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在胶东莱州吴一村地区完成的3266.06 m深钻,是目前焦家金成矿带最深见矿钻孔,研究钻孔揭露的深部矿石中金矿物及黄铁矿微量元素特征,对探讨深部成矿作用演化具有重要意义。笔者采取深钻中2420~3206 m垂深的岩(矿)芯样品进行了详细的岩相学和矿相学研究,结合扫描电镜和电子探针微区分析,研究了矿石中金矿物的赋存状态和成分。对不同成矿阶段形成的黄铁矿进行了LA-ICPMS微量元素分析。研究结果表明,深部矿石中载金矿物主要为黄铁矿,其次为石英、黄铜矿、方铅矿,可见金主要以自然金和银金矿的形式存在,以晶隙金和裂隙金为主,其次为包体金。与浅部金矿床比较,深部金的成色较高。黄铁矿分为6种类型,第Ⅰ成矿阶段形成富Co型黄铁矿Py1,第Ⅱ成矿阶段形成富Ni型黄铁矿Py2a和Py2b,第Ⅲ成矿阶段形成富Au、As型黄铁矿Py3a和富Au、Ag、Pb、Bi型黄铁矿Py3b,第Ⅳ成矿阶段形成贫微量元素黄铁矿Py4。其中,Py1和Py2a发生强烈破碎,裂隙表面对热液中的Au络合物产生吸附作用,对金沉淀富集起重要作用。黄铁矿中Co、Ni、As等微量元素主要以类质同象形式赋存,而Au、Ag、Cu、Pb、Zn、Bi等主要以纳米级、微米级矿物包体形式赋存。Pb+Bi、Cu+Pb+Zn、Te+Bi与Au+Ag呈明显正相关,而Au与As相关性较差。黄铁矿中Co、Ni含量较低,而Au+Ag+As或Au+Ag+Pb+Bi+Cu含量较高指示成矿有利。另外,黄铁矿中Co、Ni含量较高,并且破碎强烈,成矿相关元素含量较高也指示成矿有利。 相似文献
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激光剥蚀电感耦合等离子体质谱(LA-ICP-MS)是一种固体微区分析新技术。用该技术来分析矿床中硫化物的微量元素组成可以为研究成矿流体特征、矿床成因及找矿勘探提供有关的科学信息。文中以安徽铜陵矿集区内新桥Cu-Au-S矿床中的黄铁矿为研究对象,在详细的野外观察和室内鉴定的基础上,将矿床中的黄铁矿分为具有沉积特征的胶状黄铁矿(PyⅠ)、具有变形重结晶和热液叠加作用特征的细粒他形黄铁矿(PyⅡ)和具热液成因特征的中—粗粒自形黄铁矿(PyⅢ)3种类型。LA-ICP-MS原位微量元素测定结果显示,PyⅠ中相对富含Ti、Co、Ni、As、Se、Te;PyⅡ继承了PyⅠ中富含Ti、Co、Ni、As、Se、Te、Bi的特征,同时还含有不均匀分布的少量成矿元素(Cu、Pb、Zn、Au、Ag);PyⅢ中成矿元素Cu、Pb、Zn、Ag、Au以及Bi元素的含量较高,Co、Ni、As的含量较低。在元素赋存状态方面,Co、Ni、As、Se和Te均以类质同象的形式进入到了黄铁矿的晶格中;Bi在PyⅡ中主要以含Bi矿物的微细包裹体形式存在,而在PyⅢ中的Bi还部分取代了Fe而占据了晶格;Cu、Pb、Zn、Au、Ag这些成矿元素中,Cu和Zn分别以黄铜矿和闪锌矿的矿物包裹体存在于黄铁矿中;PyⅡ中所含的少量Au、Ag,可能分别以自然金和自然银的形式存在,而在PyⅢ中Au可能主要以银金矿的形式存在,Ag除了以银金矿的形式存在以外还可能赋存于黄铁矿中含铋的矿物包裹体内;Pb主要赋存于黄铁矿中的方铅矿或含铋矿物的包裹体中。在综合分析黄铁矿的结构形态和微量元素组成特征的基础上认为,PyⅠ型黄铁矿可能形成于前人提出的晚古生代海底沉积或喷流沉积环境,PyⅡ和PyⅢ型黄铁矿分别形成于中生代区域构造变形-热液叠加改造的过渡环境和热液环境,PyⅡ和PyⅢ的形成时间相近。新桥矿床的形成可能经历了晚古生代海底沉积或喷流沉积期和燕山期热液期,胶黄铁矿主要形成于沉积成矿期,而矿床中成矿物质Cu、Pb、Zn、Au、Ag等主要来自燕山期岩浆侵入作用形成的热液成矿系统。 相似文献
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胶东地区是我国最大金成矿聚集区,其金矿床的成因长期以来一直存在很大争议,三山岛金矿床是胶东地区最大的金矿床,通过采用LA-ICP-MS分析不同阶段黄铁矿中微量元素组成,可以探讨成矿流体演化及成矿物质来源。根据野外地质特征及岩相学观察,结合SEM结构分析将三山岛金矿床的黄铁矿分为3个阶段,6个亚类,即黄铁绢英岩化带(Py1)中包裹大量绢云母和石英的Py1-a和表面光滑的Py1-b,石英—黄铁矿±菱铁矿脉(Py2)中富含矿物包裹体的Py2-a和与菱铁矿共生且表面光滑的Py2-b,石英—多金属硫化物脉(Py3)中有很多细粒多金属硫化物包裹体的Py3-a和表面光滑的Py3-b。3个阶段黄铁矿晶格中金含量均很低,大部分小于1×10^-6,金主要以可见金形式存在。从早阶段到晚阶段黄铁矿中Au与Ag,Cu,Pb,Sb有较好的正相关性,且含量有逐渐增加的趋势。最早阶段黄铁矿中Co+Ni的含量很高(最高为9268×10^-6),反映了早期黄铁矿可能来源于岩浆岩源区,后期Co/Ni值逐渐降低,暗示了成矿流体温度逐渐降低。结合地质特征和黄铁矿微量元素研究,表明三山岛金矿床成矿物质可能来源于深部岩浆热液储库,通过地震泵机制沿断裂构造多次侵位成矿。 相似文献
