帮助 关于我们

返回检索结果

湖南黄沙坪多金属矿床流体包裹体研究
Fluid inclusion study of the Huangshaping polymetallic deposit,Hunan Province,South China

查看参考文献41篇

黄诚 1   李晓峰 1 *   王立发 2   刘凤平 2  
文摘 黄沙坪多金属矿床位于南岭中段的湘东南地区,成矿斑岩主要为石英斑岩和花岗斑岩,其中钨钼矿体主要形成于岩体与碳酸盐岩接触带的矽卡岩中,铅锌矿体形成于矽卡岩外围,以及碳酸盐岩地层内的破碎带中。黄沙坪多金属矿床的成矿过程可以分为与钨钼成矿有关的矽卡岩期和与锌铅(钼)成矿有关的硫化物期。早矽卡岩阶段的石榴石和阳起石中包裹体均一温度为528~>600℃,普遍发育含石盐子晶包裹体(盐度达40%~45.5% NaCleqv)和低盐度(3.06%~4.65% NaCleqv)富气相包裹体,表现出流体不混溶现象。该阶段的流体压力大致为600~800bar,在静岩压力条件下,对应深度2.2~3.0km。晚矽卡岩阶段,白钨矿中流体包裹体以高温高盐度流体为特征,成矿温度为400~460℃,盐度为40%~45% NaCleqv,是沸腾作用下发生沉淀的,估算的流体压力大致为200~400bar,相当于静岩压力条件下0.7~1.5km的深度。而该阶段紫色萤石中流体包裹体发育以石盐子晶消失而达到均一的高盐度流体包裹体,其均一温度介于250~303℃,对应盐度介于34.7%~40.6% NaCleqv之间,估算得其最低捕获压力介于1500~2000bar。金属硫化物期,与Mo矿化有关的含辉钼矿石英脉中石英流体包裹体主要以富气相和富液相包裹体共存为特征,温度范围较一致(300~340℃),而盐度变化范围很大(5.86%~16.24% NaCleqv),显示流体的沸腾作用。与Zn-Pb矿化有关的萤石中几乎全部发育Type Ia富液相包裹体,流体沸腾作用不明显,温度集中在240~160℃,盐度范围大(0.88%~16.58% NaCleqv),表明该阶段成矿流体已演变为中低温、低盐度性质的流体。成矿流体包裹体研究表明,黄沙坪多金属矿床W-Mo-Pb-Zn矿床的形成是早期高温高盐度流体向低温低盐度流体演化的产物,在成矿过程中,流体发生了多次的沸腾作用。
其他语种文摘 Huangshaping W-Mo-Pb-Zn polymetallic deposit is located in southeastern Hunan Province, South China. The mineralizations are associated with granite porphyry and quartz porphyry. Tungsten-molybdenum ore bodies occur as disseminated ore in skarn between quartz porphyry and carbonate rocks, while lead-zinc sulfide ores occur as veins outward the skarn, or within carbonate country rocks. The mineralization process can be generally divided into two stages. Skarn stage is associated with W-Mo mineralization and sulfide stage is associated with Pb-Zn mineralization. The fluid inclusions in garnet and actinolite are characterized by coexisting brine and vapor-rich fluid inclusions, indicating an immiscible condition. Using the homogenization temperatures (528℃ to >600℃) and salinity of brine (40%~45.5% NaCleqv), trapping pressure can be estimated to be 600~800bars, equivalent to a depth of 2.2~3.2km. Tungsten mineralization from later skarn stage was formed under boiling condition, characterized by fluid inclusion with high temperature (400~460℃), high salinity (40%~45% NaCleqv). The pressure is estimated to be 200~400bar, equivalent to a depth of 0.7~1.5km. At the sulfide stage, vapor-rich, liquid-rich and CO_2-rich inclusions from quartz are coexisting in molybdenite-bearing quartz vein, indicating boiling at narrow range of temperatures from 300~340℃ and wide range of salinity from 5.86%~16.24% NaCleqv. The fluid inclusions in fluorite associated with Zn-Pb mineralization are almost liquid-rich fluid, indicating fluid boiling is not obvious. During Zn-Pb mineralization stage, the ore-forming temperature drops to 240~160℃ and salinity shows a wide range from 0.88% to 16.58% NaCleqv, indicating the characteristic of low-medium temperature and low salinity of ore-forming fluid. We concluded that the W-Mo-Pb-Zn mineralization in Huangshaping deposit is related to the cooling and boiling of fluids from early high-temperature, high salinity to late low-temperature, low salinity.
来源 岩石学报 ,2013,29(12):4232-4244 【核心库】
关键词 流体包裹体 ; 流体作用与演化 ; 矽卡岩型多金属矿床 ; 湖南黄沙坪
地址

1. 中国科学院地球化学研究所, 矿床地球化学国家重点实验室, 贵阳, 550002  

2. 黄沙坪矿业分公司, 郴州, 424421

语种 中文
文献类型 研究性论文
ISSN 1000-0569
学科 地质学
基金 国家973计划 ;  国家自然科学基金项目 ;  中国科学院“百人计划”项目
文献收藏号 CSCD:5018449

