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1.
西华山钨矿床晶洞中水晶与黑钨矿流体包裹体显微测温与特征元素测定 总被引:1,自引:0,他引:1
摘要:西华山钨矿床晶洞中水晶与黑钨矿以及晶洞外部块状石英与共生黑钨矿中流体包裹体对比研究结果表明,后期应力作用和流体改造是造成共生石英与黑钨矿包裹体均一温度出现重大差异的主要原因。一般来说,在后期应力作用和流体改造下,黑钨矿有较好的稳定性,能较好地保存原生包裹体和较少出现次生包裹体,而与之共生石英中的原生包裹体几乎破坏殆尽,现在所看到的包裹体绝大部分是后来形成的次生包裹体,且很难确切区别原生与次生关系。当后期应力作用和流体改造很微弱时,石英中可保存较多原生包裹体,并且原生与次生关系较易区分。当完全未受应力作用改造时,共生石英(水晶)与黑钨矿中都只有原生包裹体,其Th值和盐度值基本相同或完全一致,且石英(水晶)流体包裹中富含W、Mn、Fe等成矿元素,表明石英与黑钨矿是由同一流体在相同时间和相同条件下沉淀的。鉴于一般金属矿床皆在一定程度上经受了后期应力作用和流体改造,因此在有关流体包裹体研究中应该结合不透明矿物进行全面对比,并且切实加强岩相学研究。 相似文献
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西华山钨矿床共生透明矿物与不透明矿物中流体包裹体的对比研究 总被引:3,自引:1,他引:2
西华山钨矿床是一个产于燕山期花岗岩中的大脉型钨矿床。笔者利用红外显微镜、冷热台及其他相关设备对矿床中的透明矿物(石英、绿柱石和萤石)与不透明矿物(黑钨矿、黄铁矿)中的流体包裹体进行了对比研究。结果显示,共生透明矿物与不透明矿物之间,在包裹体均一温度等特征上既可基本相同又可出现很大差异。一般来说,黑钨矿能有效地保存原生流体包裹体(th=300~420℃;晶洞中为220~290℃),仅有少量次生包裹体(th=160~280℃),而与之共生的石英中原生包裹体则几乎被破坏殆尽,现在所见到的包裹体绝大多数是次生的或是在较晚结晶时捕获的(th=130~270℃)。只有未经后期应力作用和流体改造的晶洞水晶及与其共生的黑钨矿,二者获得的结果才相同或相似。绿柱石中通常有大量的次生包裹体和原生包裹体。黑钨矿与绿柱石中硅酸盐熔融包裹体的出现,表明西华山钨矿床的成矿作用始于岩浆-热液过渡阶段,其初始成矿流体是一种岩浆-热液过渡性流体,尔后才演变成单一的热水溶液。笔者认为,在进行金属矿床流体包裹体研究时,应强调共生透明矿物与不透明矿物的对比研究,在进行对比研究时,详尽的基础地质研究和包裹体岩相学观察必不可少;当单独利用透明矿物包裹体资料对金属矿床进行地质解释时,需慎之又慎。 相似文献
3.
共生黑钨矿与石英等多种矿物中流体包裹体的红外显微测温对比研究——以江西西华山石英脉钨矿床为例 总被引:3,自引:0,他引:3
西华山钨矿床是一个产于燕山期花岗岩中的大脉型钨矿床。已有百余年的开采史。但在矿床成矿条件和成矿流体性质等方面一直存在不同认识。作者利用红外显微镜及其它相关设备,对西华山矿床不同中段样品中的黑钨矿、锡石、绿柱石、黄铁矿、闪锌矿、石英和萤石中的流体包裹体进行了详细对比研究。结果显示,蚀变花岗岩中造岩石英只见次生气液包裹体,晶洞水晶中只有原生包裹体,而云英岩石英中原生、次生包裹体均较发育。黑钨矿中以原生气液包裹体为主,在早期结晶的黑钨矿中还有较多的硅酸盐熔融包裹体,而晶洞中的黑钨矿和水晶一样——只有原生气液包裹体。绿柱石中除了硅酸盐包裹体外,主要是气液包裹体(多为次生)。其它锡石、黄铁矿、闪锌矿和萤石等都只有气液包裹体(原生或次生)。研究结果表明,西华山钨矿床的初始成矿流体是一种岩浆——热液过渡性流体,尔后才演变成单一的热水溶液,在这一过程中黑钨矿、黄铁矿、闪锌矿、萤石和石英等矿物不断晶出。矿床总的成矿温度大致为700~200℃,压力约为160~200MPa。各种气液包裹体的盐度主要为5.0%~10%Na Cleqv。文中还对这些数据的地质意义以及对脉钨矿床流体包裹体研究和数据解释中的某些问题进行了较深入的讨论。 相似文献
4.
