青海东昆仑阿斯哈金矿床成矿物质来源:C-H-O-S-Pb同位素约束

都兰县阿斯哈金矿床位于青海东昆仑造山带东段,为近年来发现的大型金矿床。金矿体受NNE向和NNW-NW向断裂构造控制,赋存于闪长岩和花岗闪长岩体中。围岩蚀变强烈,主要有硅化、绢云母化、黄铁矿化、绿泥石化、碳酸岩化(方解石化)、绢云岩化、黄铜矿化和高岭土化。本文通过脉石矿物C-H-O同位素和矿石矿物S-Pb同位素地球化学研究,探讨该矿床成矿流体和成矿物质来源。方解石δ^(13)C值为−2.72‰~−2.46‰,δ^(18)O值为10.36‰~11.61‰,表明成矿流体主要来源于岩浆。石英δD值为−84.3‰~−59.6‰,δ^(18)O_(H_(2)O)值为5.7‰~12.0‰,进一步表明成矿流体属于岩浆流体。硫化物δ^(34)S值变化范围较窄,为3.2‰~7.7‰,平均值为6.1‰,与变质流体和沉积岩中的S同位素组成不同,而与中酸性岩浆S同位素组成相似,暗示S来源于中酸性岩浆。硫化物Pb同位素值变化较小(^(206)Pb/^(204)Pb=18.199~18.235,^(207)Pb/^(204)Pb=15.542~15.605,^(208)Pb/^(204)Pb=38.163~38.321),且落入造山带Pb演化线附近,指示造山作用对阿斯哈金矿床的形成可能有一定影响。结合已报道的成果,认为阿斯哈金矿床的成矿流体属于岩浆热液,成矿物质主要由中酸性岩浆提供,属于造山过程中形成的、与岩浆(很可能是已发现的斑岩)作用有关的热液脉型金矿床,为中–晚三叠世东昆仑造山伸展构造背景下岩浆–流体–构造耦合成矿的产物。

云南荒田大型铅锌矿床的成因:流体包裹体和C-H-O-S-Pb同位素地球化学约束

荒田铅锌矿位于扬子板块西南缘,与华夏地块和三江地块相接,属峨眉山大火成岩省的南延部分,川-滇-黔铅锌银多金属成矿域的南部。矿体赋存于上二叠统峨眉山玄武岩底部与下二叠统茅口组接触面上及其附近的玄武质-灰质角砾岩层中。本文应用流体包裹体和C-H-O-S-Pb同位素地球化学研究手段,来探讨荒田铅锌矿的成因。流体包裹体分析表明,成矿流体性质具有阶段性演化特征,早期硫化物阶段(阶段Ⅰ)出现含子矿物包裹体、CO_2包裹体和H_2O包裹体的组合发育特征,均一温度介于245～320℃,平均为270℃;到中期硫化物阶段(阶段Ⅱ)和晚期硫化物阶段(阶段Ⅲ)则逐渐变为以H_2O包裹体为主要类型,均一温度分别介于180～250℃和100～210℃,平均为224℃和174℃。随着成矿作用的进行,成矿流体的均一温度和盐度均表现出从早阶段到晚阶段逐渐降低的趋势。显微激光拉曼光谱分析显示流体包裹体的液相成分主要为H_2O,气相成分为H_2O、CO_2、CH_4以及N_2。碳、氧同位素组成(δ^(13)C_(PDB)值介于-8.54‰～3.76‰,δ^(18)O_(SMOW)值介于8.57‰～24.22‰)在δ^(18)O-δ^(13)C图上分布于原生碳酸岩和海相碳酸盐岩之间,指示CO_2可能来自地幔、海相沉积碳酸盐岩溶解和沉积物中有机质的脱羟基作用。氢氧同位素组成(δD值介于-97.4‰～-71.4‰,δ^(18)O_水值介于-4.6‰～8.0‰)在δD-δ^(18)O图上落在岩浆水和大气降水的过渡带上,推测热液流体运移过程中与顺层下渗的大气降水流体混合,期间可能有海水的加入。矿石硫化物的δ^(34)S值介于-5.5‰～10.3‰,指示矿化剂硫具有多种来源,除了直接来自玄武岩外,还来自古海水硫酸盐和碳酸盐岩地层,硫酸盐通过热化学还原(TSR)过程发生还原作用。矿石硫化物铅的^(208)Pb/^(204)Pb、^(207)Pb/^(204)Pb和^(206)Pb/^(204)Pb比值分别为38.320～39.365、15.603～15.860和18.136～18.786,数据分布呈线性趋势,几乎所有点均落在地壳铅平均演化线以上,且位于峨眉山组玄武岩、碳酸盐岩地层和基底岩石的Pb同位素组成范围之内,说明成矿物质具有多源性,铅同位素在成矿之前存在均一化过程。结合成矿物质和成矿流体来源,以及区域成矿地球动力学背景,认为荒田铅锌矿属于密西西比河谷型(MVT)叠加岩浆热液改造型矿床。

Genesis of the Weiquan Ag-Polymetallic Deposit in East Tianshan, China： Evidence from Zircon U-Pb Geochronology and C-H-O-S-Pb Isotope Systematics

