甘肃大水金矿床铅同位素组成与成矿物质来源探讨

通过对矿床矿石铅同位素组成的分析,并与矿区岩浆岩脉和围岩地层中的岩石铅同位素组成进行对比,借以示踪矿床成矿物质来源。研究表明,矿石铅与矿区岩石铅(灰岩和脉岩)的铅同位素组成具有较相近和较窄的变化范围,暗示铅可能属同一铅源。在铅同位素构造模式图及不同成因类型矿石铅的Δγ-Δβ成因分类图解中,显示出造山带铅、地壳与地幔混合的俯冲带岩浆作用铅特征,说明铅不是单一来源的正常铅,而是混合型多来源的异常铅。成矿物质是多来源的,赋矿地层和岩浆岩共同提供了铅源及成矿物质,但以岩浆为主,地层为辅,地幔铅参与了成矿。     

云南大坪超大型金矿床铅同位素组成及成矿物质来源探讨

云南大坪超大型金矿床是哀牢山金矿带内最具代表性的金矿床之一,矿体赋存于华力西期桃家寨闪长岩体内,矿化类型以石英脉型为主。对该矿床石英脉型矿石中方铅矿进行了系统的铅同位素测定,测定结果表明,矿石铅具有较窄的²⁰⁶Pb/²⁰⁴Pb比值和相对较高的²⁰⁷Pb/²⁰⁴Pb比值及²⁰⁸Pb/²⁰⁴Pb比值,但变化范围均不大,均分布于正常铅范围。通过计算获得相关特征参数,并利用铅构造模式图及相关图解综合分析表明,大坪金矿矿石中的铅主要来源于下地壳及地幔。铅同位素特征反映了大坪金矿床成矿物质来源于壳幔混合区。     

哀牢山南段长安金矿床成矿物质来源:来自S、Pb同位素的证据

哀牢山南段长安金矿床是三江造山带哀牢山成矿带南段大型矿床之一,就位于甘河断裂的脆性破碎带内,赋矿岩石以下奥陶统砂岩和碎屑岩为主。目前已知各地质体内黄铁矿的硫同位素δ34S值变化范围为-3.49‰～+3.57‰,峰值集中在+1‰～+3‰;矿石与其他围岩及岩浆岩脉的硫同位素组成的对比表明,成矿热液中硫最可能源自于地层,或者部分混染了喜山期岩浆热液中的硫。矿石铅同位素组成为:208Pb/204Pb=38.722～40.649,207Pb/204Pb=15.604～15.813,206Pb/204Pb=18.788～19.761。结果显示其变化范围相对较小,说明矿石相对富集放射成因铅;矿石铅来源于成熟度较高的上地壳,显示矿床铅更可能源自区内的白云岩、碎屑岩、粉砂岩等沉积岩类。蚀变岩和岩浆岩类的铅主要显示出造山带铅源特点,暗示矿石铅源与矿区内岩浆岩相关性较小,应主要来自赋矿围岩。区内新生代岩浆活动为矿床的进一步叠加富集提供了热源和部分成矿物质。     