西华山黑钨矿石英脉绿柱石中熔融包裹体的发现及其意义 总被引:7,自引:0,他引:7
过去一直认为西华山黑钨矿石英脉是高中温热液充填而成。研究发现,在黑钨矿石英脉的绿柱石中存在与流体(气液)包裹体共生的流体-溶体包裹体和溶融包裹体,这表明形成黑钨矿石英脉的成矿流量是一种岩浆-热液过渡性流体。 相似文献
5.
湖南瑶岗仙石英脉型黑钨矿床成矿流体特征 总被引:8,自引:0,他引:8
利用红外显微镜对湖南瑶岗仙石英脉型黑钨矿床中不透明矿物黑钨矿的流体包裹体以及黑钨矿共生的透明矿物石英中的流体包裹体进行显微测温对比分析,结果表明,黑钨矿中的原生流体包裹体有富液体包裹体、纯液体包裹体和富气体包裹体等,其均一温度范围大致在230℃~320℃,平均温度为281℃;冰点-4.2℃~-12.9℃,盐度6.74%~16.80%溶液。石英中流体包裹体主要为富液体包裹体,其均一温度范围大致在202℃~273℃,平均温度为240℃;冰点-0.5℃~-4.1℃,盐度为0.88%~6.59%溶液。黑钨矿形成时捕获的流体属于中温、中等盐度、低密度的流体,石英形成时捕获的流体属于中低温、低盐度、低密度的流体。通过黑钨矿中流体包裹体的显微测温结果及前人研究成果分析显示,成矿流体主要来自岩浆,流体演化经历了自然冷却、混合作用等过程,这些过程可能是钨沉淀的有效机制。 相似文献
6.
西华山钨矿床中熔融包裹体的初步研究与矿床成因探讨 总被引:10,自引:2,他引:10
过去一直认为西华山黑钨矿石英脉是高中温热液充填而成。研究发现,在黑钨矿石英脉的绿柱石中存在与流体(气液)包裹本共生的流体-熔体包裹体和熔融包裹体,表明形成黑钨矿石英脉的成矿流体是一种岩浆-热液过渡性流体,并讨论了熔融体与金属成矿作用的关系。 相似文献
7.
共生黑钨矿与石英中流体包裹体红外显微对比研究——以瑶岗仙石英脉型钨矿床为例 总被引:19,自引:5,他引:14
利用红外显微镜对湖南瑶岗仙石英脉型黑钨矿矿床中共生的黑钨矿与石英原生流体包裹体均一温度和冰点的测定结果表明,石英中流体包裹体均一温度范围为149~352℃,主要集中在160~300℃之间,盐度w(NaCleq)为0.9%~9.5%;黑钨矿中流体包裹体均一温度范围为212~386℃,主要集中在280~360℃之间,盐度w(NaCleq)为4.5%~15.2%.可见,黑钨矿中流体包裹体具有更高的均一温度和盐度,与石英中原生流体包裹体均一温度相差可达60℃,盐度w(NaCleq)相差可达6%.结合该矿床的矿石显微结构特征、包裹体岩相学特征及前人所做的氢、氧同位素测试分析结果,推断黑钨矿主要形成于早期阶段,为均一流体冷却成因,石英形成较晚,主要为流体混合成因. 相似文献
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9.
将四极质谱、分子泵和超高真空流体包裹体击碎装置联机,利用冷阱与外置液氮去除部分水蒸气和杂气,建立分阶段提取不同世代流体包裹体并测定其气体成分的实验平台。以锡田钨锡多金属矿床中石英脉型钨锡矿矿石为研究对象,分阶段提取不同世代流体包裹体并测定其气体成分,对比分析矿石中共生石英–黑钨矿矿物对不同阶段释气成分、气体百分含量特征。研究表明初始阶段和后期阶段提取的流体成分一致,以N_2、CO_2和CH_4为主,含少量~(40)Ar、C_2H_6和~4He;但初始阶段N_2、CO_2和~(40)Ar气体浓度高于后期阶段,而CH_4、C_2H_6和~4He气体浓度低于后期阶段,指示初始阶段和后期阶段提取出不同期次的流体包裹体,即初始阶段提取的主要是次生包裹体,后期阶段提取的主要是原生包裹体,而中间阶段是两者的混合,表明四极质谱和超高真空流体包裹体提取装置联用能够实现分阶段提取不同世代流体包裹体且测定其气体成分。其中,次生包裹体富N_2、CO_2和~(40)Ar,而原生包裹体富CH_4、C_2H_6和~4He。 相似文献
10.
