钨的气态迁移与岩浆一热液成矿作用:实验研究及其成矿学意义
Gaseous transport and magmatic-hydrothermal mineralization of tungsten: Experimental study and its metallogenic implications
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文摘
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低密度的水热蒸气和超临界似气流体广泛存在于中地壳至地球表面的各种地质环境中,是成矿金属搬运和富集的重要介质。火山喷气凝结水、火山结壳和升华物、矿床的流体包裹体气相中均存在具有地质意义的W含量或含钨矿物,表明W同样可在含水气相中溶解和迁移。本文在350 ℃~400 ℃和压力为60~200 bar的实验条件下,测定了W0_3-H_20体系中W在水蒸气和似气流体中的溶解度,考察了水蒸气压力对W溶解度的影响。结果显示,W在水蒸气中的逸度(或含量)远高于依据无水体系中固体WO_3挥发性数据计算的蒸气压力,证明气态溶质W与溶剂水蒸气之间存在促进W溶解的水合作用。经热力学方法分析,认为可能形成了W0_3 ? nH_2O(g)形式的水合气体物种,其水合数n在350 ℃、370 ℃和400 ℃时分别为1.4、1.6和2.9。因此WO_3 ? 3H_20(g)或H_2WO_4 ? 2H_2O(g)及H_6WO_6(g)在温压较高的岩浆一热液或气成—热液成矿环境中(如斑岩系统)对W的气态迁移和浓集可能具有重要作用,而在温压较低的水热蒸气条件下,W的迁移形式可能以水合数较小的WO_3 ?H_20(g)(或H_2WO_4)和WO_3 ? 2H_20(g)(或H_2WO_4 ? H_20)物种为主,其含量或比例随水蒸气的压力而改变。某些斑岩型和脉型钨(钼)矿床常存在富气体包裹体,伴随酸性岩浆结晶出溶的以低盐度含水蒸气占优势的岩浆流体对斑岩系统中W、Mo在高温阶段的气态迁移和矿质在花岗岩体顶部和上覆岩层的聚集具有重要意义,之后蒸气冷凝可产生高盐度的含矿卤水或与渗流地下水混合形成低一中等盐度的成矿流体,流体的减压沸腾(相分离)和对围岩的交代蚀变导致W、Mo等金属在不同阶段和构造一岩性部位沉淀富集。 |
其他语种文摘
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Low-density hydrothermal vapor and vapor-like fluid occur widely in various geological environments from middle crust to terrestrial surface,and they are important agents for the transport and enrichment of ore-forming metals. Geologically significant tungsten contents or tungsten-bearing minerals are found in fumarolic condensates, sublimates and incrustations in volcanic areas and in vapor phase of fluid inclusion in ore deposits,showing tungsten can also be dissolved and transported in aqueous vapor. The solubility of tungsten in water vapor and vapor-like fluid in the W0_3-H_20 system was experimentally determined at temperatures of 350 °C ~ 400 °C and pressures of 60 ~200 bar, and whereby the influence of water vapor pressure on the solubility was investigated. The results indicate that the fugacity or contents of tungsten in water vapor are much higher than the vapor pressure of solid W0_3 calculated with the volatile data in water-free system,demonstrating hydration takes place between the gaseous solute of tungsten and the solvent of water vapor,which promotes the dissolution of tungsten in the vapor. Based on thermodynamic analysis,the solubility is attributed to the formation of hydrated gas species W0_3 ? nH_20 (g),and the hydration numbers are 1.4 at 350 °C,1.6 at 370 °C, and 2.9 at 400 °C, respectively. Thus, W0_3 ? 3H_20 (g) or H_2W0_4 ? 2H_20 (g) and H_6W0_6(g) is likely to play an important role in the gaseous transport and concentration of tungsten in the magmatic -hydrothermal or pneumatolytic -hydrothermal circumstances such as porphyry system under high temperature and pressure conditions,whereas the complexes with less hydration numbers, W0_3?H_20(g) (or H_2W0_4)and W0_3?2H_20(g) (or H_2W0_4? H_20),whose proportion varies with the water vapor pressure,will probably predominate in the hydrothermal vapor at lower temperatures and pressures. Vapor-rich inclusions occur commonly in some porphyry and vein-type W (-Mo) deposits, the magmatic fluid dominated by low-salinity aqueous vapor exsolved from acid magma during crystallization is mostly responsible for the gaseous transport and gathering of tungsten and molybdenum in the apical space of the granitic pluton and overlying wall rocks. Subsequently vapor can evolve into metal-bearing high-salinity liquid or brine through condensation or further produce low to moderate salinity mineralizing fluid by mixing with infiltrating groundwater. Fluid boiling or phase separation caused by pressure drop and replacement and alteration in wall rocks will result in the deposition and enrichment of W,Mo and other metals in different stages and structural-lithologic positions. |
来源
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地质科学
,2015,50(3):898-910 【核心库】
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DOI
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10.3969/j.issn.0563-5020.2015.03.015
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关键词
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钨
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含水蒸气
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溶解度
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水合物种
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气态迁移
;
斑岩型钨矿床
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地址
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中国科学院广州地球化学研究所, 中国科学院矿物学与成矿学重点实验室, 广州, 510640
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语种
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中文 |
文献类型
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研究性论文 |
ISSN
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0563-5020 |
学科
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地质学 |
基金
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国家自然科学基金项目
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国家“305”项
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文献收藏号
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CSCD:5471383
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参考文献 共
54
共3页
|
1.