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【研究目的】为确定硫化物中金的赋存状态及元素含量特征。【研究方法】本文选取西天山萨瓦亚尔顿造山型金矿床(探明金储量127 t,远景资源量350 t),针对矿石矿物黄铁矿、毒砂开展系统显微岩/矿相学观测、电子探针、LAICP-MS和扫描电镜分析。【研究结果】结果表明萨瓦亚尔顿矿石中除可见金外,还有“不可见金”主要以固溶体(Au+)形式赋存于黄铁矿、毒砂中。矿石中载金黄铁矿发育3期:球丛状黄铁矿(Py0)呈浸染状分布于围岩中,局部富含金,同时富集Ag、As、Bi、Ni、Cu、Pb、Sb等微量元素;他形黄铁矿(Py1),分布于硅化围岩及强烈变形石英脉中,与他形毒砂(Apy1)伴生,电子探针得到的平均金含量为0.050%,富集Co、Mn、Zn等微量元素;自形—半自形黄铁矿(Py2),在矿体中分布最为广泛,与未变形石英脉密切共生,伴生自形毒砂(Apy2),电子探针分析得到的平均金含量为0.052%,微量元素相对Py1、Py2较为亏损。【结论】推测Py0形成于沉积成岩期;Py1形成于同碰撞期,与塔里木板块与中天山地块在晚石炭世碰撞事件有关;Py2形成于晚/后碰撞阶段。赋矿地层可能是金的初始矿源层,... 相似文献
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泥堡金矿床为黔西南地区新近发现的又一个重要的卡林型金矿床,显微镜下观察和电子探针分析显示,含砷黄铁矿是其主要的载金矿物。在详细的野外调研和室内观察的基础上,将该矿床中的载金含砷黄铁矿分为3种类型,即环带状含砷黄铁矿(PyⅠ)、胶状含砷黄铁矿(PyⅡ)和生物结构状含砷黄铁矿(PyⅢ)。电子探针和LA-ICP-MS原位主微量元素测定结果显示,PyⅠ明显存在继承核和增生环带,内核富S、Fe,贫Au、As、Ag、Cu等中低温成矿元素,为沉积成因或成矿前热液成因黄铁矿;增生环带则相对贫S、Fe,富Au、As、Ag、Cu等中低温成矿元素,为主成矿期热液成因黄铁矿。PyⅡ和PyⅢ均为均质结构,具有富Au、As、Ag、Cu等中低温成矿元素及贫S、Fe的特点,类似PyⅠ的增生环带,应与PyⅠ的增生环带为同一成因类型,可能是同期形成的。毒砂中普遍富As,而贫Au、Ag、Hg、Cu等元素,应为成矿热液晚期的结晶产物。综合分析认为,泥堡金矿床载金矿物的结晶顺序为:贫砷的沉积成因或早阶段热液成因黄铁矿(PyⅠ内核)→含砷黄铁矿颗粒+含砷黄铁矿环带(PyⅠ增生环带)→毒砂。矿床中Au、Ag、As、Cu等成矿物质主要来自于燕山晚期的岩浆热液系统。 相似文献
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曲家金矿位于我国重要的蚀变岩型金矿矿集区之焦家金矿带的中段,矿床赋存标高为-726~-1 334 m。为研究黄铁矿的演化及其对金成矿过程的指示,运用LA-ICP-MS分析黄铁矿原位微量元素含量,结合岩相学观察和点群分析对黄铁矿进行了分类。发现黄铁矿中Co、Ni、As等微量元素主要以类质同像形式赋存,而Au、Ag、Cu、Zn、Pb、Bi等元素主要以纳米级、微米级矿物包裹体形式赋存。黄铁矿主要分为5种类型:富Co型Py1,富Ni型Py2,富Au、As型Py3,富Au、Ag、Pb、Bi型Py4及“干净”型Py5。黄铁矿微量元素特征指示成矿物质可能主要来源于前寒武纪变质基底岩石和中生代岩浆岩,少量来源于地幔,成矿热液可能属变质热液、岩浆热液和浅部大气降水的混合成因。不同类型黄铁矿反映成矿热液由富Co、Ni经富As、Au向富Pb、Bi、Au、Ag演化。Py1和Py2形成后受构造活动影响发生强烈破碎,裂隙表面对热液中金络合物增强的吸附作用促使金在裂隙中沉淀,对金的富集成矿可能起重要作用。Co、Ni含量较低,同时Au、Ag、As、Pb、Bi等元素含量较高的黄铁矿与成矿作用有密切关系。另外,黄铁矿中C... 相似文献
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滇西老王寨金矿床黄铁矿形貌特征与化学组成 总被引:5,自引:4,他引:1
老王寨金矿床是三江特提斯成矿域中已探明规模最大的造山型金矿床,黄铁矿是其最主要的载金矿物,依据矿(化)脉切割关系、矿石结构构造及矿物共生组合,该矿床成岩-成矿期共发育5个世代黄铁矿。沉积-成岩期草莓状黄铁矿含Pb、Zn、Mn、Co、Ni和Bi。热液金成矿期可划分为:Ⅰ石英-绢云母-黄铁矿、Ⅱ石英-多金属硫化物、Ⅲ方解石-石英-毒砂-黄铁矿和Ⅳ方解石-石英-辉锑矿-黄铁矿四个阶段,其黄铁矿分别以粗粒他形、立方体、五角十二面体和立方体为主,总体继承了沉积-成岩期黄铁矿含Pb、Zn、Mn、Co、Ni和Bi的特征,Au、As、Sb和Cu也有不同程度富集,显示成矿流体成分复杂。Ⅲ阶段为金的主成矿阶段,以发育五角十二面体黄铁矿为特征,富集Au、As、Sb、Pb、Zn、Cu、Co、Ni和Bi,其中,Au与As构成 [Au, As]2-和[Au(As, S3)]2-等络合物以类质同象的形式替代[S2]2-而进入到黄铁矿中,两者呈正相关,成矿系统处于中-低温、流体过饱和度(硫逸度)高,且缓慢冷却,矿质来源充足的环境。 相似文献
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砂宝斯金矿床是上黑龙江盆地内唯一的大型岩金矿床,但其成矿物质来源和矿床成因仍然存在争议。为此,在详细的矿相学和黄铁矿显微结构研究基础上,对不同世代黄铁矿开展LA-ICP-MS微量元素和S、Pb同位素分析。结果表明,砂宝斯金矿床从成矿早期到主成矿阶段,黄铁矿可划分为3个世代,不同世代黄铁矿微量元素组成差异明显。PyⅠI为金的主成矿期,其中Au、Ag、Cu、Pb、Zn、Bi、Co、Ni、As、Mn、Sb、Sn、Ga等元素含量较高。Co、Ni、As以类质同象的形式进入黄铁矿晶格, Cu、Pb、Zn、Sb、Bi元素以金属硫化物矿物包裹体的形式赋存于黄铁矿中。Au元素以Au+、银金矿、铜金矿矿物包裹体微粒和亚微米的包体金形式存在于黄铁矿中。As–置换S–,形成Au(HAs)–,对Au的迁移及沉淀具有重要的作用。砂宝斯金矿床黄铁矿Co/Ni比值大多数小于1,大部分点落入沉积成因范围,少部分落入火山成因和热液成因范围,表明黄铁矿并非单一来源。综合S、Pb同位素及黄铁矿微量元素特征,砂宝斯金矿床成矿物质既来源于具上地壳和地幔混源特征的深部岩浆,又来源于二十二站组围岩。结合区域成矿构造背景,认为蒙古—鄂... 相似文献