湖南宜章瑶岗仙黑钨矿石英脉成矿流体性质的探讨 总被引:17,自引:0,他引:17
对于黑钨矿石英脉的成因,历来都认为是高中温热液充填而成。本文根据石英脉与细晶岩、伟晶岩过渡;围岩蚀变种类及强度的变化;石英脉中晶洞特征的研究;矿物包裹体研究及测温资料;金属矿物局部大量集中的不规律性;石英脉中黑钨矿的产出特点;产在角岩中的石英脉内出现花岗岩角砾;黑钨矿中MnO/FeO比值变化特征:含钨石英脉中矿物组合和化学成分变化特征,认为形成黑钨矿石英脉的成矿流体是一种粘稠的、密度较大、成分以SiO_2为主的熔浆—热液过渡性流体,它具有上部偏液、下部偏浆的特点。 相似文献
11.
Feng Yang Wei Zhai Xiaoming Sun Reiner Klemd Yanyan Sun Yunshan Wu Renmin Hua Siqi Zheng 《Resource Geology》2019,69(1):107-122
The Yaoling tungsten deposit is a typical wolframite quartz vein‐type tungsten deposit in the South China metallogenic province. The wolframite‐bearing quartz veins mainly occur in Cambrian to Ordovician host rocks or in Mesozoic granitic rocks and are controlled by the west‐north‐west trending extensional faults. The ore mineralization mainly comprises wolframite and variable amounts of molybdenite, chalcopyrite, pyrite, fluorite, and tourmaline. Hydrothermal alteration is well developed at the Yaoling tungsten deposit, including greisenization, silicification, fluoritization, and tourmalinization. Three types of primary/pseudosecondary fluid inclusions have been identified in vein quartz, which is intimately intergrown with wolframite. These include two‐phase liquid‐rich aqueous inclusions (type I), two‐ or three‐phase CO2‐rich inclusions (type II), and type III daughter mineral‐bearing multiphase high‐salinity aqueous inclusions. Microthermometric measurements reveal consistent moderate homogenization temperatures (peak values from 200 to 280°C), and low to high salinities (1.3–39 wt % NaCl equiv.) for the type I, type II, and type III inclusions, where the CO2‐rich type II inclusions display trace amounts of CH4 and N2. The ore‐forming fluids are far more saline than those of other tungsten deposits reported in South China. The estimated maximum trapping pressure of the ore‐forming fluids is about 1230–1760 bar, corresponding to a lithostatic depth of 4.0–5.8 km. The δDH2O isotopic compositions of the inclusion fluid ranges from ?66.7 to ?47.8‰, with δ18OH2O values between 1.63 and 4.17‰, δ13C values of ?6.5–0.8‰, and δ34S values between ?1.98 and 1.92‰, with an average of ?0.07‰. The stable isotope data imply that the ore‐forming fluids of the Yaoling tungsten deposit were mainly derived from crustal magmatic fluids with some involvement of meteoric water. Fluid immiscibility and fluid–rock interaction are thought to have been the main mechanisms for tungsten precipitation at Yaoling. 相似文献
12.
The Piaotang deposit is one of the largest vein-type W-polymetallic deposits in southern Jiangxi Province, South China. The coexistence of wolframite and cassiterite is an important feature of the deposit. Based on detailed petrographic observations, microthermometry of fluid inclusions in wolframite, cassiterite and intergrown quartz was undertaken. The inclusions in wolframite were observed by infrared microscope, while those in cassiterite and quartz were observed in visible light. The fluid inclusions in wolframite can be divided into two types: aqueous inclusions with a large vapor-phase proportion and aqueous inclusions with a small vapor-phase ratio. The homogenization temperature (Th) of inclusions in wolframite with large vapor-phase ratios ranged from 280°C to 390°C, with salinity ranging from 3.1 to 7.2 wt% NaCl eq. In contrast, the Th values of inclusions with small vapor-phase ratios ranged from 216°C to 264°C, with salinity values ranging from 3.5 to 9.3 wt% NaCl eq. Th values of primary inclusions in cassiterite ranged from 316°C to 380°C, with salinity ranging from 5.4 to 9.3 wt% NaCl eq. Th values for primary fluid inclusions in quartz ranged from 162°C to 309°C, with salinity values ranging from 1.2 to 6.7 wt% NaCl eq. The results show that the formation conditions of wolframite, cassiterite and intergrown quartz are not uniform. The evolutionary processes of fluids related to these three kinds of minerals are also significantly different. Intergrown quartz cannot provide the depositional conditions of wolframite and cassiterite. The fluids related to tungsten mineralization for the NaCl-H2O system had a medium-to-high temperature and low salinity, while the fluids related to tin mineralization for the NaCl-H2O system had a high temperature and medium-to-low salinity. The results of this study suggest that fluid cooling is the main mechanism for the precipitation of tungsten and tin. 相似文献
13.
