Au–Ag–Te Mineralization of the Low‐Sulfidation Epithermal Aginskoe Deposit,Central Kamchatka,Russia

Mineralogic studies of major ore minerals and fluid inclusion analysis in gangue quartz were carried out for the for the two largest veins, the Aginskoe and Surprise, in the Late Miocene Aginskoe Au–Ag–Te deposit in central Kamchatka, Russia. The veins consist of quartz–adularia–calcite gangue, which are hosted by Late Miocene andesitic and basaltic rocks of the Alnei Formation. The major ore minerals in these veins are native gold, altaite, petzite, hessite, calaverite, sphalerite, and chalcopyrite. Minor and trace minerals are pyrite, galena, and acanthine. Primary gold occurs as free grains, inclusions in sulfides, and constituent in tellurides. Secondary gold is present in form of native mustard gold that usually occur in Fe‐hydroxides and accumulates on the decomposed primary Au‐bearing tellurides such as calaverite, krennerite, and sylvanite. K–Ar dating on vein adularia yielded age of mineralization 7.1–6.9 Ma. Mineralization of the deposit is divided into barren massive quartz (stage I), Au–Ag–Te mineralization occurring in quartz‐adularia‐clays banded ore (Stage II), intensive brecciation (Stage III), post‐ore coarse amethyst (Stage IV), carbonate (Stage V), and supergene stages (Stage VI). In the supergene stage various secondary minerals, including rare bilibinskite, bogdanovite, bessmertnovite metallic alloys, secondary gold, and various oxides, formed under intensely oxidized conditions. Despite heavy oxidation of the ores in the deposit, Te and S fugacities are estimated as Stage II tellurides precipitated at the log f Te₂ values ?9 and at log fS₂ ?13 based on the chemical compositions of hypogene tellurides and sphalerite. Homogenization temperature of fluid inclusions in quartz broadly ranges from 200 to 300°C. Ore texture, fluid inclusions, gangue, and vein mineral assemblages indicate that the Aginskoe deposit is a low‐sulfidation (quartz–adularia–sericite) vein system.     

新疆阿希金矿:古生代的低硫型浅成低温热液金矿床

新疆阿希金矿床为一形成于古生代的低硫型浅成低温热液金矿床,矿床产于伊犁—中天山板块北部中天山北缘活动大陆边缘的吐拉苏火山岩断陷盆地中。其赋矿围岩为大哈拉军山组安山质火山岩和火岩碎屑岩,矿体呈脉状产于古火山口外围的环形断裂带中,主要金属矿物有自然金、银金矿、黄铁矿、白铁矿、毒砂、赤铁矿、褐铁矿以及微量的浓红银矿、硒银矿、硫锑铜银矿、角银矿等,非金属矿物有石英、玉髓、菱铁矿、方解石、绢云母、冰长石等,围岩蚀变作用主要有硅化、绢云母化、碳酸盐化和青盘岩化。矿床以富集Au、Ag、As、Sb、Bi、Hg、Se、Te、Mo元素组合为特征,Ag/Au比值小,为0.46～11.1。氢、氧、碳、硫及稀有气体同位素组成特征显示其成矿流体主要为循环大气降水;成矿流体盐度主要为0.7%～3.1%NaCl_(eqv),平均为2.2%NaCl_(eqv);成矿温度为120～240℃,平均190℃;最大成矿深度约700 m。沸腾作用是引起成矿流体中矿质发生沉淀富集的主要成矿机制,成矿作用过程中流体处于近中性pH值的还原环境,成矿时代介于晚泥盆世晚期((363.2±5.7)Ma)到早石炭世维宪期。其一系列特征显示该矿是一个典型的、形成于古生代的低硫型浅成低温热液型金矿床。矿床得以保存与矿床形成后很快被阿恰勒河组沉积盖层覆盖有关,从上新世开始由于印度板块对欧亚板块的碰撞挤压作用,天山造山带被快速抬升遭受风化剥蚀作用使矿床重新露出地表而被发现。阿希金矿的发现对于在中、新生代以前的造山带中寻找浅成低温热液型金矿床具有重要的借鉴和指导意义。     