The Weiquan Ag-polymetallic deposit is located on the southern margin of the Central Asian Orogenic Belt and in the western segment of the Aqishan-Yamansu arc belt in East Tianshan,northwestern China. Its orebodies, controlled by faults, occur in the lower Carboniferous volcanosedimentary rocks of the Yamansu Formation as irregular veins and lenses. Four stages of mineralization have been recognized on the basis of mineral assemblages, ore fabrics, and crosscutting relationships among the ore veins. Stage I is the skarn stage(garnet + pyroxene), Stage Ⅱ is the retrograde alteration stage(epidote + chlorite + magnetite ± hematite 士 actinolite ± quartz),Stage Ⅲ is the sulfide stage(Ag and Bi minerals + pyrite + chalcopyrite + galena + sphalerite + quartz ± calcite ± tetrahedrite),and Stage IV is the carbonate stage(quartz + calcite ± pyrite). Skarnization,silicification, carbonatization,epidotization,chloritization, sericitization, and actinolitization are the principal types of hydrothermal alteration. LAICP-MS U-Pb dating yielded ages of 326.5±4.5 and 298.5±1.5 Ma for zircons from the tuff and diorite porphyry, respectively. Given that the tuff is wall rock and that the orebodies are cut by a late diorite porphyry dike, the ages of the tuff and the diorite porphyry provide lower and upper time limits on the age of ore formation. The δ13C values of the calcite samples range from-2.5‰ to 2.3‰, the δ18OH2 Oand δDVSMOWvalues of the sulfide stage(Stage Ⅲ) vary from 1.1‰ to 5.2‰ and-111.7‰ to-66.1‰, respectively,and the δ13C, δ18OH2 Oand δDV-SMOWvalues of calcite in one Stage IV sample are 1.5‰,-0.3‰, and-115.6‰, respectively. Carbon, hydrogen, and oxygen isotopic compositions indicate that the ore-forming fluids evolved gradually from magmatic to meteoric sources. The δ34SV-CDTvalues of the sulfides have a large range from-6.9‰ to 1.4‰, with an average of-2.2‰, indicating a magmatic source, possibly with sedimentary contributions. The206Pb/204Pb,207Pb/204Pb, and208Pb/204Pb ratios of the sulfides are 17.9848-18.2785,15.5188-15.6536, and 37.8125-38.4650, respectively, and one whole-rock sample at Weiquan yields206Pb/204Pb,207Pb/204Pb, and208Pb/204Pb ratios of 18.2060, 15.5674, and 38.0511,respectively. Lead isotopic systems suggest that the ore-forming materials of the Weiquan deposit were derived from a mixed source involving mantle and crustal components. Based on geological features, zircon U-Pb dating, and C-H-OS-Pb isotopic data, it can be concluded that the Weiquan polymetallic deposit is a skarn type that formed in a tectonic setting spanning a period from subduction to post-collision. The ore materials were sourced from magmatic ore-forming fluids that mixed with components derived from host rocks during their ascent, and a gradual mixing with meteoric water took place in the later stages.

Fluid inclusions,C-H-O-S-Pb isotope systematics,geochronology and geochemistry of the Budunhua Cu deposit,northeast China:Implications for ore genesis

The Budunhua Cu deposit is located in the Tuquan ore-concentrated area of the southern Great Xing’an Range,NE China.This deposit includes the southern Jinjiling and northern Kongqueshan ore blocks,separated by the Budunhua granitic pluton.Cu mineralization occurs mainly as stockworks or veins in the outer contact zone between tonalite porphyry and Permian metasandstone.The ore-forming process can be divided into four stages involving stage Ⅰ quartz-pyrite-arsenopyrite;stage Ⅱ quartz-pyrite-chalcopyrite-pyrrhotite;stage Ⅲ quartz--polynetallic sulfides;and stage IV quartz-calcite.Three types of fluid inclusions(FIs) can be distinguished in the Budunhua deposit:liquid-rich two-phase aqueous FIs(L-type),vapour-rich aqueous FIs(V-type),and daughter mineral-bearing multi-phase FIs(S-type).Quartz of stages Ⅰ-Ⅲ contains all types of FIs,whereas only L-type FIs are evident in stage Ⅳ veins.The coexisting V-and S-type FIs of stages Ⅰ-Ⅲ have similar homogenization temperatures but contrasting salinities,which indicates that fluid boiling occurred.The FIs of stages Ⅰ,Ⅱ,Ⅲ,and Ⅳyield homogenization temperatures of 265-396℃,245-350℃,200-300℃,and 90-228℃ with salinities of3.4-44.3 wt.%,2.9-40.2 wt.%,1.4-38.2 wt.%,and 0.9-9.2 wt.% NaCl eqv.,respectively.Ore-forming fluids of the Budunhua deposit are characterized by high temperatures,moderate salinities,and relatively oxidizing conditions typical of an H2 O-NaCl fluid system.Mineralization in the Budunhua deposit occurred at a depth of0.3-1.5 km,with fluid boiling and mixing likely being responsible for ore precipitation.C-H-O-S-Pb isotope studies indicate a predominantly magmatic origin for the ore-forming fluids and materials.LA-ICP-MS zircon U-Pb analyses indicate that ore-forming tonalite porphyry and post-ore dioritic porphyrite were formed at 151.1±1.1 Ma and 129.9±1.9 Ma,respectively.Geochemical data imply that the primary magma of the tonalite porphyry formed through partial melting of Neoproterozoic lower crust.On the basis of available evidence,we suggest that the Budunhua deposit is a porphyry ore system that is spatially,temporally,and genetically associated with tonalite porphyry and formed in a post-collision extensional setting following closure of the Mongol-Okhotsk Ocean.