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东坑铀矿床是粤北地区代表型花岗岩型铀矿床之一,复杂的成矿过程制约了人们对其成因的理解。文章依据成矿期次,将其中黄铁矿划分为4类:矿前期粗晶萤石-梳状石英中的黄铁矿(Py Ⅰ)、成矿期早阶段红色微晶石英中的自形-半自形黄铁矿(Py Ⅱ)、主成矿阶段沥青铀矿中的胶状-他形黄铁矿(Py Ⅲ)以及晚成矿阶段自形-半自形细粒黄铁矿(Py Ⅳ)。微量元素分析结果表明,黄铁矿中Co、Ni、As、Se主要以类质同象的形式存在,而U、Pb、Cu、Zn、Bi等元素则以矿物包裹体的形式存在。Py Ⅰ和Py Ⅱ具有相对较高的As、Tl含量和较低的Co、Ni以及U、W、Mo、V、Ti含量,表明其形成温度较低;Py Ⅲ具有最低的As、Tl含量和最高的Co、Ni、Ti、V、Mn、U、Mo含量,暗示流体温度相对较高,且辉绿岩或深源流体可能提供了部分物质;Py Ⅳ的As、Tl、Sb略微升高,Co、Ni及Se、U、Mo、W、Ti、V、Mn、Cu、Zn则降低,且其Co/Ni值变化较大,结合结构特征认为其形成于流体快速降温过程。不同矿床黄铁矿微量元素的对比结果表明,东坑铀矿床主成矿期黄铁矿与竹山下“交点型”和辉绿岩中黄铁矿类... 相似文献
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There are controversies about the genesis of the lode gold deposits in Jiaodong area. The Sanshandao gold deposit is the largest one in Jiaodong area. To better understand the genesis of the gold deposit, it is necessary to know the evolution of ore-forming fluid and the source of ore-forming material for the Sanshandao gold deposit. In this paper, the trace element composition of pyrite at different metallogenic stages in the Sanshandao gold deposit was analyzed by using LA-ICP-MS. Based on geological characteristics and petrography observation and SEM analysis, pyrite can be divided into three stages and six classes, including porous Py1-a and smooth Py1-b in pyrite-sericite-quartz alteration (Py1), many mineral inclusions in the Py2-a and smooth Py2-b associated with carbonate in the quartz-pyrite ± siderite veins (Py2), a lot of polymetallic sulfide inclusions hosted Py3-a and Py3-b with smooth and oscillation band in the quartz-polymetallic sulfide vein (Py3). The experimental results show that the gold content is very low in the lattice of pyrite, most of which is less than 1×10-6, and gold mainly occurs in the form of visible gold. The contents of Au, Ag, Cu, Pb and Sb of pyrite gradually increase from early stage to late stage. The high content of Co+Ni in the earliest stage (up to 9268×10-6) reflects that pyrite in the early stage is likely derived from magma, and the Co/Ni ratio gradually decreases, suggesting the decrease of ore forming fluid temperature. Combined with the geological observations and trace elements component of pyrite, the study shows that the genesis of the Sanshandao gold deposit is related to the evolution of magmatic hydrothermal reservoir. The ore-forming fluid is transported several times along the fault by seismic pumping. 相似文献