甘肃省迭部县加勒克金矿地质特征及成因探讨

加勒克金矿呈脉状、不规则囊状或漏斗状产于西秦岭造山带古道岭组灰岩中,矿化受到NWW向和近EW向断裂严格控制,矿石矿物以赤铁矿、自然金和黄铁矿为主,蚀变以硅化、绢云母化和褐（赤）铁矿化为特征。矿石主要为碎裂岩型、硅化碎裂斑岩型、碎裂灰岩型。成矿作用方式主要为热液渗滤交代、构造裂隙等有限空间的充填沉淀作用,构成比较完整的热液交代-充填-沉淀成矿体系经历了原生热液成矿期和表生氧化-次生富集期。成矿环境为近地表,成矿时代为印支晚期,成矿物质来源与印支期陆内造山阶段酸性岩浆活动密切有关,金矿化和岩浆岩可能是统一的受深部构造制约的印支期构造-岩浆-热液活动体系的系列演化产物。     

Polymetallic and Au-Ag Mineralizations at the Mutnovskoe Deposit in South Kamchatka, Russia

Abstract. The Mutnovskoe deposit located in the Porozhisto‐Asachinskaya metallogenic province of South Kamchatka, Russia, is a polymetallic vein and Au‐Ag quartz vein associated type of hydrothermal deposit. The Mutnovskoe deposit is located inside a paleo‐caldera structure at the center of the Mutnovsko‐Asachinskaya geothermal field of Pliocene ‐ Quaternary age, where active gold deposition is identified in hot spring precipitate. The Mutnovskoe deposit is subdivided into the north flank, the central flank and the south flank based on the vein distributions and mineral parageneses. The mineralized vein system is oriented N‐S hosted in diorite ‐ gabbroic diorite stock, volcanic rocks and sedimentary rocks of Miocene ‐ Pleistocene age. The mineralization stage I (polymetallic vein) mainly in the central and the south flanks is Zn‐Pb‐Cu‐Au‐Ag contained in sphalerite, galena and tetrahedrite‐tennantite group mineral. The stage II (Au‐Ag quartz vein) occurs in the north and the central flanks. The stage III (Mn‐sulfide and Mn‐Ca‐carbonate vein) occurs in the whole deposit area. Stage II is the typical Au‐Ag quartz‐adularia vein of low‐sulfidation type. Stage III is alabandite‐rhodochrosite‐quartz‐calcite vein. The K‐Ar ages are 1.3±0.1 Ma for stage I sericite in alteration zone, and 0.7±0.1 Ma for the stage II adularia in mineralized vein. Based on the fluid inclusion study, range of ore forming temperature of the Mutnovskoe deposit is 200 to 260d?C (av. 230d?C). Salinities of fluid inclusions indicate 2.2 to 5.7 wt% NaCl in sphalerite and 0.8 to 3.3 wt% NaCl in quartz for the stage I. Mineral paragenesis of the polymetallic vein (stage I) is characterized by a district zoning of tennantite and Cd‐rich sphalerite in the south flank and tetrahedrite and Mn‐rich sphalerite in the central flank, which is due to the fractional crystallizations of ore‐forming fluid. Depositional condition of the low sulfidation state is inferred for the Mutnovskoe deposit, where the polymetallic vein of the south flank is in relatively higher sulfidation state than the central flank.     

陕西略阳张家山金矿成矿作用及Au-Se矿物形成物理化学条件研究

陕西略阳煎茶岭金矿矿集区中的张家山金矿主要由破碎蚀变岩型、角砾岩型和含金石英黄铁矿脉型矿石组成。含金石英-黄铁矿脉型矿石产于断层下盘的石英菱镁岩中。黄铁矿发育富As黄铁矿边,环边受As含量的变化呈现一定的韵律变化,自然金赋存在富As黄铁矿中。在断裂发育形成断层角砾岩的过程中,流体充填破碎石英菱镁岩的裂隙中形成热液矿物,包括硫化物、硒化物以及自然金。石英菱镁岩发生破碎形成的网状裂隙被含金石英-方解石-黄铁矿脉充填。破碎蚀变岩型矿石中,自然金主要分布在含金石英-黄铁矿脉的石英之中或靠近热液脉的菱镁矿或石英间隙。随着大量方解石脉沿裂隙贯入,进一步促进石英菱镁岩的破碎及岩石角砾的分离,形成由石英菱镁岩碎屑、石英和褐铁矿组成的复成分角砾岩,自然金和硒化物呈浸染状分布在角砾岩中。笔者在角砾岩型矿石中发现了灰硒汞矿、直硒镍矿、硒铅矿等硒化物,这些硒化物往往与自然金密切共生。结合矿物组合以及相关化学反应关系,通过热力学计算,构建了该矿床在不同温度条件下的热力学相平衡关系图,限定了硒化物与其他相关矿物稳定存在的物理化学条件。硒化物一般与自然金和石英共生,高的f(Se2)值和f(Se2)/f(S2)比值是控制硒化物形成的关键因素。     