南秦岭柞水-山阳矿集区金盆梁金矿床成因——来自流体包裹体及C-H-O-S-Pb同位素的制约

金盆梁是南秦岭柞水-山阳矿集区勘查的一处微细浸染型金矿床,矿床成因与成矿机制尚不清楚。矿体产于上泥盆统桐峪寺组粉砂质板岩和钙质板岩中,以浸染状、脉状金锑矿化为主,成矿过程可划分为3个阶段:毒砂-黄铁矿-硅化阶段(Ⅰ)、石英-辉锑矿-白铁矿±锑氧化物阶段(Ⅱ)和方解石-石英阶段(Ⅲ)。流体包裹体及C-H-O-S-Pb同位素研究结果显示,Ⅱ阶段主要为金锑矿化,以H_(2)O-NaCl两相包裹体占绝对优势,成矿流体属于中温(200~290℃)、低盐度(w(NaCl_(eq))为0~6.0%)、低密度(0.64~0.99 g/cm^(3))的H_(2)O-NaCl±CO_(2)体系,以循环大气降水为主。无矿化的Ⅲ阶段主要发育H_(2)O-NaCl两相包裹体,含少量CO_(2)-H_(2)O-NaCl±CH_(4)、纯CO_(2)±CH_(4)及含子晶多相包裹体,流体以中低温(140~280℃)、低盐度(w(NaCl_(eq))为2.0%~8.0%)、低密度(0.68~1.02 g/cm^(3))的富CO_(2)-H_(2)O-NaCl±CH_(4)体系为主,或存在少量高温、高盐度、高密度H_(2)O-NaCl体系的岩浆热液混入。硫化物δ^(34)S值为较大负值(−12.50‰~−10.20‰),Pb同位素组成具上地壳源铅特征,成矿物质主要来源于围岩地层。综合研究表明,金盆梁金矿的成因类型属于卡林型金矿,水-岩反应(围岩硫化作用)是金富集沉淀的主要机制。

内蒙古根河三道桥铅锌银矿床C-H-O-S同位素和U-Pb定年研究及其意义

内蒙古根河三道桥大型铅锌银矿床位于大兴安岭得尔布干成矿带中北段,矿体主要呈脉状赋存于火山岩地层中。氢氧同位素研究表明,成矿期石英和绢云母的δD值变化范围为-149.1‰~-156.7‰,δ^(18)OH_(2)O值变化范围为-13.6‰~3.4‰;成矿后期石英δD值变化范围为-131.9‰~-147.7‰,δ^(18)OH_(2)O值变化范围为-16.5‰~-18.2‰。碳同位素分析结果表明,与矿化有关的方解石δ^(13)C值变化范围为-1.8‰~-3.1‰,δ^(18)O值变化范围为5.3‰~8.6‰。原位S同位素分析结果表明,硫化物的δ^(34)S值变化范围为2.3‰~5.6‰,与其西南侧下护林矽卡岩型铅锌银矿床中的硫化物的δ^(34)S值(1.2‰~5.9‰)基本一致。上述同位素组成特征指示成矿物质主要来源于岩浆热液,在上升到地壳浅部时有一定量的大气降水混入。锆石U-Pb年代学研究表明,矿化的闪长玢岩脉年龄为(136.0±0.7)Ma(MSWD=0.44);未矿化、穿切硫化物微细脉的闪长玢岩脉的锆石U-Pb年龄为(120.8±0.6)Ma(MSWD=0.49)。结合前人相关研究进展,认为三道桥铅锌银矿床形成于136.0~120.8 Ma期间(早白垩世),为伸展构造背景下与浅成侵入岩有关的中温热液型铅锌银矿床。

