湘中锡矿山超大型锑矿床的碳、氧同位素体系

本文系统地研究了锡矿山锑矿床的围岩、蚀变围岩和热液成因方解石的碳、氧同位素组成。研究表明，相对于区域地层，矿区灰岩明显亏损^18O；围岩蚀变过程中，围岩的δ^18O值趋于减小并有明显的空间变化趋势。不同期次方解石的碳、氧同位素特征明显不同：成矿早期显示出深特征；成矿晚期方解石的碳、氧同位素组成呈正相关，为水－岩反应和温度降低耦合作用所致；成矿期后方解石的碳、氧同位素组成呈明显的负相关，这种方解石的沉淀介质成成矿流体明显不同。水－岩反应的理论模拟显示，成矿流体不可能为未经深部循环的大气降水；成矿流体中的可溶性碳以H2CO3为主；早期成矿流体的δ^13C、δ^18O分别为－6‰、＋10‰，晚期成矿流体的δ^13C、δ^18O分别为0‰、4‰。     

滇西北衙金矿方解石的碳氧同位素特征及其成因

北衙金矿床是金沙江-哀牢山富碱侵入岩带上迄今发现的与富碱侵入岩有关的最重要的金矿床.方解石是北衙金矿体中的主要脉石矿物,其形成与金矿化关系密切.本文在划分方解石期次基础上,定量模拟了北衙金矿方解石的碳、氧同位素成因模式.该模式暗示:北衙金矿方解石为碳酸盐蚀变(重结晶)成因,与Ⅱ期方解石形成有关的主成矿期流体的C、O同位素组成分别为δ13C=-5.5‰,δ18 O=10.5‰,具典型的岩浆流体特征;而与Ⅲ期方解石形成有关的晚期流体的C、O同位素组成相对较低,分别为δ13C=-12‰,δ18 O=7‰,说明部分地加入了大气降水.     

华东南相山铀矿田的氢氧同位素地球化学研究

矿物及包裹体水的氢氧同位素组成的研究结果表明，相山铀矿田成矿热液的δ^18O与δD值分别变化于－67‰－－7．2‰（SMOW）和－44．1‰－－5．2‰，属大气降水成因流体，蚀变体系δ^18O的变化情况显示，与岩石作用的流体具低δ^18O的降水特征，不同水／岩比值条件下的水－岩同位素平衡交换反应的理论计算和综合分析揭示，本矿田的铀成矿热液起源于大气降水与相山主要岩石的相互作用，岩浆水对成矿热液的贡献不大。     

江苏观山高硫型铜铅金矿床稳定同位素地球化学和成因意义

江苏观山铜铅金矿是典型的高硫型浅成低温热液矿床。本文通过对观山铜铅金矿床氢、氧、碳、硫同位素组成的研究,探讨成矿溶液中水、碳、硫的来源以及成矿溶液的演化。同位素测定显示石英流体包裹体水的δD=-90‰～-70‰,δ18O水=-8.9‰～-1.1‰;热液方解石流体包裹体水的δD=-90‰～-81‰,δ18O水=0.1‰～2.3‰。氢氧同位素组成说明成矿流体主要为与围岩进行过水岩反应的循环大气降水,不排除有少量岩浆水的加入。黄铁矿与黄铜矿矿石的δ34SV-CDT=5.8‰～9.9‰,平均值为7.6‰,表明该矿成矿过程中的S很可能是沉积岩来源的硫与岩浆岩来源硫的混合。矿床中可见较多的重晶石等硫酸盐矿物,这种高价态硫的矿物的存在显示其成矿溶液具有富集34S的特征,加上成矿过程中流体的沸腾导致H2S等气体大量逸出和残余岩浆流体富集34S,使得沉淀的黄铁矿、黄铜矿等硫化物同样具有富集34S的特征;热液方解石碳同位素δ13C方解石=-4.1‰～6.1‰,平均为δ13C方解石=1.3‰,显示其中的C主要来源于流体对流循环过程中对基底岩石中碳酸盐地层的溶解。     