马来西亚吉兰丹SOKOR金矿地质特征及成因浅析

马来半岛金矿主要分布在半岛中央金矿带北部,该成矿带地处特提斯成矿带与环太平洋成矿带交汇处,成矿条件优越。含矿岩石主要是千枚岩及石英斑岩,矿物以黄铁矿为主,矿体产状与接触带产状基本一致,金矿化类型主要有含金块状硫化物型、含金石英脉型及褐铁矿型3种,品位变化较大。矿床地质特征、矿体产状及矿化蚀变信息表明成矿与热液活动紧密相关,应属于浅成低温热液型金矿。     

北京万庄金矿床成矿特征及成因探讨

北京平谷万庄金矿产于燕山沉降带内的中元古界碳酸盐岩中，金矿化受燕山期三百山岩体、变质地层、层间虚脱构造及多期活动的NE走向断裂构造控制。金矿体呈筒状、扁担状及脉状产出。矿石矿物以褐铁矿、黄铁矿、自然金、银金矿为主。矿石类型主要有硅化多金展硫化物型和硅化黄铁矿型。矿区内矿化水平分带性明显。自三百山岩体为中心，从岩体内部到接触带，再到外接触带的变质地居中，依次发育有热液脉型铜矿化、夕卡岩铜金矿化和热液型金矿化，其中前两者未形成县有工业意又的矿床，仅第三者形成具有工业意又的万庄金矿床。矿区内大古界密云群基底变质岩为万庄金矿的形成提供了部分矿源，三百山闪长玢岩及石英闪长岩为成矿提供了热源和部分含矿热液，并与循环大气水混合促进了金的沉淀。中元古代长城系碳酸盐岩成为金矿化的有利围岩。万庄金矿为一层控特征明显的中低温热液型金矿床。     

Mineralogical and Geochemical Characteristics of the Utanobori Gold Deposit in Northern Hokkaido,Japan

The Utanobori gold deposit is a low‐sulfidation, epithermal vein‐type deposit located in northern Hokkaido, Japan. The deposit is hosted by conglomerate, sandstone, and tuff of the Middle to Late Miocene Esashi Formation. These rocks were hydrothermally altered. Silica sinters and quartz‐adularia veins are common in the deposit. The quartz‐adularia veins either contain a ginguro band, which corresponds to the main gold‐bearing vein (Type 1 Veins), or do not contain a ginguro band but contain minor adularia (Type 2 Veins). Type 1 Veins are divided into three stages with 12–14 substages. Ore minerals identified include electrum, naumannite, chlorargyrite, bromargyrite, an unidentified Fe‐Sb mineral, and an Fe‐(Sb)‐As mineral. These ore minerals formed in the main mineralization stages I (bands I‐b and I‐d) and II (band II‐a). Scanning electron microscopy with cathodoluminescence images show that cathodoluminescence‐dark microcrystalline quartz exhibiting colloform (ghost‐sphere) texture is closely associated with ore minerals in the Type 1 Vein and Type 2 Vein, and the Al and K contents of such quartz are commonly >1000 ppm. This indicates that the ore minerals were crystallized from alkaline, silica‐saturated fluids at temperatures <200°C, which initially deposited amorphous silica that was recrystallized to microcrystalline quartz. The average Au content of electrum is 52.5 at% Au (n = 10), 65.7 at% Au (n = 20), and 55.5 at% Au (n = 5) in bands I‐b, I‐d, and II‐a, respectively, of Type 1 Veins. The δ³⁴S_CDT values of two fine‐grained disseminated pyrites in the altered conglomerate and bedded tuff in the argillic altered zone are ?4.3 and ?4.2‰. Ar‐Ar dating on adularia yielded 13.6 ± 0.06 Ma, 13.6 ± 0.07 Ma, and 13.6 ± 0.06 Ma for the stages I, II, and III of the Type 1 Vein, respectively. K‐Ar ages determined on adularia in the silica sinter and on whole‐rock of glassy rhyolite of the Esashi Formation are 15.0 ± 0.4 Ma and 14.6 ± 0.4 Ma, respectively. These radiometric ages indicate that silica sinter associated with the rhyolitic volcanic rocks formed prior to the main gold mineralization.     