内蒙古扎拉格阿木铜矿成矿流体与成矿机制

扎拉格阿木铜矿床位于锡林浩特地块北缘,矿体赋存于二叠系砂质板岩和角砾岩中,受NE向断裂控制,为中温热液脉型铜矿床。本文通过流体包裹体和C-H-O-S-Pb同位素地球化学研究手段,来探讨扎拉格阿木铜矿成矿机制。成矿热液期存在5个成矿阶段:钾长石阶段、石英-绢云母阶段、石英-黄铁矿阶段、石英-多金属硫化物阶段、石英-方解石阶段。其中石英-多金属硫化物阶段为主成矿阶段,本阶段主要发育富液相、富气相、含子矿物包裹体。富液相包裹体均一温度与盐度分别为:138~289℃和2.06%~16.11%NaCleq;含子矿物包裹体均一温度与盐度分别为:320~374℃和32.68%~39.81%NaCleq,包裹体气体成分除少量CO_(2)以外,均为H2O。H-O同位素分析得出,石英中的δO18值为-8.5‰~6.5‰,流体的δD值为-116‰~-98‰,暗示早阶段成矿流体主要为岩浆热液,晚阶段伴有大气降水混入。C-O同位素分析表明,δ^(13)C值为-10.1‰~-6.9‰,δ^(18)OSMOW介于2.5‰~11.7‰,在δ^(18)O-δ^(13)C图上数据点落在岩浆水与大气水的中间区域。矿石硫化物δ34S值介于-4.5‰~1.5‰,指示具有幔源岩浆硫的特征。矿石硫化物Pb同位素^(208)Pb/^(204)Pb、^(207)Pb/^(204)Pb和^(206)Pb/^(204)Pb比值分别为38.034~38.609、15.497~15.655和18.141~18.446,推测Pb具有地幔来源的特点并伴有地壳或造山带Pb混入。成矿过程中伴随着流体沸腾作用,成矿物质沉淀受早期形成的岩浆热液与后加入大气降水混合的影响。

安徽铜陵凤凰山铜矿床成矿流体特征研究

本文以凤凰山矽卡岩型铜矿床为例,通过对成矿流体特征研究以及碳、氢、氧、硫、铅同位素分析,探讨成矿流体性质、成矿流体来源以及成矿物质来源。凤凰山铜矿床透辉石、石榴子石、石英和方解石中普遍发育流体包裹体,其类型为液体包裹体、气体包裹体和H2O—CO2三相包裹体。气液固相成分的激光拉曼探针分析,流体包裹体液相以H2O为主,气相以为CO2、H2O、N2、CH4为主。流体包裹体的均一温度和盐度显示成矿流体演化经历了的3个不同阶段,反应了成矿流体从高温度、高盐度向低温度、低盐度的持续演化过程,与成矿作用阶段基本对应,降温、流体沸腾是导致流体中巨量铜元素卸载的主要因素。石英和方解石中的氢、氧同位素组成表明成矿流体以岩浆热液为主,成矿晚期混有少量大气降水。黄铁矿中的硫同位素(1.8‰～2.9‰)具有幔源硫的特征。方铅矿中的铅同位素具有岩浆热液特征,表明凤凰山铜矿床中成矿元素来自上地幔。

滇黔交界地区玄武岩铜矿同位素地球化学特征

对滇黔交界地区玄武岩铜矿进行了同位素地球化学示踪。铜矿石中沥青δ1 3 CPDB为 - 33.1‰～- 30 .9‰ ,炭质δ1 3 CPDB为 - 2 3.2‰～ - 2 0 .2‰ ;方解石的δ1 3 CPDB一般为 - 1 3.5‰～ - 1 9.4‰ ,δ1 8OSMOW 一般为1 9.0‰～ 2 3.5‰ ;石英流体包裹体水δD为 - 6 9‰～ - 89‰ ,δ1 8O石英_SMOW 为 1 5 .7‰～ 1 7.4‰ ,与其平衡的流体的δ1 8O水_SMOW为 2 .2‰～ 3.9‰ ;各种矿物的铅同位素组成一般为2 0 6Pb/ 2 0 4Pb 1 7.85 5～ 1 8.92 3,2 0 7Pb/ 2 0 4Pb 1 5 .5 0 3～1 5 .6 94 ,2 0 8Pb/ 2 0 4Pb 38.2 93～ 39.0 36 ;辉铜矿δ3 4 SCDT为 1 9.2‰和 2 0 .7‰。这些特征综合显示峨眉山玄武岩铜矿的成矿作用与盆地流体的对流循环及从玄武岩中萃取成矿物质有关 。

河南栾川百炉沟铅锌矿床地质、流体包裹体和稳定同位素地球化学

百炉沟矿床是近年来在盛产斑岩-矽卡岩型钼矿床的河南栾川地区新发现的一处铅锌矿床,位于豫西南牛心剁穹状背斜之西侧,与栾川地区的南泥湖、三道庄、上房沟、马圈等斑岩型及斑岩-矽卡岩型钼矿床相毗邻。矿体呈脉状、板状产在中元古界变质碳酸盐岩-碎屑岩层中,受NWW向层间断裂构造控制。矿石由闪锌矿、方铅矿、黄铁矿、石英、方解石等矿物组成。矿石中石英和闪锌矿所捕获的原生流体包裹体有富液体气液两相包裹体、富气体气液两相包裹体、纯气体包裹体、含子矿物三相包裹体等4种类型,邻近分布,其均一温度相近,表明成矿过程中可能存在流体沸腾作用。气液两相包裹体的均一温度为180～327℃,以中温(250～260℃)为主;盐度w(Na-Cleq)为4.0%～14.0%,以5.0%～9.0%为主;依据均一温度峰值所对应的压力(38.94～44.87MPa),求得成矿深度为1.44～1.66km。表明该矿床明显具有浅成、中温、低盐度热液成矿的特征。单个流体包裹体的气相成分至少有纯H2O蒸汽、N2+CO2+CH4、N2+CO2和N2+CH4等4种组合。矿石中石英和方解石内包裹体水的δDV-SMOW为-76‰～-90‰,方解石的δ13CV-PDB为-0.44‰～1.80‰,选取所对应的流体包裹体均一温度,计算得到包裹体水的δ18O水为2.51‰～10.96‰,反映出成矿流体的主体为岩浆热液。矿石中硫化物的δ34SV-CDT为-1.2‰～10.9‰,其峰值(1‰～2‰)与该地区斑岩型钼矿床中的硫化物相近,指示其具有岩浆来源硫的特征。矿石中硫化物206Pb/204Pb=17.552～18.426,207Pb/204Pb=15.451～15.5794,208Pb/204Pb=38.264～39.637,反映出成矿金属主要来自于岩浆,有少量地层岩石铅的加入。百炉沟铅锌矿床应属受层间构造控制的中温岩浆热液充填-交代矿床。