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Basem Zoheir Richard Goldfarb Astrid Holzheid Hassan Helmy Ahmed El Sheikh 《地学前缘(英文版)》2020,11(1):325-345
The Um Rus tonalite-granodiorite intrusion(~6 km2)occurs at the eastern end of the Neoproterozoic,ENE-trending Wadi Muba rak shear belt in the Central Eastern Desert of Egypt.Gold-bearing quartz veins hosted by the Um Rus intrusion were mined intermittently,and initially by the ancient Egyptians and until the early 1900 s.The relationship between the gold mineralization,host intrusion,and regional structures has always been unclear.We present new geochemical and geochronological data that help to define the tectonic environment and age of the Um Rus intrusion.In addition,field studies are integrated with EPMA and LA-ICP-MS data for gold-associated sulfides to better understand the formation and distribution of gold mineralization.The bulk-rock geochemical data of fresh host rocks indicate a calc-alkaline,metaluminous to mildly peraluminous,I-type granite signature.Their trace element composition reflects a tectonic setting intermediate between subduction-related and within-plate environments,presumably transitional between syn-and post-collisional stages.The crystallization age of the Um Rus intrusion was determined by in situ SHRIMP 206 Pb/238 U and 207Pb/235U measurements on accessory monazite grains.The resultant monazite U-Pb weighted mean age(643±9 Ma;MSWD 1.8)roughly overlaps existing geochronological data for similar granitic intrusions that are confined to major shear systems and are locally associated with gold mineralization in the Central Eastrn Desert(e.g.,Fawakhir and Hangaliya).This age is also consistent with magmatism recognized as concomitant to transpressional tectonics(D2:~650 Ma)during the evolution of the Wadi Mubark belt.Formation of the gold-bearing quartz veins in NNE-SSW and N-S striking fault segments was likely linked to the change from transpressional to transtensional tectonics and terrane exhumation(D3:620-580 Ma).The development of N-S throughgoing fault arrays and dike swarms(~595 Ma)led to heterogeneous deformation and recrystallization of the mineralized quartz veins.Ore minerals in the auriferous quartz veins include ubiquitous pyrite and arsenopyrite,with less abundant pyrrhotite,chalcopyrite,sphalerite,and galena.Uncommon pentlandite,gersdorffite,and cobaltite inclusions hosted in quartz veins with meladiorite slivers are interpreted as pre-ore