金坝金矿床地质特征

金坝超微粒型金矿床有30多个矿体,划分6个矿带.矿带NE向展布,带长350~2000m.矿体呈透镜状、似层状、串珠状产出.者桑复背斜控制矿化带的分布,断裂构造为含矿热液提供运移通道,次级构造控制矿体具体储存部位及矿体的形态产状.赋矿层位以上二叠统为主(含5个矿带),还有下中三叠统.容矿岩石有泥质粉砂岩、粉砂岩、粉砂质凝灰岩、凝灰岩、泥质白云岩、细碧岩、辉绿岩脉等.矿化类型:地层岩石破碎带蚀变岩型、脉岩破碎蚀变岩型以及石英脉型.围岩蚀变有黄铁矿化、毒砂化、硅化、碳酸盐化等.矿石类型按自然分类为氧化矿石和原生矿石;按岩石类型划分为凝灰岩类矿石,粉砂岩、粉砂质泥岩类矿石,泥质白云岩矿石,辉绿岩矿石以及细碧岩矿石.矿石含金品位0.5×10^-6~15.9×10^-6.原生矿石金属矿物有黄铁矿、毒砂、黄铜矿;氧化矿石金属矿物有褐铁矿、臭葱石等;而脉石矿物主要取决于各自的容矿岩石.矿石的化学组成:SiO₂比原岩低,(Fe₂O₃+FeO)高于原岩,富K贫Na.微量元素Au、Ag、As、Sb、Cu高于原岩.矿石为泥质结构、细碎屑结构、凝灰结构、辉绿结构、粒状结晶结构、环边环带结构;碎裂构造、角砾构造、浸染状构造、结核状蜂窝状构造等.金以微包体金的形式赋存于褐铁矿、毒砂、黄铜矿中.     

湘西沃溪钨锑金矿床辉锑矿脉矿物学特征及其矿床成因指示

辉锑矿脉为沃溪钨锑金矿床最具工业价值的矿石类型。本文报道了近期对该型矿石的主要矿石矿物如自然金、自然锑、辉锑矿、白钨矿、黑钨矿等的观察研究和电子探针分析结果。分析了矿石矿物微量化学成分特征及其所揭示的矿床成因信息。研究表明，矿床成矿应与区域构造—岩浆作用有成因联系。从而建立了该矿床新的成矿机理模式。     

金厂沟梁——二道沟金矿田地质地球化学特征及成因探讨

金厂沟梁－二道沟金矿田的大地构造位置为内蒙地轴上的努鲁儿虎隆起区，其金矿脉多属石英－硫化物复合脉型，矿脉的产状受NW向区域断裂及对面沟岩体侵入形成的主动式断裂构造控制。主要矿物有石英、黄铁矿、黄铜矿等，载金矿物主要为黄铁矿、石英；矿床的矿化和蚀变具多阶段叠加性。其氢氧同位素特征表明，岩体、围岩、矿体三者具有密切关系，矿石的氢氧同位素特征表明金矿热液来源于岩浆，并有雨水加入，硫同位素值接近陨石硫值，具单峰塔式效应，矿体铅与岩体铅具有一致性，岩体与矿体稀土曲线具相似性。从而认为金厂沟梁－二道沟金矿田的成因为重熔岩浆热液型矿床。     

北山地区金矿床金的赋存状态和金矿物特征

甘肃北山地区金矿床主要有岩浆热液型金矿床和与韧性剪切带有关的金矿床,矿化类型为石英脉型和蚀变岩型。金多呈独立金矿物形式出现,少放许呈分散状;金矿物以银金矿为主,次为自然金,平均成色７７２;金矿物以粒间金、裂隙金、连生金、连生金和包体金等形成嵌布于石英、黄铁矿、方铅矿及闪锌矿等主要载物较为发育。金矿物特征反映出本区金矿床的成矿物质主要来源于变质岩,华力西－印支期中酸性岩浆活动是主要的动力源。     