新疆萨喀尔得铜矿C-H-O-S同位素特征

新疆萨喀尔得铜矿属中低温热液型,该矿石英和方解石样品中^δ13CPDB值为-17．3‰— -0．7％,δ^18OSMOW为16．2‰-22．4‰ δ18OH2O 水值为6.9‰-12.5‰水值为6．9‰-12．5‰,8D变化于-73．8‰—-52．4‰之间。研究表明,成矿流体主要来源于深部发生循环加热的建造水,并混合变质水和岩浆水;成矿早期流体中的C主要来源于地层水或大气降水,晚期有深部岩浆水的加入。^δ^34S值变化范围为0．2‰-6．1％o,表明流体中的S主要来自岩浆或上地幔。     

攀西大陆槽稀土矿床深源成矿流体的稳定同位素证据

通过对大陆槽矿床的成矿流体稳定同位素研究表明,矿体石英中流体包裹体的δD、δ^18O和δ^13C值分别为-87‰、 6．0‰和-8．4‰,矿石(氟碳铈矿)的δ^13C为-8．0‰,矿体萤石中流体包裹体的δD和δ^18O分别为-99‰和-11．6‰。研究表明,矿床的成矿流体应为少量大气降水混合的深源成矿流体,流体包体中和矿石中的碳则可能源自较深的壳幔混熔源区。     

云南白秧坪银铜多金属矿集区碳氧同位素组成及其意义

为探讨兰坪盆地内白秧坪银铜多金属矿集区水_岩反应的可能性 ,对矿集区的热液矿物、蚀变岩石和原岩的碳、氧同位素组成进行了分析。分析结果显示 ,热液成矿阶段形成的方解石、菱铁矿、菱锶矿的δ13 CPDB 值为-8.3‰～ + 2 .7‰ ,相对变化较小 ;而δ18OSMOW 值为 -2 .5‰～ + 2 4.3‰ ,变化较大 ,且出现了自然界中少见的极低值(± 0‰ )。水岩交换模拟反应显示 ,在成矿早阶段 ,成矿流体的δ13 C和δ18O值分别为 -7‰和 + 7‰ ,与岩浆水组成特征相似 ,它是一种具有深源CO2 的热卤水。在此流体中 ,可溶性碳以HCO-3 为主 ,方解石等热液矿物的形成温度为3 0 0～ 160℃ ,水岩交换比值较小 (0～ 0 .4)。在成矿晚阶段 ,成矿流体的δ13 C和δ18O值分别为 -2 .5‰和 -12 .5‰ ,可溶性碳以H2 CO3 为主 ,方解石等形成温度为 2 50～ 150℃ ,水岩交换比值稍大 (0 .2～ 0 .6) ,显示出晚阶段成矿流体具有大气降水的特征。δ13 C值的增加 ,很可能与降温作用和灰岩的溶解或去碳酸盐化作用有关     

黔西北天桥铅锌矿床热液方解石C、O同位素和REE地球化学

利用连续流动质谱和电感耦合等离子体质谱(ICP-MS)对黔西北天桥铅锌矿床原生矿石中脉石矿物热液方解石C、O同位素组成和稀土元素含量进行了分析,结果表明热液方解石C、O同位素组成相对均一,不同标高方解石C、O同位素组成不具明显差别,其δ13CPDB和δ18OSMOW分别为-3.4‰～-5.3‰和14.7‰～19.5‰,在δ13CPDB-δ18OSMOW图上介于原始碳酸岩与海相碳酸盐岩之间。热液方解石总稀土元素含量较低(ΣREE=6.80×10-6～49.1×10-6),表现为轻稀土富集、Eu负异常的"M"型,其Eu/Eu*变化范围为0.30～0.55,与硫化物具有相似的稀土配分模式。根据热液方解石与蚀变围岩、远矿围岩及不同时代地层碳酸盐岩的C、O同位素组成和REE含量特征对比结果,结合前人研究成果,认为该矿床成矿流体具"多来源混合"特征,其中围岩碳酸盐岩为成矿流体提供了主要的C和REE来源,地层中膏岩海相硫酸盐岩为成矿流体提供了主要的S来源,而成矿流体中的水则主要为变质基底昆阳群等提供的变质水,并受到大气降水的影响。     

