure ranges between in 118.02 to 232.13'105 pa, and it is estabmiated that the oreforming depth ranges from 0.39 to 0.77 km, indicating it is a hypabyssal deposit in genesis. The low rare earth elements content in pyrites, widely developed fluorite in late ore-forming stage and lack of chlorargyrite(Ag Cl), indicates that the ore-forming fluid is rich in F rather than Cl. The ratios of Y/Ho, Zr/Hf and Nb/Ta of between different samples have little difference, indicating that the later hydrothermal activities had no effects on the former hydrothermal fluid. The chondrite-normalized REE patterns of pyrites from country rocks and ore veins are basically identical, with the characteristics of light REE enrichment and negative Eu anomalies, implying that the ore-forming fluid was oxidative and derived partly from the country rocks. The δD and δ18O of fluid inclusions in quartz formed during the main metallogenic stage range from -105‰ to -69 ‰ and -6.01‰ to -3.81‰, respectively. The D-O isotopic diagram shows that the metallogenic fluid is characterized by the mixing of formation water and meteoric water, without involvement of magmatic water. The geological and geochemical characteristics of the Gaoshan gold-silver deposit are similar to those of continental volcanic hydrothermal deposit, and could be assigned to the continental volcanic hydrothermal gold-silver deposit type.