安徽白岭金矿金的赋存状态研究

白岭金矿位于下扬子台坳、长江褶断隆起带中段。金矿体赋存于三叠系中统铜头尖组中，矿体形态呈不规则脉状。矿石类型主要有以含金褐铁矿为主的氧化矿石和以含金黄铁矿为主的原生矿石两大类。载金矿物主要有黄铁矿、褐铁矿、石英、伊利石、黄铜矿等。通过矿相鉴定，单矿物含金分析、物相分析、多点分析、电子探针分析等，查明了金的赋存状态。金矿物以自然金为主，其次为银金矿。金的粒度较细，主要为中细粒显微金。金的嵌布类型有包体金、晶隙金、裂隙金。金的成色较高，平均为906．5。金主要呈矿物态存在。     

Geology,geochemistry, and genesis of Axi: A Paleozoic low-sulfidation type epithermal gold deposit in Xinjiang,China

Axi is a low-sulfidation type epithermal gold deposit hosted in Paleozoic subaerial volcanic rocks in the western Tianshan orogenic belt, Xinjiang, China. The resource is more than 50 t gold at an average grade of > 4.4 ppm. The deposit occurs in the Tulasu volcanic fault-basin in the Paleozoic active continental margin on the northern side of the Yili-Central Tianshan plate. The host rocks are andesitic volcaniclastic rocks of the Paleozoic Dahalajunshan Formation, and the orebodies occur as veins in annular faults of a paleocaldera. Mineralization at Axi can be subdivided into five stages: quartz and/or chalcedony vein, quartz vein, quartz-carbonate vein, sulfide vein and carbonate vein. There are two types of ore host: quartz vein and altered rocks. Ore minerals are native gold, electrum, pyrite, marcasite, arsenopyrite, hematite, limonite, and trace amounts of pyrargyrite, polybasite, naumannite, cerargyrite, sphalerite, chalcopyrite, tetrahedrite, galena, pyrrhotite and clausthalite; gangue minerals are mainly quartz, chalcedony, illite, calcite, siderite, dolomite, adularia and laumontite. The main wall-rock alteration is silicification and phyllic alteration, carbonatization and propylitization. The deposit is characterized by an enrichment, relative to crustal abundance, of Au, Ag, As, Sb, Bi, Hg, Se, Te and Mo, depletion in base metals (Cu, Pb, and Zn), and a low Ag/Au ratio (0.5–3.7).Three types of fluid inclusions were recognized in quartz from the major mineralization stages: liquid aqueous inclusions, liquid-rich two-phase inclusions and small amounts of vapor-rich two-phase inclusions. Microthermometric measurements indicate that the final ice melting temperatures are − 0.3 to − 4.4 °C, corresponding to salinities of 0.5–6.9 wt.% NaCl equiv. (2.2 wt.% NaCl equiv. in average). The peak temperatures of ice melting varies from − 0.4 to − 1.9 °C, corresponding to salinities of 0.7–3.1 wt.% NaCl equiv. Homogenization temperatures range mainly between 120 and 240 °C, with an average of 190 °C and a maximum of 335 °C. The fluid density is 0.73 to 0.95 g/cm³ and thus the estimated maximum mineralization depth is about 700 m.Hydrogen and oxygen isotopic compositions of the ore fluids lie within a narrow range: δD_H2O is − 98 to − 116‰ and δ¹⁸O_H2O − 1.8 to 0.4‰. ³He/⁴He ranges from 0.0218 to 0.138 Ra, with an average of 0.044 Ra, indicating that He derived predominantly from crust with negligible mantle He in the ore fluids. By contrast, the ⁴⁰Ar/³⁶Ar ranges from 317.7 to 866.0, suggesting that crust-derived radioactive ⁴⁰Ar⁎ accounts for 7.0 to 66%, and atmospheric ⁴⁰Ar about 43 to 93% in the ore fluids. Hydrogen, oxygen, carbon, sulfur and noble gas isotopes indicate that the ore-forming fluids of the Axi gold deposit consisted predominantly of circulating meteoric water. Ore-forming metals may have derived mainly from the host volcaniclastic rocks of the Dahalajunshan Formation and basement rocks. The occurrence of adularia, platy calcite, and quartz or sulfide aggregates as pseudomorphs after bladed calcite in ore veins, and occurrence of aqueous liquid, and liquid-rich and vapor-rich two-phase inclusions, indicates that boiling of the ore-forming fluid have occurred, leading to supersaturation of the hydrothermal solution and deposition of ore metals. This is the main mineralization mechanism for quartz-vein type ores in Axi. The ore-forming fluid was buffered to a near-neutral pH in a reduced environment during mineralization. The preservation of this Paleozoic Axi deposit and its discovery required a rapid accumulation of sediments in the basin after formation of the deposit, and minimal amount of erosion after Late Cenozoic uplift.     