sulfide phases.The gold-sulfide paragenesis encompasses an early pyrite-arsenopyrite±loellingite assemblage,a transitional pyrite-arsenopyrite assemblage,and a late pyrrhotite-chalcopyrite-sphalerite±galena assemblage.Free-milling gold/electrum grains(10 sμm-long)are scattered in extensively deformed vein quartz and in and adjacent to sulfide grains.Marcasite,malachite,and nodular goethite are authigenic alteration phases after pyrrhotite,chalcopyrite,and pyrite and arsenopyrite,respectively.A combined ore petrography,EPMA,and LA-ICP-MS study distinguishes morphological and compositional differences in the early and transitional pyrites(PyⅠ,PyⅡ)and arsenopyrite(ApyⅠ,ApyⅡ).Py I forms uncommon small euhedral inclusions in later PyⅡand Apy II.PyⅡforms large subhedral crystals with porous inner zones and massive outer zones,separated by narrow As-rich irregular mantles.The Fe and As contents in PyⅡare variable,and the LA-ICP-MS analysis shows erratic concentrations of Au(<1 to 177 ppm)and other trace elements(e.g.,Ag,Te,and Sb)in the porous inner zones,most likely related to discrete sub-microscopic sulfide inclusions.The outer massive zones have a rather homogenous composition,with consistently lower abundances of base metals and Au(mean 1.28 ppm).The early arsenopyrite(Apy I)forms fine-grained euhedral crystals enriched in Au(mean 17.7 ppm)and many other trace elements(i.e.,Ni,Co,Se,Ag,Sb,Te,Hg,and Bi).On the other hand,ApyⅡoccurs as coarsegrained subhedral crystals with lower and less variable concentrations of Au(mean 4 ppm).Elevated concentrations of Au(max.327 ppm)and other trace elements are measured in fragmented and aggregated pyrite and arsenopyrite grains,whereas the undeformed intact zones of the same grains are poor in all trace elements.The occurrence of gold/electrum as secondary inclusions in deformed pyrite and arsenopyrite crystals indicates that gold introduction was relatively late in the paragenesis.The LAICP-MS results are consistent with gold redistribution by the N-S though-going faults/dikes overprinted the earlier NNW-SSE quartz veins in the southeastern part of the intrusion,where the underground mining is concentrated.Formation of the Um Rus intrusion and gold-bearing quartz veins can be related to the evolution of the Wadi Mubarak shear belt,where the granitic intrusion formed during or just subsequent to D2 and provided dilatation spaces for gold-quartz vein deposition when deformed by D3 structures. 相似文献
14.