马脑壳金矿床成矿物质来源研究

马脑壳金矿床位于川西北九寨沟县，通过对该矿床地质背景、矿床特征、稀土元素和铅同位素资料的分析，认为成矿物质主要来源于上三叠统浊积岩系，少部分来自结晶基底碧口群。     

湘东北正冲金矿床成矿物质来源的S-Pb同位素示踪

长沙-平江(长-平)成矿带位于江南造山带中段,金资源储量达250余吨。该区金矿床是典型的沉积变质岩容矿的热液脉状金矿床,构造控矿特征清晰,然而巨量金来源与矿床成因尚不明确。正冲金矿床主体赋存于新元古代变质沉积岩中,矿区内同时发育少量花岗岩体,是识别不同地质体对成矿贡献的理想选择。因此,本文选取正冲金矿床,在野外宏观地质工作基础上,系统开展了成矿阶段划分与载金硫化物同位素地球化学测试等工作。正冲金矿床严格受控于NNE-NE向的长-平断裂及其次级断裂系统,矿体呈脉状,走向NW或NNE,蚀变分带不明显。正冲金矿床矿物组合简单:早阶段发育有乳白色贫矿石英与白云母;成矿主阶段为石英细脉与自然金黄铁矿毒砂-多金属硫化物-少量绿泥石;成矿晚阶段发育有石英-方解石脉。其中,黄铁矿与毒砂是矿床内自然金与不可见金重要的载体。为弱化毒砂和黄铁矿裂隙中细粒多金属硫化物对同位素地球化学结果的干扰,本次研究挑选自形、未变形的毒砂、黄铁矿颗粒测试研究。实验结果表明载金毒砂铅同位素组成~(208)Pb/~(204)Pb、~(207)Pb/~(204)Pb与~(206)Pb/~(204)Pb分别为37.867～38.285、15.555～15.663与17.743-18.073,略高于黄铁矿铅同位素组成37.774～38.268、15.547～15.660与17.670～18.021;毒砂δ~(34)S变化幅度较小(-4.7‰～-0.9‰,均值为-3.0%),略高于黄铁矿δ~(34)S值(-9.1‰～-1.1‰,均值为-4.4‰),成矿流体氧逸度约为10~(-30.7)。正冲金矿床硫、铅同位素组成与赋矿围岩、区域内岩体和斑岩型矿床同位素特征具有较大差异,说明区内岩体与赋矿地层并不是正冲金矿床成矿物质的主要来源。金矿床成矿物质具有深源特征,可能来源于比冷家溪群地层变质程度更高、沉积位置更深的变质沉积岩。结合区域地质背景、金矿床地质-地球化学特征与成矿年代学资料,推断正冲金矿床为造山型金矿床。     

小秦岭金矿床的成矿物质来源

研究表明，太华群是小秦岭地区金矿床的矿源层。通过对比混合岩化、花岗岩化、围岩蚀变和成矿作用过程中的微量元素的分布情况，发现Ａｕ和Ｐｂ，Ｃｕ，Ａｇ，Ｚｎ等在这一系列过程中始终表现出变化的一致性，说明Ａｕ等成矿物质来源于太华群变质岩，同位素证据也表明Ａｕ等成矿物质来源于太华群。     

内蒙古四五牧场金矿床成矿物质来源研究

根据内蒙古四五牧场金矿床的S、Pb、O、C同位素组成特征,对金矿床成矿物质来源进行了分析.认为金属硫化物中的硫来源于火山岩盆地基底古生代海相地层;铅主要由赋矿地层及火山岩盆地基底岩石所提供;成矿流体在成矿期主要来源于岩浆,成矿期后热液中有大气水混入.四五牧场金矿成矿期为晚侏罗-早白垩世.     

江西金山金矿床成矿物质来源的铅和硫同位素示踪

江西金山金矿床赋存于浅变质的中元古界双桥山群上亚群 ,该建造明显富Au ,Au平均丰度达 2 5 5× 10 -9。矿石铅同位素组成出现明显的线性关系表明 ,区域构造活动 成矿作用中存在着铅同位素的混合机制。大部分矿石铅Doe单阶段模式年龄与该矿床的Rb Sr年龄值十分接近 ,可能反映了区域变质的成矿意义。矿石铅 μ值介于 9 2 9～ 9 86之间 ,2 3 2 Th/ 2 3 8U比值变化于 3 88～ 4 0 9,揭示了成矿物质的壳源特征。Zartman图解和△γ △ β图解表明 ,双桥山群是矿石铅的主要源区。该矿床硫同位素组成特征与外围双桥山群上亚群中硫化物的硫同位素极为相似 ,成矿流体的硫主要来源于双桥山群含矿建造。对比研究表明 ,虽然不同金矿床的硫同位素组成特征不尽相同 ,但金山金矿床的层控特征与江南金成矿带中其他金矿极为相似。金山金矿床的铅、硫同位素地球化学特征揭示 ,该矿床的成矿物质主要来自浅变质的中元古界双桥山群含金建造 ,燕山期岩浆热液活动为该矿床的后期富集提供了部分成矿物质。     