新疆库尔尕生铅锌矿床地质、流体包裹体和同位素地球化学

新疆西天山赛里木地块中部的库尔尕生铅锌矿床受NW向断裂构造的控制;矿体呈脉状、透镜状;矿石呈网脉状、块状、浸染状、角砾状和斑杂状构造;矿石的矿物组成简单,金属矿物主要有方铅矿、闪锌矿、黄铁矿,脉石矿物主要为石英和方解石。脉石石英中发育纯液体包裹体和气液两相包裹体,均一温度为135.4~158.8℃。脉石石英和方解石的H、O、C同位素研究显示,成矿流体的δD值主要为-96.8‰^-84.3‰,δ18O值为-10.92‰^-6.11‰,反映出成矿流体来自岩浆水与大气水的混合水;方铅矿的δ34S值为4.1‰~8.4‰,与区域上晚石炭世的斑岩体来源硫范围(如达巴特流纹斑岩体硫化物的δ34S值为4.9‰~7.9‰,平均6.3‰)相似,揭示其硫可能为斑岩来源;方铅矿的铅同位素组成为206Pb/204Pb=18.207~18.291,207Pb/204Pb=15.595~15.654,208Pb/204Pb=38.085~38.291,在Δβ-Δγ成因分类图解上投影于"化学沉积型铅"与"海底热水作用铅"界线附近,可能反映出有相当一部分成矿金属物质来源于围岩。综合分析认为,库尔尕生铅锌矿床可能是与斑岩有关的远源低温热液型矿床。

延边小西南岔富金斑岩铜矿床的含矿流体起源与演化——H,O,C,S,Pb同位素示踪

延边地区小西南岔富金斑岩铜矿床的H、O、C、S和Pb同位素特征如下:δ18OQ-H2O为-0.1‰^+5.6‰、δD为-77‰^-38‰,δ18OCc-H2O为-4.3‰、δD为-62‰;石英流体包裹体的δ13CCO2为-5.6‰^-3.5‰,1δ8OCc-H2O为-4.3‰^+11.39‰、1δ3CPDB为-8.8‰^-5.3‰,3δ4S集中在+2.1‰^+4.8‰之间,206Pb/204Pb=18.103~18.3882、07Pb/204Pb=15.405~15.5902、08Pb/204Pb=37.888~38.184,μ值为8.52~8.79。其中:S同位素特征指示含矿流体与次大陆岛弧岩浆相似,而C、O、Pb同位素则指示初始地幔源。结合H、O同位素的地幔初生水+岩浆水+变质水和演化过程向雨水热液和海水方向进行的特征初步认为,初始含矿流体的热动力源是原始地幔,成矿物质来源于I MORB性质地幔,含矿流体演化的浅部过程受到一定程度的雨水热液的混染作用。

青藏高原碰撞造山背景造山型金矿床:构造背景、地质及地球化学特征

青藏高原碰撞造山背景下形成了雅鲁藏布江缝合带及哀牢山造山带两条造山型金矿带。雅鲁藏布江缝合带包含马攸木、念扎、邦布及折木朗金矿等;该矿带形成于拉萨地块及特提斯喜马拉雅地层序列地壳初始缩短加厚的背景(59~44Ma),与林子宗火山岩和高压变质岩同期形成。控矿构造主要以EW向展布。金以自然金形式赋存在石英硫化物脉及石英脉两侧以绿片岩相变质为主的千枚岩及板岩中。哀牢山造山带包含镇沅、金厂、大坪及长安金矿等,主要形成于35~26Ma,成矿背景为区域发生大规模走滑剪切,矿区内分布有成矿前期的煌斑岩及富碱斑岩。控矿构造主要以NW-SE向展布,围岩变质级低于雅鲁藏布江缝合带。C-S-H-O-Pb同位素变化较大,整体雅鲁藏布江缝合带及哀牢山造山带造山型金矿成矿流体主要来源于深部地幔流体、围岩地层的变质流体及岩浆流体,成矿围岩的差异性也会导致同位素的变化性。

Geology and Isotope Geochemistry of the Yinchanggou-Qiluogou Pb-Zn Deposit,Sichuan Province,Southwest China