Joseph Onglo Espi Ken-Ichiro Hayashi Kosei Komuro Hiroyasu Murakami Yoshimichi Kajiwara 《Resource Geology》2007,57(3):249-268
The Bilimoia deposit (2.23 Mt, 24 g/t Au), located in the eastern Central Mobile Belt of mainland Papua New Guinea, is composed of fault‐hosted, NW–NNW‐trending Irumafimpa–Kora and Judd–Upper Kora Au‐quartz veins hosted by Middle–Late Triassic basement that was metamorphosed to medium‐grade greenschist facies between Middle–Late Triassic and Early–Middle Jurassic. Mineralizing fluids were introduced during crustal thickening, rapid uplift, change of plate motions from oblique to orthogonal compression, active faulting and S3 and S4 events in an S1–S4 deformation sequence. The Bilimoia deposit is spatially and temporally related to I‐type, early intermediate to felsic and late mafic intrusions emplaced in Late Miocene (9–7 Ma). Hydrothermal alteration and associated mineralization is divided into 10 main paragenetic stages: (1) chlorite–epidote‐selvaged quartz–calcite–specularite vein; (2) local quartz–illite–pyrite alteration; (3) quartz–sericite–mariposite–fuchsite–pyrite wall‐rock alteration that delimits the bounding shears; (4) finely banded, colloform‐, crustiform‐ and cockade‐textured and drusy quartz ± early wolframite ± late adularia; (5) hematite; (6) pyrite; (7) quartz ± amethyst‐base metal sulfides; (8) quartz–chalcopyrite–bornite–Sn and Cu sulfides–Au tellurides and Te ± Bi ± Ag ± Cu ± Pb phases; (9) Fe ± Mn carbonates; and (10) supergene overprint. Fluid inclusions in stage 4 are characterized by low salinity (0.9–5.4 wt% NaCl equivalent), aqueous–carbonic fluids with total homogenization temperatures ranging from 210 to 330°C. Some of the inclusions that homogenized between 285 and 330°C host coexisting liquid‐ and vapor‐rich (including carbonic) phases, suggesting phase separation. Fluid inclusions in quartz intergrown with wolframite have low salinity (0.9–1.2 wt% NaCl equivalent), aqueous–carbonic fluids at 240–260°C, defining the latter’s depositional conditions. The ore fluids were derived from oxidized magmatic source initially contaminated by reduced basement rocks. Wall‐rock alteration and involvement of circulating meteoric waters were dominant during the first three stages and early part of stage 4. Stage 5 hematite was deposited as a result of stage 4 phase separation or entrainment of oxygenated groundwater. Gold is associated with Te‐ and Bi‐bearing minerals and mostly precipitated as gold‐tellurides during stage 8. Gold deposition occurred below 350°C due to a change in the sulfidation and oxidation state of the fluids, depressurization and decreasing temperature and activities of sulfur and tellurium. Bisulfides are considered to be the main Au‐transporting complexes. The Bilimoia deposit has affinities that are similar to many gold systems termed epizonal orogenic and intrusion‐related. The current data allow us to classify the Bilimoia deposit as a fault‐controlled, metamorphic‐hosted, intrusion‐related mesothermal to low sulfidation epithermal quartz–Au–Te–Bi vein system. 相似文献
14.
山东文登金矿成矿条件及成矿过程——阴极发光技术在包裹体研究中的应用 总被引:4,自引:1,他引:3
使用阴极发光技术可取得一般岩石显微镜无法得到的地质信息,并可将包裹体的研究从原来的“群分析”统计规律研究水平提高到“单包体分析”水平,获得更小时间单位成矿流体的演化特征,因而能更准确地模拟和恢复地质作用过程。运用阴极发光对石英等矿物的研究,发现蚀变带中的石英按不同的形态特征和发光性可以分为三期,和成矿关系密切为第一、二期石英。根据阴极发光下显示的生长微形态,系统地测试三期石英不同生长时期的包裹体物相,从而获取了整个成矿过程流体的p-t-v-x参数,确定构造作用加热大气降水形成成矿流体,体系开放流体两次减压沸腾导致金矿沉淀的矿体定位机理和成矿动力学机制。 相似文献
15.