云南澜沧老厂大型银多金属矿床碳、氧同位素组成及其意义

文章系统研究了老厂矿床的碳酸盐围岩和成矿方解石的碳、氧同位素组成.研究表明,相对于区域地层,矿区碳酸盐岩围岩普遍亏损18O;成矿方解石的碳氧同位素总体上具有明显的正相关性,这些特征表明成矿流体与围岩发生了大规模的水岩反应.文章初步建立了水岩反应的理想模式,根据该模式进一步将成矿方解石划分为矿体中心相和边缘相2组.水岩反应理论模拟表明:总体上成矿流体中的可溶性碳以H2CO3为主,中心相成矿流体的δ13C、δ18O值分别为-5.5‰和+4‰,具有典型深部岩浆流体的特征;边缘相成矿流体的δ13C、δ18O值分别为-1.5‰和+4‰,代表了深部岩浆流体与下渗天水共同交代碳酸盐岩围岩后的碳、氧同位素特征.     

新疆萨喀尔得铜矿C-H-O-S同位素特征简

新疆萨喀尔得铜矿属中低温热液型,该矿石英和方解石样品中δ13CPDB值为-17.3‰~-0.7‰,δ18OSMOW为16.2‰~22.4‰,δ18OH2O水值为6.9‰~12.5‰,δD变化于-73.8‰~-52.4‰之间。研究表明,成矿流体主要来源于深部发生循环加热的建造水,并混合变质水和岩浆水;成矿早期流体中的C主要来源于地层水或大气降水,晚期有深部岩浆水的加入。δ34S值变化范围为0.2‰~6.1‰,表明流体中的S主要来自岩浆或上地幔。     

矿床地球化学应用

稳定同位素方法已成为现代地球科学研究的重要手段之一，稳定同位素体系的理论模式及其地球化学应用是国际上地球化学研究的前沿方向之一。本文概括了热液体系内成矿地球化学过程引起稳定同位素组成变化的定量理论模式，包括热液矿物之间的同位素平衡的判断、热液去气和矿物沉淀的储库效应、二元混合与矿床成因等。这些模型对于确定成矿温度、鉴定成矿流体源区和推测成矿地球化学机理提供了更为合理的同位素数据定量解释基础。     

The Darasun gold deposit,Eastern Transbaikal region: Chemical composition,REE patterns,and stable carbon and oxygen isotopes of carbonates from ore veins

The chemistry, REE patterns, and carbon and oxygen isotopic compositions of carbonates from ore veins of the Darasun deposit are discussed. In addition to the earlier described siderite, calcite, and carbonates of the dolomite-ankerite series, kutnahorite is identified. The total REE content in Fe-Mg carbonates of the dolomite-ankerite series (2.8–73 ppm) is much lower than in later calcite (18–390 ppm). δ¹³C of Fe-Mg carbonates and calcite varies from +1.1 to −6.7‰ and from −0.9 to −4.9‰, respectively. δ¹⁸O of Fe-Mg carbonates and calcite varies from +17.6 to 3.6‰ and from +15.7 to −0.5‰, respectively. The REE sum and carbon and oxygen isotopic compositions reveal zonal distribution relative to the central granodiorite porphyry stock. The correlation between the carbon and oxygen isotopic compositions and REE sum reflects variations in the physicochemical formation conditions and composition of ore-forming fluid. The isotopic composition of fluid is calculated, and possible sources of its components are considered. Earlier established evidence for a magmatic source of ore-forming fluid and participation of meteoric water in ore formation is confirmed. Geochemical evidence for interaction of ore-forming fluid with host rocks is furnished. The relationships between the REE sum, on the one hand, and carbon and oxygen isotopic compositions of hydrothermal ore-forming fluid, on the other, are established.     