Gold deposits at El Sid are confined to hydrothermal quartz veins which contain pyrite, arsenopyrite, sphalerite and galena. These veins occur at the contact between granite and serpentinite and extend into the serpentinite through a thick zone of graphite schist. Gold occurs in the mineralized zone either as free gold in quartz gangue or dissolved in the sulfide minerals. Ore-microscopic study revealed that Au-bearing sulfides were deposited in two successive stages with early pyrite and arsenopyrite followed by sphalerite and galena. Gold was deposited during both stages, largely intergrown with sphalerite and filling microfractures in pyrite and arsenopyrite.Spectrochemical analyses of separated pyrite, arsenopyrite, sphalerite and galena showed that these sulfides have similar average Au contents. Pyrite is relatively depleted in Ag and Te. This suggests that native gold was deposited in the early stage of mineralization. Arsenopyrite and galena show relatively high concentrations of Te. They are also respectively rich in Au and Ag. Tellurides are, thus, expected to be deposited together with arsenopyrite and galena. 相似文献
15.
I. V. Vikentyev R. Kh. Mansurov Yu. N. Ivanova E. E. Tyukova I. D. Sobolev V. D. Abramova R. I. Vykhristenko A. P. Trofimov V. B. Khubanov E. O. Groznova S. S. Dvurechenskaya S. G. Kryazhev 《Geology of Ore Deposits》2017,59(6):482-520
Geological and structural conditions of localization, hydrothermal metasomatic alteration, and mineralization of the Petropavlovskoe gold deposit (Novogodnenskoe ore field) situated in the northern part of the Lesser Ural volcanic–plutonic belt, which is a constituent of the Middle Paleozoic island-arc system of the Polar Urals, are discussed. The porphyritic diorite bodies pertaining to the late phase of the intrusive Sob Complex play an ore-controlling role. The large-volume orebodies are related to the upper parts of these intrusions. Two types of stringer–disseminated ores have been revealed: (1) predominant gold-sulfide and (2) superimposed low-sulfide–gold–quartz ore markedly enriched in Au. Taken together, they make up complicated flattened isometric orebodies transitory to linear stockworks. The gold potential of the deposit is controlled by pyrite–(chlorite)–albite metasomatic rock of the main productive stage, which mainly develops in a volcanic–sedimentary sequence especially close to the contacts with porphyritic diorite. The relationships between intrusive and subvolcanic bodies and dating of individual zircon crystals corroborate a multistage evolution of the ore field, which predetermines its complex hydrothermal history. Magmatic activity of mature island-arc plagiogranite of the Sob Complex and monzonite of the Kongor Complex initiated development of skarn and beresite alterations accompanied by crystallization of hydrothermal sulfides. In the Early Devonian, due to emplacement of the Sob Complex at a depth of approximately 2 km, skarn magnetite ore with subordinate sulfides was formed. At the onset of the Middle Devonian, the large-volume gold porphyry Au–Ag–Te–W ± Mo,Cu stockworks related to quartz diorite porphyry—the final phase of the Sob Complex— were formed. In the Late Devonian, a part of sulfide mineralization was redistributed with the formation of linear low-sulfide quartz vein zones. Isotopic geochemical study has shown that the ore is deposited from reduced, substantially magmatic fluid, which is characterized by close to mantle values δ34S = 0 ± 1‰, δ13C =–6 to–7‰, and δ18O = +5‰ as the temperature decreases from 420–300°C (gold–sulfide ore) to 250–130°C (gold–(sulfide)–quartz ore) and pressure decreases from 0.8 to 0.3 kbar. According to the data of microanalysis (EPMA and LA-ICP-MS), the main trace elements in pyrite of gold orebodies are represented by Co (up to 2.52 wt %), As (up to 0.70 wt %), and Ni (up to 0.38 wt %); Te, Se, Ag, Au, Bi, Sb, and Sn also occur. Pyrite of the early assemblages is characterized by high Co, Te, Au, and Bi contents, whereas the late pyrite is distinguished by elevated concentrations of As (up to 0.7 wt %), Ni (up to 0.38 wt %), Se (223 ppm), Ag (up to 111 ppm), and Sn (4.4 ppm). The minimal Au content in pyrite of the late quartz–carbonate assemblage is up to 1.7 ppm and geometric average is 0.3 ppm. The significant correlation between Au and As (furthermore, negative–0.6) in pyrite from ore of the Petropavlovskoe deposit is recorded only for the gold–sulfide assemblage, whereas it is not established for other assemblages. Pyrite with higher As concentration (up to 0.7 wt %) is distinguished only for the Au–Te mineral assemblage. Taking into account structural–morphological and mineralogical–geochemical features, the ore–magmatic system of the Petropavlovskoe deposit is referred to as gold porphyry style. Among the main criteria of such typification are the spatial association of orebodies with bodies of subvolcanic porphyry-like intrusive phases at the roof of large multiphase pluton; the stockwork-like morphology of gold orebodies; 3D character of ore–alteration zoning and distribution of ore components; geochemical association of gold with Ag, W, Mo, Cu, As, Te, and Bi; and predominant finely dispersed submicroscopic gold in ore. 相似文献
16.