The Yinchanggou-Qiluogou Pb-Zn deposit,located in the western Yangtze Block,southwest China,is hosted by the Upper Sinian Dengying Formation dolostone.Ore bodies occur in the Qiluogou anticline and the NS-and NNW-trending faults.Sulfide ores mainly consist of sphalerite,pyrite,galena and calcite,with subordinate dolomite and quartz.Seventeen ore bodies have been discovered to date and they have a combined 1.0 million tons of sulfide ores with average grades of 2.27wt%Zn and 6.89wt%Pb.The δD（H2O-SMOW） and δ18O（H2O-SMOW） values of fluid inclusions in quartz and calcite samples range from-68.9‰ to-48.7‰ and 7.3‰ to 15.9‰,respectively,suggesting that H2O in the hydrothermal fluids sourced from metamorphic water.Calcite samples have δ13C（PDB） values ranging from-6.2‰ to-4.1‰ and δ18O（SMOW） values ranging from 15.1‰ to 17.4‰,indicating C and O in the hydrothermal fluids likely derived from a mixed source of metamorphic fluids and the host carbonates.The δ34S（CDT） values of sulfide minerals range from 5.5‰ to 20.3‰,suggesting that thermal chemical reduction of sulfate minerals in evaporates were the most probable source of S in the hydrothermal fluids.The 206Pb/204Pb,207Pb/204Pb and 208Pb/204Pb ratios of sulfide minerals fall in the range of 18.11 to 18.40,15.66 to 15.76 and 38.25 to 38.88,respectively.The Pb isotopic data of the studied deposit plot near the upper crust Pb evolution curve and overlap with the age-corrected Proterozoic basement rocks and the Upper Sinian Dengying Formation hosting dolostone.This indicates that the Pb originated from a mixed source of the basement metamorphic rocks and the ore-hosting carbonate rocks.The ore geology and C-H-O-S-Pb isotopic data suggest that the YinchanggouQiluogou deposit is an unusual carbonate-hosted,strata-bound and epigenetic deposit that derived ore-forming materials from a mixed source of the underlying Porterozoic basements and the Sinian hosting carbonates.

稀有气体同位素地球化学研究的某些进展

稀有气体的化学惰性使其在示踪成矿流体方面具有明显的优越性,其与碳、氢、氧、硫、锶、钕、铅同位素方法,以及卤素方法等结合使用,不但可以避免单一方法的片面性,还可以相互补充,相互印证,更好地示踪成矿流体的来源与演化,进而探讨矿床的成矿机制。本文归纳了近年来稀有气体同位素与其他同位素体系联合应用的研究进展,及其存在的问题和发展趋势。

安徽金寨银水寺铅锌矿床流体包裹体和同位素地球化学特征

银水寺铅锌矿床位于大别造山带北缘,是该区最大的矽卡岩型矿床。矿体主要发育在中元古界庐镇关岩群仙人冲组大理岩与郑堂子组千枚岩之间的层间破碎带以及正长花岗斑岩与大理岩的接触带中。矿床先后经历了四个成矿阶段,矽卡岩阶段(Ⅰ)、石英.白钨矿阶段(Ⅱ)、石英.硫化物阶段(Ⅲ)、碳酸盐阶段(Ⅳ)。矽卡岩阶段(Ⅰ)主要发育绿帘石、阳起石、石英、绿泥石、磁铁矿及少量金属硫化物等;石英.白钨矿阶段(Ⅱ)主要发育石英、方解石、萤石及少量白钨矿和金属硫化物;石英.硫化物阶段(Ⅲ)广泛发育闪锌矿、方铅矿、黄铜矿等金属硫化物及石英、方解石、萤石、绿泥石等;碳酸盐阶段(Ⅳ)主要发育方解石、石英及少量黄铁矿。矿床中发育三种类型流体包裹体,包括富CO2水溶液包裹体(AC类)、气液两相水溶液包裹体(L类)和含子晶多相包裹体(S型)。根据流体包裹体岩相学、显微测温、激光拉曼研究结果,矽卡岩阶段主要有富CO2包裹体和气液两相水溶液包裹体,均一温度为314~400℃、盐度变化范围较大(1.1%~19.3%NaCleqv);石英.白钨矿阶段发育气液两相水溶液包裹体、含子晶多相包裹体和富CO2包裹体,后两者均一温度相近(263~349℃)、盐度差异较大(32.8%~41%NaCleqv和0.8%~6.1%NaCleqv),表明流体发生了沸腾作用;石英.硫化物阶段主要发育气液两相水溶液包裹体,均一温度为230~332℃,盐度为0.2%~8.9%NaCleqv;碳酸盐阶段只发育气液两相水溶液包裹体,显示低温(162~245℃)、低盐度(0.2%~5.6%NaCleqv)的特征。矿床不同成矿阶段石英、绿帘石中流体包裹体中水H-O同位素研究结果表明,δ18Ofluid值从早到晚逐渐减小,其中矽卡岩阶段为–1.3‰~4.7‰、石英.硫化物阶段为–5.1‰~–3.1‰,表明银水寺矿床早期成矿流体主要为岩浆来源,并在成矿过程中不断有大气降水的加入。石英流体包裹体中CO2的C同位素测试结果表明,矽卡岩阶段δ13CV-PDB值为–9.2‰,石英.硫化物阶段为–25.8‰~–15.4‰,表明早期成矿流体中碳质主要来自岩浆,石英-硫化物阶段有大量有机碳加入,其可能与流体和富含有机质的地层反应有关。矿石中主要金属硫化物的δ34S值(1.7‰~4.4‰)显示了深源硫的特征。Pb同位素变化范围集中(206Pb/204Pb=16.55~16.705,207Pb/204Pb=15.369~15.459,208Pb/204Pb=37.463~37.767),显示壳幔混源的特点。随着成矿作用的进行,岩浆流体与碳酸盐围岩地层发生水岩交代反应形成矽卡岩,该过程造成了成矿矽卡岩阶段磁铁矿和少量闪锌矿的沉淀;断裂活动造成热液体系压力下降,流体发生沸腾,CO2、HF进入气相并逃逸促使矿床中钨的沉淀;同时大气降水沿裂隙灌入,混合作用导致流体的温度、盐度降低,Cl–浓度下降,造成矿床中铅锌的大面积沉淀。