大沟谷钠长石岩型金矿床Pb、S、Sr同位素特征初探

大沟谷金矿床产于震旦系乐晶峡群钠长石岩带底部陡倾斜钠长石岩中。金矿床铅同位素组成变化大^206Pb/^204Pb17.356-19.306,^207Pb/^204Pb15.330-15.862,^208Pb/^204Pb37.532-39.957。u值在8.23-10.6之间，黄铁矿δ^34S值在5.1‰-13.4‰之间，铅同位素组成具线性相关关系，^206Pb/^204Pb与^207Pb/^204Pb线性方程y=0.24x 11.19,r=0.83,^206Pb/^204Pb与^208Pb/^204Pb方程为y=1.3x 14.8,r=0.93，黄铁矿铅硫同位素组成具负相关关系，钠长石岩Rb、Sr含量较低，^87Sr/^86Sr值为0.72263-0.73150，平均0.72595。综合铅、锶、硫同位素特征，可以认为大沟谷金矿床成矿物质主要来自高u值基底碎屑沉积岩及钠化基性火成岩。     

柴北缘赛坝沟金矿床硫、铅同位素组成:对成矿物质来源的指示

柴北缘赛坝沟金矿床是青海省赛什腾山-阿尔茨托山成矿带上重要的岩金矿床,成矿地质条件优越.矿体赋存于北西-北北西向韧-脆性断裂构造组内,呈脉状、透镜状,构造控矿作用明显,矿石类型分为石英脉型和蚀变糜棱岩型.热液成矿期可划分为4个阶段:Ⅰ少量黄铁矿-烟灰色石英阶段、Ⅱ金-黄铁矿-乳白色石英阶段、Ⅲ多金属硫化物-金-灰白色-...     

The Isotopic Composition of Noble Gases in Gold Deposits and the Source of Ore- Forming Materials in the Region of North Hebei, China

1IntroductionOnthenorthernmarginoftheNorthChinaplatformislocatedoneofthemostimportantAu Ag polymetallicore concentratedzones,wherethereareavarietyoforetypes .Soithasbeenat tractingeverincreasingattentionofmanygeologists (PeiRongfuetal.,1 998;ShenBaofengetal.,1 994 ;LuSongnianetal.,1 997;HuShouxietal.,1 994 ;ChenYuchuan ,1 999;ZhaiYushengetal.,1 999) .Manyscholarspresentedtheirresearchresultsinvariousaspects.How ever ,thesourceofore formingmaterialshaslongbeenafocusofdiscussion .Studieso…     

Isotopic Characteristics of Mesozoic Au-Ag Polymetallic Ore Deposits in Northern Hebei and Their Ore-Forming Materials Source

It has long been a controversy about the source of ore-forming materials of Au-Ag polymetallic deposits both in metallogenic theory and in ore-searching practice. In terms of a large wealth of the isotopic statistics data from Indosinian-Yanshanian endogenic ore deposits in northern Hebei (generally referring to the areas along the northern part of Taihang Mountains and northern Hebei, the same below) , it is considered that the ore-forming materials came from the deep interior of the Earth, which had migrated through plumes to the Earth surface while ex-perienced multi-stage evolution and then emplaced progressively in favorable structural loci to form ores. Their isotope data show that 559 sulfur isotopic data from 40 ore deposits are, for the most part, within the range of -5‰ -5‰, with a high degree of homogenization, indicating that the sulfur is derived mainly from magma; 200 lead isotope data from 37 ore deposits indi-cate that the ore-forming materials are principally of mantle source though some crust-source ma-terial was involved; 96 oxygen, hydrogen and carbon isotope data from 34 ore deposits illustrate that the ore-forming fluids are dominated by magmatic water while other sources of water would be involved. It may therefore be seen that the formation of endogenic deposits has nothing to do with the strata .     

Helium and argon isotopic compositions of the Longquanzhan gold deposit in the Yishu fault zone and their geological implications

The Longquanzhan gold deposit hosted in granitic cataclasites with mylontization of the foot wall of the main Yishui-Tangtou fault. 3He/4He ratios in fluid inclusions range from 0. 14 to 0. 24 R/Ra,close to those of the crust-source helium. 40Ar/36Ar ratios were measured to be 289-1811, slightly higher than those of atmospheric argon. The results of analysis of helium and argon isotopes suggested that ore-forming fluids were derived chiefly from the crust. The δ18O values of fluid inclusions from vein quartz range from -1.78‰ to 4.07‰, and the δD values of the fluid inclusions vary between -74‰ and -77‰. The hydrogen and oxygen isotope data indicated that the ore-forming fluid for the Longquanzhan gold deposit had mixed with meteoric water in the process of mineralization. This is consistent with the conclusion from the helium and argon isotope data.     