参考文献 共 41 共3页

1.  Baker T. Reconciling fluid inclusion types,fluid processes,and fluid sources in skarns: An example from the Bismark Deposit,Mexico. Mineralium Deposita,2003,38(4):474-495 被引 26    
2.  Becker S P. Synthetic Fluid Inclusions. XVII. 1 PVTX properties of high salinity H_2O-NaCl solutions (> 30% NaCl) : Application to fluid inclusions that homogenize by halite disappearance from porphyry copper and other hydrothermal ore deposits. Economic Geology,2008,103(3):539-554 被引 32    
3.  Bodnar R J. A method of calculating fluid inclusion volumes based on vapor bubble diameters and P-V-T-X properties of inclusion fluids. Economic Geology,1983,78(3):535-542 被引 189    
4.  Bodnar R J. Revised equation and table for determining the freezing point depression of H_2O-NaCl solutions. Geochimica et Cosmochimica Acta,1993,57(3):683-684 被引 447    
5.  Burnham C W. Magmas and hydrothermal fluids. Geochemistry of Hydrothermal Ore Deposits. (2~(nd) Edition),1979:71-136 被引 3    
6.  Collins P L F. Gas hydrates in CO_2-bearing fluid inclusions and the use of freezing data for estimation of salinity. Economic Geology,1979,74(6):1435-1444 被引 168    
7.  Driesner T. The System H_2O-NaCl. Part I. Correlation formulae for phase relations in temperature-pressurecomposition space from 0 to 1000 degrees C,0 to 5000 bar,and 0 to 1 X-NaCl. Geochimica et Cosmochimica Acta,2007,71(20):4880-4901 被引 32    
8.  Fournier R O. The transition from hydrostatic to greater than hydrostatic fluid pressure in presently active continental hydrothermal systems in crystalline rock. Geophysical Research Letters,1991,18(5):955-958 被引 5    
9.  Fournier R O. Hydrothermal processes related to movement of fluid from plastic into brittle rock in the magmatic-epithermal environment. Economic Geology,1999,94:1193-1211 被引 45    
10.  Gu L. On the genesis of the lead-zinc polymetallic deposit in Huangshaping. Hunan Geology, (in Chinese with English abstract),1997,16(4):661-669 被引 1    
11.  Hall D L. Freezing point depression of NaCl-KCl-H_2O solutions. Economic Geology,1988,83(1):197-202 被引 445    
12.  Heinrich C A. The physical and chemical evolution of low-salinity magmatic fluids at the porphyry to epithermal transition: A thermodynamic study. Mineralium Deposita,2005,39(8):864-889 被引 111    
13.  Klemm L M. Hydrothermal evolution of the El Teniente deposit,Chile: Porphyry Cu-Mo ore deposition from low-salinity magmatic fluids. Economic Geology,2007,102(6):1021-1045 被引 40    
14.  Kwak T A P. Fluid inclusions in skarns (carbonate replacement deposits). Journal of Metamorphic Geology,1986,4(4):363-384 被引 13    
15.  Li X F. Hydrothermal alteration and mineralization of middle Jurassic Dexing porphyry Cu-Mo deposit,Southeast China. Resource Geology,2007,57(4):409-426 被引 27    
16.  Li X F. SHRIMP ⅡU-Pb zircon and ~(40)Ar-~(39)Ar muscovite ages of the Yinshan deposit in the Northeast Jiangxi Province,South China. Resource Geology,2007,57(3):325-337 被引 27    
17.  Li X F. Ages and sources of ore-related porphyries at Yongping Cu-Mo deposit in Jiangxi Province,Southeast China. Resource Geology,2013,63(3):288-312 被引 14    
18.  Li X F. U-Pb and Ar-Ar geochronology of the Fujiawu porphyry Cu-Mo deposit, Dexing district, Southeast China: Implications for magmatism, hydrothermal alteration,and mineralization. Journal of Asia Earth Sciences,2013,74:330-342 被引 18    
19.  Meinert L D. Application of skarn deposit zonation models to mineral exploration. Exploration and Mining Geology,1997,6(2):185-208 被引 32    
20.  Meinert L D. Formation of anhydrous and hydrous skarn in Cu-Au ore deposits by magmatic fluids. Economic Geology,2003,98(1):147-156 被引 66    
引证文献 15

1 李晓峰 华南中生代与同熔型花岗岩有关的铜铅锌多金属矿床时空分布及其岩浆源区特征 岩石学报,2013,29(12):4037-4050
被引 27

2 原垭斌 湘南黄沙坪矿区花岗岩的硫同位素特征及其地质意义 地质学报,2014,88(12):2437-2442
被引 7

显示所有15篇文献

论文科学数据集

1. 湘东北横洞钴矿床白垩纪时期流体包裹体数据

2. 湖南东北部万古-黄金洞金矿区流体包裹体地球化学数据(2020)

数据来源:
国家青藏高原科学数据中心
PlumX Metrics
相关文献

 作者相关
 关键词相关
 参考文献相关

版权所有 ©2008 中国科学院文献情报中心 制作维护:中国科学院文献情报中心
地址:北京中关村北四环西路33号 邮政编码:100190 联系电话:(010)82627496 E-mail:cscd@mail.las.ac.cn 京ICP备05002861号-4 | 京公网安备11010802043238号