Fluid inclusions in coesite-bearing eclogites and jadeite quartzite at Shuanghe, Dabie Shan (China) 总被引:6,自引:0,他引:6
Fluid inclusions in coesite‐bearing eclogites and jadeite quartzite at Shuanghe in Dabie Shan, East‐central China, have preserved remnants of early, prograde and/or peak metamorphic fluids, reset during post‐UHP (ultrahigh‐pressure) metamorphic uplift. Inclusions occur in several minerals (e.g. omphacite & epidote), notably as isolated, primary inclusions in quartz included in various host minerals. Two major fluid types have been identified: non‐polar fluid species (N2 or CO2) and aqueous, the latter is by far the most predominant. Aqueous fluids cover a wide range of salinity, from halite‐bearing brines to low salinity fluids. For non‐polar fluids, few N2 inclusions occur in undeformed eclogite, whereas a number of CO2‐rich inclusions have been found in microshear zones of eclogite or jadeite quartzite in close proximity to marble occurrences. The primary character of N2 and high‐salinity aqueous inclusions indicates that they are remnants from UHP metamorphic fluids and for some there is the distinct possibility that they are ultimately derived from pre‐metamorphic fluids. This conclusion is supported by the preservation, in some samples, of microdomains containing synchronous inclusions of variable salinities, which tend to relate to the chemical composition of the host crystal. Carbonic fluids may be derived from neighbouring rocks, notably marble and carbonate‐bearing metasediments, during post‐metamorphic uplift. During post‐UHP exhumation, a limited decrease of the fluid density has occurred, with formation of new sets of fluid inclusions. Fluid movements, however, remained exceedingly limited, at the scale of the enclosing crystal. 相似文献
16.
采用ICP-MS测定了胶东焦家、马塘、东季和红布金矿床黄铁矿、石英及其群体包裹体的微量元素组成。结果表明,黄铁矿包裹体与石英包裹体均富集Cu、Pb和Zn等成矿元素,反映了成矿流体的特征;不同成矿阶段成矿流体特征有差异,石英黄铁矿化阶段、黄铁绢英岩化阶段、石英多金属矿化阶段石英及其包裹体微量元素含量均高于成矿较差的钾长石化阶段的石英及其包裹体;与陆壳微量元素丰度相比,黄铁矿及石英中Cu、Pb、Zn、Ag和Au等成矿元素富集;与地热卤水及斑岩铜矿卤水微量元素含量相比,黄铁矿及石英包裹体中以Cu为代表的成矿元素均较其它元素相对富集,反映了成矿流体中富集成矿元素的特征。上述结果表明,可以采用ICP-MS测定黄铁矿及石英包裹体微量元素来研究成矿流体的特征。 相似文献
17.
小加山钨矿床位于新疆巴里坤地区,属石英脉型钨矿床。矿体赋存于邻近海西晚期花岗岩侵入体附近的中泥盆统大南湖组第一亚组第二段(D2d12)的变晶屑凝灰岩中。黑钨矿石英脉分为灰色含钨石英脉和白色含钨石英脉两种。岩相学观察认为,含矿石英脉中流体包裹体主要为两相水溶液包裹体, EW 走向的灰色石英脉包裹体气液比大, SN 走向的白色石英脉包裹体气液比较小。显微测温结果显示灰色石英脉均一温度(Th)范围为143~354℃,白色石英脉 Th 范围为154~312℃。激光拉曼探针显示小加山钨矿床含黑钨矿石英脉中流体包裹体含有少量 CO2组分。H、O 同位素研究表明:钨矿床成矿流体来源以岩浆水为主。成矿演化过程为:岩浆岩侵入活动→岩浆水运移分离→含钨络合物迁移搬运→冷却富集成矿,成矿晚期流体有大气降水的混合。与赣南钨矿的对比研究表明,小加山钨矿床与赣南钨矿床的成矿流体特征相似;在构造环境上,小加山钨矿床位于东准噶尔造山带和东天山成矿带的交汇复合部位,与位于武夷山和南岭两大成矿带的交汇复合部位的赣南钨矿床成矿环境相似。 相似文献