中国某些金属矿床矿石铅来源的铅同位素诠释

在矿质来源研究中,铅同位素组成作为一种有效手段,已应用于几乎所有的金属甚至非金属矿床,起到了重要的作用。随着矿床地球化学研究所的不断深入,一个矿床的矿质来源已不能简单地说来自地球的某个圈层,需要把矿质来源定位到矿区某个具体的岩体或层位,这样才具有实际意义,这样才具有实际意义。本文采取矿石、岩浆岩、地层及基底铅同位素对比的方法研究了４种矿床类型中９个金属矿床铅的来源。结果表明,与岩浆活动有关的夕卡岩     

内蒙古十八倾壕金矿床铅同位素组成的构造学意义

十八倾壕金矿有两种类型矿体：糜棱岩型矿体和石英脉型矿体。糜棱岩型矿石Pb同位素组成以低放射性成因铅为特点：^206Pb／^204Pb为16．63～17．45，^207pb／^304Pb为1531～15．48，^208Pb/^204Pb为36．52～38．85；在铅的动力学演化曲线上非常接近幔源铅演化模式曲线；与区域上典型的韧性剪切带型金矿——后石花金矿的铅同位素组成一致，是早元古代晚期(2040Ma)韧性剪切变质变形作用的产物。石英脉型矿石Pb同位素组成以高放射性成因铅为特点：^206Pb／^204Pb为18.23～19．74，^207Pb／^204Pb为15．69～15．89，^208Pb／^204pb为38．64～40．13；在铅的动力学演化曲线上非常接近上地壳铅演化的模式曲线；与区域上典型的燕山期岩浆热液型金矿——东伙房金矿以及燕山期花岗岩的铅同位素组成一致，是燕山期岩浆热液型金矿化。十八倾壕金矿是两次小同性质成矿作用叠加的结果。这从Pb同位素组成上证明了笔者曾经提出的关于该矿床叠加构造控矿的观点。     

辽南地区金矿床铅同位素组成特征

辽南地区是我国重要的金矿化集中区,区内产出大、中,小型金矿２０余处。简要叙述了猫岭,五龙,四道沟,岫岩,新房５个金矿床的地质概况。讨论了它们的铅同位素组成并划分为两大类：第一类具有正常铅的同位素组成,其成矿年龄与辽河群变质年龄相当;第二类具有异常铅的同位素组成。在铅构造模式图上,上述５个金矿床铅同位素组成具有壳源铅的特点。     

滇东南白牛厂多金属矿床铅同位素组成及铅来源新认识

白牛厂矿床位于滇东南锡多金属成矿带中部,是一个Ag、Pb、Zn、Sn等共生的多金属矿床,但成因争议较大.前人引用早期矿床矿石矿物铅同位素数据得出矿石铅主要来源于基底岩石淋滤,矿床经历了热水沉积+岩浆热液叠加两个成矿阶段的结论.本文采用最新铅同位素数据系统研究了白牛厂矿床的铅同位素组成,其中,白牛厂矿床矿石矿物的铅同位素组成206Pb/204Pb、207Pb/204Pb和208Pb/204Pb分别为17.264～18.537、14.843～15.862和38.481～39.424;薄竹山花岗岩长石铅同位素组成206Pb/204Pb、207Pb/204Pb和208Pb/204Pb分别为18.301～18.387、15.611～15.670和38.677～38.904;薄竹山岩体接触带型矿床(点)矿石矿物铅同位素组成206Pb/204Pb、207Pb/204Pb和208Pb/204Pb分别为18.302～18.417、15.603～15.692和38.596～38.868;区域地层及矿区地层钻孔样品铅同位素组成206Pb/204Pb、207Pb/204Pb和208Pb/204Pb分别为18.307～19.206、15.622～15.809和38.436～39.932.对比四者铅同位素组成特征,白牛厂矿床矿石矿物、薄竹山花岗岩长石、薄竹山岩体接触带型矿床(点)矿石矿物具有一致的铅同位素组成,与地层铅同位素组成相差甚远,表明白牛厂矿床铅主要来自岩浆作用,在侵入的过程中可能受到了地层的轻度混染.矿床地质特征及近期地球化学和年代学研究成果表明,白牛厂矿床的形成主要受岩浆作用影响,沉积成矿作用在白牛厂矿床很可能是不存在的.     