北祁连干沙鄂博稀土元素矿床地质和矿床地球化学特征

干沙鄂博稀土元素矿床位于北祁连造山带中段,是该地区唯一大型稀土元素矿床。矿体产于早泥盆世碱性岩体及其接触带中,围岩蚀变表现为霓长岩化、碳酸岩化和萤石化,矿石类型主要为霓辉正长岩型和霓辉正长斑岩型,矿物组合为氟碳钙铈矿+黄铜矿+霓辉石+钠长石+钠闪石+萤石+方解石。通过详细的岩相学和矿相学观察,划分出4个成矿期,包括岩浆成矿期(Ⅰ)、早期热液成矿期(Ⅱ)、晚期热液成矿期(Ⅲ)和表生成矿期(Ⅳ)。其中,早期热液成矿期为主成矿期,包括3个成矿阶段:霓石-钠长石-氟碳钙铈矿阶段(Ⅱ_1)、钠闪石-氟碳钙铈矿阶段(Ⅱ_2)、霓石-方解石-氟碳钙铈矿阶段(Ⅱ_3)。脉石矿物石英的δ^(18)O值为7.3‰～11.3‰,δD值为-89.4‰～-68.8‰,δ^(13)C_(V-PDB)值为-10.5‰～-7.9‰,表明成矿流体以岩浆热液为主,有大气降水的参与。矿石中硫化物δ^(34)S_(V-CDT)值介于-7.1‰～-1.3‰之间,平均-4.4‰,总硫同位素δ^(34)S_(ΣS)为-3.9‰;矿石硫化物铅同位素组成基本一致,^(206)Pb/^(204)Pb、^(207)Pb/^(204)Pb和^(208)Pb/^(204)Pb比值分别为18.417～18.524、15.637～15.769和38.425～38.863,与矿区早泥盆世含矿碱性岩体岩石铅同位素组成十分相似,推测成矿物质主要来源于该碱性岩体。

新疆东准噶尔顿巴斯套金矿床成因:H-O-C-S-Pb同位素制约

顿巴斯套金矿床位于新疆东准噶尔阿尔曼泰构造带东段北东侧,是目前该带上发现的典型金矿床。矿床中主要矿体赋存于下石炭统姜巴斯套组下段浅变质含碳细碎屑岩中,受NWW向的陡倾断裂构造控制。与金矿化密切相关的蚀变类型为毒砂-黄铁矿化、硅化和绢云母化。根据矿物共生组合及相互穿切关系,可将成矿期划分为四个成矿阶段:石英脉阶段、粗粒黄铁矿-石英脉阶段、细粒黄铁矿(毒砂)-石英脉阶段和石英-碳酸盐阶段,其中第三阶段为主成矿阶段,形成于张性环境。H-O同位素数据显示,主成矿阶段流体δ^(18)O和δD组成分别为1.1‰～3.9‰和-115.5‰～-120.6‰,指示成矿流体以岩浆热液为主,后期有部分大气水的参与; C同位素研究显示,成矿流体中δ13C的范围为-24.7‰～-25.4‰,是深源无机碳与地层有机碳不同程度的混合碳,深源流体对金的成矿具有重大影响,同时地层有机质也参与了金的运移和卸载;矿石中黄铁矿和毒砂的δ^(34)S分别为3.0‰～5.8‰和4.2‰～5.6‰,数值比较集中,指示成矿物质硫源具有岩浆硫特征,有深源硫参与;矿石中黄铁矿的Pb同位素组成基本一致, ^(206)Pb/^(204)Pb、^(207)Pb/^(204)Pb、^(208)Pb/^(204)Pb分别为17.875～18.102、15.483～15.625和37.699～38.148,指示成矿物质铅源以地幔铅为主,并同化了壳源铅,应是一种分别来自地幔和上地壳的混合铅。综合矿床地质特征及多元同位素分析,认为顿巴斯套金矿床为岩浆热液成因的构造破碎蚀变岩型金矿床,为早二叠世伸展构造背景下的构造-岩浆-流体活动综合作用的产物。