Three–Dimensional Isotopic Characteristics of Crystalline Limestone around the Sakonishi Zn Ore Bodies in the Kamioka Mining District, Japan

Abstract: Predominant Zn-rich ore bodies were found to a deep part of the Sakonishi area in the Kamioka mining district, Japan. The ore mineralization was recognized at 230 to 300m above sea level in the Sakonishi area. Since crystalline limestone is broadly distributed over the area, and the variation in isotopic composition is easily detected, the isotopic prospecting should be powerful in surveying of the extent of the ore bodies and the related hydrothermal system. Although isotopic anomalies have been extracted two-dimensionally so far, three-dimensional information is possibly more powerful. In this paper, Zn-rich ore bodies in the Sakonishi area are treated as hydrothermal ore deposits, and the importance of the activity of hydrothermal fluids during mineralization is emphasized. Oxygen and carbon isotopic ‘iso–surfaces’ are three-dimensionally calculated for the Sakonishi area. The δ¹⁸O values of crystalline limestone from the surface and from the drill holes range from +8. 1 to +21. 1% and from –2. 7 to +20. 4%, respectively. The δ¹³C values of crystalline limestone from the surface and from the drill holes range from –1. 0 to +5. 3% and from –7. 7 to +4. 6%, respectively. The oxygen and carbon iso-topic ratios at the mineralization level are extremely low, but there are exceptions as to carbon isotopes. The oxygen isotopic ratios of crystalline limestone may decrease by isotopic exchange reaction with a hydrothermal fluid, while the carbon isotopic ratios slightly change. Since the precipitated calcite from a hydrothermal fluid has low carbon isotopic ratio and various oxygen isotopic ratio depending on the formation temperature, the bulk sample of crystalline limestone containing the precipitated calcite has oxygen and carbon isotopic ratios of relatively low values accordingly. Thus the decrease mechanism for carbon isotopic ratio of crystalline limestone is different from that for oxygen isotopic ratio. Samples with the carbon isotopic ratio of –4 to –8% are considered to be crystallized from hydrothermal fluids. Since the oxygen and carbon isotopic ratios of crystalline limestone at the ore mineralization level are low, the ore bodies are considered to have formed by a prominent hydrothermal activity. Thus oxygen and carbon isotopic ratios of crystalline limestone can be used as an indicator of the related hydrothermal activity. The alteration such as chloritization is intense near fractures in the Sakonishi area, showing that the hydrothermal system is controlled by a fracture system. It is assumed that the decreased isotopic ratios indicate the high degree of reactivity with hydrothermal fluids, and the depleted zone in oxygen and carbon isotopes may correspond to the conduit of the hydrothermal fluids.     

Prograde and retrograde fluid-rock interaction in calc-silicates northwest of the Idaho batholith: stable isotopic evidence

Carbon and oxygen isotopic analyses of silicate and carbonate minerals indicate that isotopic compositions in metasediments of the Wallace Formation (Belt Supergroup) exposed northwest of the Idaho batholith have been affected by both prograde and retrograde fluid-rock interaction. Silicates retain isotopic fractionations that reflect equilibration at peak metamorphic temperatures. In contrast, calcite oxygen isotopic compositions range from δ¹⁸O(Calcite)=+2.3 to +18.6‰ SMOW (standard mean oceanic water) and indicate that some calcites have exchanged with low-δ¹⁸O meteorichydrothermal fluids. Values of Δ¹⁸O (Quartz-Calcite) as large as +15.5 clearly indicate that the isotopic depletion of these calcites postdates the peak of regional metamorphism. Carbon isotopic compositions of ¹⁸O-depleted calcites are not significantly shifted relative to δ¹³C values in undepleted calcites, suggesting that the retrograde fluid was carbon-poor. Petrographically, retrograde fluid-rock interaction is associated with the occurrence of fine-grained, highly-luminescent calcite overgrowths on less-luminescent, metamorphic calcites, slight to moderate argillic alteration, and pseudomorphing of scapolite porphyroblasts by fine-grained albite. Retrograde isotopic depletions may be related to shallow meteoric-hydrothermal fluid flow developed around the Idaho batholith after intrusion and rapid uplift of the terrane. Peak metamorphic isotopic compositions in the Wallace Formation reflect mineralogically heterogeneous protolith compositions and isotopic fractionation due to devolatilization and/or infiltration. Variability in oxygen isotopic compositions on the order of 4–6‰ within the same rock type can be attributed to the combined effects of inherited isotopic compositions and isotopic shifts resulting from prograde devolatilization. Isotopic and compositional heterogeneity on the scale of mm to m precludes generalization of isotopic gradients on a regional scale. The isotopic data presented here, and metamorphic fluid compositions determined in previous studies, are best reconciled with heterogeneous bulk compositions, dominantly channelized prograde and retrograde fluid flow, and locally low fluid-rock ratios.     