迟实福. 阳储岭斑岩型钨钼矿床含矿斑岩及矿化特征.
长春地质学院学报,1985,15(1):37-58
|
被引
3
次
|
|
|
|
2.
巩小栋. 江西武宁县大湖塘钨矿成矿流体作用浅析.
矿物学报,2013,33(增刊):445-446
|
被引
1
次
|
|
|
|
3.
宋国学. 鸡头山Mo-W矿成矿流体包裹体特征及其对深部斑岩型矿化的指示.
矿物学报,2009,29(增刊):23-24
|
被引
2
次
|
|
|
|
4.
项新葵. 江西省大湖塘石门寺矿区超大型钨矿的发现及找矿意义.
资源调查与环境,2012,33(3):141-151
|
被引
30
次
|
|
|
|
5.
项新葵. 赣北石门寺超大型钨多金属矿床地质特征.
矿床地质,2013,32(6):1171-1187
|
被引
31
次
|
|
|
|
6.
杨永飞. 河南省栾川南泥湖斑岩型钼钨矿床流体包裹体研究.
岩石学报,2009,25(10):2550-2562
|
被引
37
次
|
|
|
|
7.
印贤波. 中国典型脉型钨、锡矿床和斑岩钼矿流体包裹体特征.
桂林理工大学学报,2011,31(4):524-532
|
被引
5
次
|
|
|
|
8.
张生. 成矿元素的气相迁移与实验研究.
地学前缘,2009,16(1):68-75
|
被引
6
次
|
|
|
|
9.
张生. 硼在共存水蒸气-富硼熔体之间分配的实验研究及其地质意义.
地球化学,2014,43(6):583-591
|
被引
5
次
|
|
|
|
10.
朱习君. 我国钨矿床研究现状.
四川地质学报,2011,31(4):428-434
|
被引
1
次
|
|
|
|
11.
Archibald S M. The stability of Au-chloride complexes in water vapor at elevated temperatures and pressures.
Geochimica et Cosmochimica Acta,2001,65(23):4413-4423
|
被引
27
次
|
|
|
|
12.
Archibald S M. An experimental study of the stability of copper chloride complexes in water vapor at elevated temperatures and pressures.
Geochimica et Cosmochimica Acta,2002,66(9):1611-1619
|
被引
27
次
|
|
|
|
13.
Bernard A. Condensation of volatile elements in high-temperature gases of Mount St.
Helens. Journal of Volcanology and Geothermal Research,1986,28(1/2):91-105
|
被引
2
次
|
|
|
|
14.
Bernard A. Volatile transport and deposition of Mo, W and Re in high temperature magmatic fluids.
Applied Geochemistry,1990,5(3):317-326
|
被引
22
次
|
|
|
|
15.
Burnham C W. Thermodynamic properties of water to 1,000 °C and 10,000 bars.
Geological Society of America Special Paper,1969,132:1-96
|
被引
2
次
|
|
|
|
16.
Candela P A. Model ore-metal partitioning from melts into vapor and vapor/brine mixtures.
Magmas, Fluids, and Ore Deposits,1995:101-128
|
被引
3
次
|
|
|
|
17.
Crerar D A. Chemical controls on solubility of ore-forming minerals in hydrothermal solutions.
The Canadian Mineralogist,1985,23(3):333-352
|
被引
4
次
|
|
|
|
18.
Crowe B M. Trace element geochemistry of volcanic gases and particles from 1983-1984 eruptive episodes of Kilauea volcano.
Journal of Geophysical Research,1987,92(B13):13708-13714
|
被引
2
次
|
|
|
|
19.
Davis W J. A fluid inclusion study of the porphyry-greisen,tungsten-molybdenum deposit at Mount Pleasant, New Brunswick, Canada.
Mineralium Deposita,1985,20(2):94-101
|
被引
3
次
|
|
|
|
20.
Drummond S E. Chemical evolution and mineral deposition in boiling hydrothermal systems.
Economic Geology,1985,80(1):126-147
|
被引
91
次
|
|
|
|
|