Evolution of the magmatic–hydrothermal system and formation of the giant Zhuxi W–Cu deposit in South China

The Zhuxi deposit is a recently discovered W–Cu deposit located in the Jiangnan porphyry–skarn W belt in South China. The deposit has a resource of 3.44 million tonnes of WO3, making it the largest on Earth,however its origin and the evolution of its magmatic–hydrothermal system remain unclear, largely because alteration–mineralization types in this giant deposit have been less well-studied, apart from a study of the calcic skarn orebodies. The different types of mineralization can be classified into magnesian skarn, calcic skarn, and scheelite–quartz–muscovite(SQM) vein types. Field investigations and mineralogical analyses show that the magnesian skarn hosted by dolomitic limestone is characterized by garnet of the grossular–pyralspite(pyrope, almandine, and spessartine) series, diopside, serpentine,and Mg-rich chlorite. The calcic skarn hosted by limestone is characterized by garnet of the grossular–andradite series, hedenbergite, wollastonite, epidote, and Fe-rich chlorite. The SQM veins host highgrade W–Cu mineralization and have overprinted the magnesian and calcic skarn orebodies. Scheelite is intergrown with hydrous silicates in the retrograde skarn, or occurs with quartz, chalcopyrite, sulfide minerals, fluorite, and muscovite in the SQM veins.Fluid inclusion investigations of the gangue and ore minerals revealed the evolution of the ore-forming fluids, which involved:(1) melt and coexisting high–moderate-salinity, high-temperature, high-pressure(>450 ℃and >1.68 kbar), methane-bearing aqueous fluids that were trapped in prograde skarn minerals;(2) moderate–low-salinity, moderate-temperature, moderate-pressure(~210–300 ℃and ~0.64 kbar),methane-rich aqueous fluids that formed the retrograde skarn-type W orebodies;(3) low-salinity,moderate–low-temperature, moderate-pressure(~150–240 ℃and ~0.56 kbar), methane-rich aqueous fluids that formed the quartz–sulfide Cu(–W) orebodies in skarn;(4) moderate–low-salinity,moderate-temperature, low-pressure(~150–250 ℃and ~0.34 kbar) alkanes-dominated aqueous fluids in the SQM vein stage, which led to the formation of high-grade W–Cu orebodies. The S–Pb isotopic compositions of the sulfides suggest that the ore-forming materials were mainly derived from magma generated by crustal anatexis, with minor addition of a mantle component. The H–O isotopic compositions of quartz and scheelite indicate that the ore-forming fluids originated mainly from magmatic water with later addition of meteoric water. The C–O isotopic compositions of calcite indicate that the ore-forming fluid was originally derived from granitic magma, and then mixed with reduced fluid exsolved from local carbonate strata. Depressurization and resultant fluid boiling were key to precipitation of W in the retrograde skarn stage. Mixing of residual fluid with meteoric water led to a decrease in fluid salinity and Cu(–W) mineralization in the quartz–sulfide stage in skarn. The high-grade W–Cu mineralization in the SQM veins formed by multiple mechanisms, including fracturing, and fluid immiscibility, boiling, and mixing.

陕西陈家坝铜铅锌多金属矿床C、H、O、S、Sr同位素地球化学示踪

陈家坝铜铅锌多金属矿床为近年来在陕西勉(县)-略(阳)-宁(强)铜金镍矿化集中区新发现的铜铅锌多金属矿床。为了查明陈家坝矿床成矿物质来源,笔者开展了系统的C、H、O、S和Sr同位素地球化学研究。结果表明,陈家坝矿区的围岩的δ^(13)CPDB值范围-0.93‰～1.44‰,平均值为0.35‰,δ^(18)OV-SMOW值范围14.14‰～27.49‰,平均22.1‰,为沉积成因海相碳酸盐岩。脉石矿物白云石的δ^(13)CPDB范围在-0.53‰～-0.89‰,δ^(18)OV-SMOW值范围12.12‰～13.23‰,指示成矿流体中的CO_2主要来自岩浆水,少量CO_2来源于围岩海相碳酸盐岩的溶解作用。成矿流体中δD值范围-91‰～-72‰,δ^(18)OH矿流体以岩浆流体为主。成矿流体与围2岩的水-岩反应是导致该区铜铅锌2矿床中白云石和黄铜矿、闪锌矿和方铅矿矿物沉淀结晶的主要机制。矿石金属硫化物δ34S值范围4.88‰～8.90‰,平均值为7.37‰,介于岩浆硫与海水硫之间,且与矿集区内典型的徐家沟铜矿床矿石矿物δ34S变化区间重叠,表明硫主要来自于岩浆硫,部分硫来自海水硫酸盐。矿石中黄铁矿的初始锶同位素比值87Sr/86Sr比值为0.72,高于赋矿围岩锶同位素比值,接近大陆地壳的87Sr/86Sr比值(0.719),指示了成矿流体流经了雪花太坪组地层,并与其中具有高87Sr/86Sr比值的白云岩进行水岩反应及同位素交换。