Source of ore-forming material for the Huangtuliang gold deposit,Hebei Province and ore prospecting in the deep periphery

The Huangtuliang gold deposit is characterized by its wide and large ore belt, stable extension and closely spaced orebodies. Unfortunately, no orebody was found by deep drilling. As a result, ore prospecting in this region was once put into dilemma. Detailed analysis of ore-forming and ore-controlling structures in the mining district by the authors has revealed that the ore-forming and ore-controlling structure in this mining district is a steeply dipping （85°-110°/∠70°-85° N-NNE）, spade-shaped ductile shear zone, and the ore-controlling structures are a series of nearly erected second-ordered faults which are developed in the upper part of the ductile shear zone, inter-secting with the ductile shear zone. Deep cutting of the ductile shear zone made it possible the ascending of ore fluids from the mantle plume at depth and these ore fluids would migrate upwards along the ductile shear zone under certain temperature and pressure conditions. Along their ascending path, the ore fluids would extract ore-forming elements from the country rocks and the extracted ore-forming elements would be deposited as ores in the hang- ing-wall second-ordered faults. The reason why no orebody was found in early prospecting at depth is that north- ward-dipping drilling in the southern part of the shear zone extended so deeply as to be beneath the shear zone. Only shallow-level orebodies could be found by southward-dipping drilling practice in the northern part of the shear zone. The location where deep-seated orebodies occurred shifted northwards and the orebodies occurred at greater depth. Therefore, it is natural that no orebody could be found when drill core passed through the shear zone. After the ore-forming and ore-controlling structures were well understood, the focus of ore prospecting was placed on the deep-level, northward-penetrating veins. In this way a number of new blind orebodies of great thickness have been found. On the basis of research development in the mining district, a prospecting plan has been made     

雅鲁藏布江蛇绿岩中地幔柱型岩浆作用——来自氦、氩同位素的证据

雅鲁藏布江蛇绿岩的氦、氩同位素组成分别是：蛇绿岩中变质橄榄岩的^3He/^4He比值为1．104-3．384Ra,平均为2．383Ra;玄武岩的He同位素组成比较均一,^3He/^4He平均值为5．359 Ra;辉绿岩的^3He／^4He比值变化较大,为1—5Ra。由于各岩石样品有不同程度的蚀变,造成放射性成因He的加入,因此大多数样品He同位素组成比低于亏损地幔大洋中脊玄武岩的值(MORB≈8Ra),不能真实反映源区特征。而采自吉定的辉绿岩样品^3He/^4He比值平均高达31．57Ra,与夏威夷发现的热点地幔源区的样品比值接近;分步加热法进一步测试,其高比值的He是在低温区段释放的。这种高^3He/^4He比值He的捕获,表明雅鲁藏布江蛇绿岩形成时存在地幔柱型富集地幔岩浆作用。     

Temporal and spatial distribution of Au-Ag polymetallic ore deposits and source of oreforming materials in the ZhangjiakouXuanhua mantle-branch metallogenetic zone

The Zhangjiakou-Xuanhua area is a mineral resource-concentrated area for gold-silver polymetallic ore deposits. The temporal and spatial distribution and origin of mineral resources have been argued for a long time. Based on the comprehensive studies of geochronology and sulfur, lead, oxygen, carbon and noble gas isotopes, it is considered that the temporal and spatial distribution of mineral resources in this area is obviously controlled by the Zhangjiakou-Xuanhua mantle branch structure, as is reflected by the occurrence of gold deposits in the inner parts and of Ag-Pb-Zn polymetallic ore deposits in the outer parts. The mineralization took place mainly during the Yanshanian period. Ore-forming materials came largely from the deep interior of the Earth, and hydrothermal fluids were derived predominantly from Yanshanian magmatism.