小秦岭地区不同矿化类型的含Au石英脉Au/Ag值有不同的特点,多金属硫化物型一般小于0.8,黄铁矿型介于0.8-2.0之间,少黄铁矿型一般大于2.0。利用Au/Ag值可以大致确定矿脉的矿化类型,判断矿脉的水平,垂向分带和剥蚀深度,预测深部矿脉的矿化类型,东闯金矿床深部Au/Ag值为1.39,预示其深部有可能出现黄铁矿型矿化,深部探矿仍有前景。 相似文献
17.
LA-ICP-MS trace element analysis of pyrite from the Xiaoqinling gold district, China: Implications for ore genesis 总被引:7,自引:0,他引:7
Hai-Xiang Zhao Hartwig E. Frimmel Shao-Yong Jiang Bao-Zhang Dai 《Ore Geology Reviews》2011,43(1):142-153
The Xiaoqinling district, the second largest gold producing district in China, is located on the southern margin of the North China Craton. It consists of three ore belts, namely, the northern ore belt, the middle ore belt and the southern ore belt. Pyrite from the Dahu gold deposit in the northern ore belt and Wenyu and Yinxin gold deposits in the southern ore belt were investigated using a combination of ore microscopy and in-situ laser-ablation inductively-coupled plasma-mass spectrometry (LA-ICP-MS). A range of trace elements was analyzed, including Au, Te, Ag, Pb, Bi, Cu, Co, Ni, Zn, Mo, Hg, As and Si. The results show that there are no systematic differences between the trace element compositions of pyrite in the three deposits from different ore belts. In general, Au concentrations in pyrite are low (from < 0.01 ppm to 2.2 ppm) but Ni concentrations are rather high (up to 8425 ppm). A four-stage mineralization process is indicated by microscopic and field observations and this can be related to the systematic trace element differences between distinct generations of pyrite. Stage I precedes the main gold mineralization stage; pyrite of this stage has the lowest Au concentrations. Stages II and III contributed most of the gold to the ore-forming system. The corresponding pyrite yielded the highest concentrations of Au and Ni. Our microscopic observations suggest that pyrite in the main gold mineralization stage precipitated simultaneously with molybdenite that has been previously dated as Indosinian (~ 218 Ma by Re–Os molybdenite dating), indicating the Indosinian as the main gold mineralization stage. The Indosinian mineralization age and the geological and geochemical features of these gold deposits (e.g., low salinity, CO2-rich ore fluids; spatial association with large-scale compressional structures of the Qinling orogen; δ18O and δD data suggestive of mixing between metamorphic and meteoric waters; δ34S and Pb-isotopic data that point to a mixed crustal-mantle source) all point to typical orogenic-type gold deposits. High Ni concentrations (up to 8425 ppm) of pyrite possibly linked to deep-seated mafic/ultramafic metamorphic rocks provide further evidence on the orogenic gold deposit affinity, but against the model of a granitic derivation of the mineralizing fluid as previously suggested by some workers. Generally low Au concentration in pyrite is also consistent with those from worldwide orogenic gold deposits. Therefore, the gold mineralization in the Xiaoqinling district is described as orogenic type, and is probably related to Indosinian collision between the North China Craton and the Yangtze Craton. 相似文献