菲律宾拉拉布金矿床围岩蚀变与成矿作用

从"景"、"场"、"相"、"床"4个等级体制观点出发,阐述了该金属成矿省成矿内部组成,观点新颖。金矿赋存于中新世-更新世马林丹群火山岩中,该群火山岩呈零星岛状散布于斯丹岗-哥塔巴托-大姑玛线性构造活动带(SCDL)的东部,并受到后期安山玢岩的侵入。安山玢岩具有埃达克岩性质,它的侵入对于后期的围岩蚀变和成矿作用起到重要的控制作用。拉拉布矿床的安山岩具有明显的热液蚀变,属于冰长石-绢云母型金矿化,认为金是在PH值近中性的浅表环境中由于热液沸腾并伴随流体的混合沉淀而成,通常富集于标高30~200m之间。围岩蚀变强度大,并有明显的分带规律,制约着金矿的形成。金的富集与下列地质事件相关:(1)形成角砾岩之前的围岩蚀变作用;(2)热液角砾岩的形成;(3)形成角砾岩后的围岩蚀变作用;(4)金矿形成。     

甘肃省天祝县青分岭金矿床矿石特征与金的赋存状态研究

青分岭金矿的矿石类型为石英脉型和蚀变岩型.矿石结构以自形-他形粒状结构为主,矿石构造以浸染状-团粒状、星散状构造为主.金的载体矿物主要为褐铁矿、黄铁矿,也是该矿床的重要找矿标志.金矿物的赋存状态有包裹金、粒间金和裂隙空洞金三种类型,以裂隙空洞金为主,包裹金和粒间金次之.金的形态主要呈角粒状、长角粒状、浑圆粒状,金的粒度较粗,以明金为主,显微金较少.     

敦煌金滩子金矿床地质特征及找矿前景分析

敦煌金滩子金矿床系20世纪70年代初,在区调工作中检查古代采矿遗迹时发现,80年代开展过普查,经2014~2015年详查提交的一处中型金矿床。矿区由梭子山、八卦图和金滩子3个矿段组成。金矿化受断裂破碎带控制,加里东晚期石英闪长岩为八卦图和金滩子矿段石英脉型金矿的赋矿岩石,华力西中期二长花岗岩为梭子山矿段蚀变岩型金矿的赋矿岩石。目前控制主矿体长151~320 m、斜深155~350 m、矿体平均品位7.61×10~(-6)~17.94×10~(-6),矿体延伸较稳定,金品位较高。黄铁矿、褐铁矿、石英、方解石为主要载体矿物。据对金滩子金矿各矿段深部矿化特点及走向上控矿因素的分析,认为该矿床具有较好的找矿前景。     

甘肃新金厂金矿床矿石特征

新金厂金矿为中型高氧化蚀变岩型金矿床，矿体严格受断裂裂隙控制，多赋存于辉绿岩中。化学分析结果表明，矿石的有用组分单一，有害杂质少，金矿物主要为含银自然金。主要的金属矿物为黄铁矿、褐铁矿，同时也是主要的载金矿物；非金属矿物主要为石英、长石、绿泥石。矿石多具自形、半自形、他形粒状结构，以脉状、角砾状构造为主。人工重砂样品分析共获得147粒自然金，形态为蜂窝、树枝、不规则粒状等，赋存状态以裂隙金为主，其次为粒间金。包裹体金仅占10％。自然金为显微金。主要类型为石英细脉-碎裂蚀变岩型，破碎带中褐铁矿化、黄铁矿化、硅化强烈。次生氧化作用较强。     

陕西旬阳淋湘金矿地质特征和成矿流体属性

淋湘金矿床产于南秦岭古生界泥盆系地层中 ,容矿围岩主要为碳酸盐岩和粉砂质千枚岩、千枚岩 ,金矿体主要受近东西向断裂控制。第二、三矿化阶段为金的主要矿化阶段 ,主要载金矿物为黄铁矿、磁黄铁矿、黄铜矿、石英、褐铁矿 ,矿床的同位素和成矿流体特征表明 :金属矿和硫来源于造山带围岩地层 ,属容矿岩石类的沉积岩中浅层渗滤同生热盐水型金矿床 ,成矿时代为燕山期