云南会泽超大型铅锌矿床C、O同位素地球化学

云南会泽超大型铅锌矿床规模大、品位富、伴生有用元素多,预示其成矿环境较为特殊。本文分析该矿床矿石中脉石矿物方解石和赋矿碳酸盐地层的C、O同位素组成,结果表明矿石中脉石矿物方解石的C、O同位素组成相对均一,不同矿体(不同标高)、不同产状以及相同矿体不同产状方解石的C、O同位素组成不具明显差别,其δ13CPDB值和δ18OSMOW值分别为-2.1‰～-3.5‰(均值-2.8‰)和16.7‰～18.6‰(均值17.7‰),在δ13CPDB-δ18OSMOW图上集中于岩浆碳酸岩与海相碳酸盐岩之间的狭小范围内。多方面的证据表明:矿床成矿流体为壳-幔混合流体,其中壳源组分可能主要由矿区(或区域)碳酸盐地层提供,而幔源组分则可能与区域大面积峨眉山玄武岩岩浆活动过程中的去气作用有关。     

贵州簸箕田金矿单矿物稀土元素和同位素地球化学特征

簸箕田金矿位于灰家堡背斜东头倾覆端,是灰家堡卡林型金矿田重要的组成部分。金矿床具有低温成矿特征,出现硅化、白云石化、黄铁矿化等围岩蚀变和特征的Au-As-Hg元素组合。成矿期方解石具有MREE富集和正Eu异常特点,显示矿热液是一种MREE相对富集以及具有正Eu异常的还原性流体,来源于深部或至少经历过对富含斜长石源区的水-岩反应。成矿期方解石的δ~(13)C为-6‰～-0.1‰,成矿期后方解石的δ~(13)C为0.2‰～3.2‰,显示成矿期碳来源于地幔碳和地层碳的混合,成矿期后碳主要来自于地层。矿床硫同位素变化于0.73‰～5.86‰,组成均一化较高,具有接近幔源硫的特征,反映了成矿物质可能主要来自于深源岩浆。总之我们推测成矿物质主要来源于深部,在燕山期区域构造作用下沿深大断裂上涌,当成矿流体运移至背斜核部时,由于成矿条件的聚变,金被快速富集沉淀,形成簸箕田金矿床。     

辽河盆地西部凹陷沙河街组砂岩碳酸盐胶结物特征

碳酸盐胶结物中氧碳同位素组成研究是分析成岩过程中流体-岩石相互作用的重要技术方法.综合运用岩石学、矿物学和地球化学方法，对辽河盆地西部凹陷沙河街组砂岩中碳酸盐胶结物的化学组成和碳酸盐胶结物及成岩流体同位素组成特征进行系统分析.研究表明，研究区碳酸盐岩主要为方解石和白云石，胶结物主要类型为嵌晶式胶结、孔隙式胶结、斑块状胶结和星点状胶结.碳、氧稳定同位素组成能有效地反映成岩-成矿流体及其他物质的来源，碳酸盐胶结物与现今浅层地下水氧同位素组成差异巨大而与变质水同位素组成具有相似性，反映了盆地演化过程中活动热流体对成岩作用的影响.包裹体的氢、氧同位素组成可表征成矿溶液的演化特征，砂岩碳酸盐胶结物包裹体更富集氢的轻同位素和氧的重同位素，表明发生了明显的“氧-18漂移”.碳酸盐胶结的成矿溶液表现出“受热雨水”的同位素组成特征，反映了深源活动热流体对成岩作用的影响.      

沉积地层中成矿作用的碳同位素特征和含矿缺氧盆地成因新观点

沉积盆地内地层中碳的来源 ,根据其碳、氧同位素特征可归纳为 :海洋沉积碳酸盐碳、生物碳、热解非生物成因碳、大气淡水方解石碳和热卤水系统中的无机碳。热水成因的金矿及喷气 沉积矿床中的碳都具有深源成因的无机碳。深部含无机碳的热流体喷溢到海洋底部可以解释为扩张盆地底部形成的缺氧环境和含矿黑色页岩的主导原因