四川乌斯河铅锌矿床成矿流体特征及TSR作用初探

熊索菲; 姚书振; 宫勇军; 谭满堂; 曾国平; 王伟

doi:10.3799/dqkx.2016.008

四川乌斯河铅锌矿床成矿流体特征及TSR作用初探

doi: 10.3799/dqkx.2016.008

1.
中国地质大学资源学院，湖北武汉 430074
2.
中国地质大学紧缺矿产资源勘查协同创新中心，湖北武汉 430074
3.
中国地质调查局武汉地质调查中心，湖北武汉 430200

基金项目:

中国地质调查局项目 12120113094200

详细信息

作者简介:
熊索菲(1986-),女,博士,矿物学、岩石学、矿床学专业.E-mail: sophie_0913@foxmail.com

通讯作者:
姚书振, E-mail: szyao@cug.edu.cn

中图分类号: P588.12;P595;P597
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出版历程
- 收稿日期: 2015-09-29
- 刊出日期: 2016-01-15

Ore-Forming Fluid and Thermochemical Sulfate Reduction in the Wusihe Lead-Zinc Deposit, Sichuan Province, China

1.
Faculty of Earth Resources, China University of Geosciences, Wuhan 430074, China
2.
Collaborative Innovation Center for Exploration of Strategic Mineral Resources, China University of Geosciences, Wuhan 430074, China
3.
Wuhan Center, China Geological Survey, Wuhan 430200, China

摘要

摘要: 四川乌斯河铅锌矿床是赋存于震旦系灯影组白云岩中的大型铅锌矿床.本次研究结合最新的野外地质现象发现该矿床除存在前人所强调的沉积成矿作用以外，热液成矿作用非常明显.对该矿床流体包裹体进行细致的岩相学、显微测温和激光拉曼研究，揭示成矿流体特征，并探讨成矿机制.研究结果显示该矿床包裹体类型较为单一，以气液两相为主，均一温度主要集中于120~260 ℃，平均盐度为10.0% NaCl eqv，压力为32~68 MPa，成矿流体为中-低温、中等盐度.激光拉曼测试显示包裹体气相成分含有CH₄、H₂S、C₂H₆、C₂H₂、N₂和NH₃，为多元共存的流体体系.在热驱动力下(120~260 ℃)，流体混合作用提供了物质基础(SO₄^2-)、催化剂(Mg²⁺)和还原剂(有机质、CH₄和H₂S)促使硫酸盐热化学还原反应(TSR)启动.TSR反应过程中流体pH发生变化，进一步促进了金属硫化物沉淀.
- 成矿流体 /
- 流体包裹体 /
- 铅锌矿 /
- TSR作用 /
- 地球化学
Abstract: The Wusihe lead-zinc deposit, hosted in the Dengying Formation, is a large lead-zinc deposit in the Sichuan Province, China. The previous research noted the Wusihe deposit was classified as a sediment-hosted stratiform lead-zinc deposit. However, our field survey result suggests that hydrothermal ore-forming processes are crucial to lead-zinc mineralization. In this paper, we present a detailed petrographic, microthermometric and laser Raman spectroscopy study of fluid inclusions from the Wusihe deposit reveals the characteristics of ore-forming fluids and mineralization mechanism. Primary fluid inclusions (FIs) in dolomite, quartz, calcite, fluorite and sphalerite are mainly two phases (L+V type). Microthermometric data show the homogenization temperatures range from 120 ℃ to 260 ℃, and the average of salinity is 10.0% NaCl eqv. The estimated trapping pressures are 32 MPa to 68 MPa. The laser Raman spectroscopy shows that the gas components have a certain amount of CH₄, H₂S, C₂H₆, C₂H₂, N₂ and NH₃. The mixed ore-forming fluids offer heat, SO₄^2-, and Mg²⁺ to provoke the thermochemical sulfate reduction (TSR). The TSR could be a key factor for sulfur source and H⁺. The change of pH value leads to the precipitation of metallogenic elements.
- ore-forming fluid /
- fluid inclusions /
- lead-zinc deposit /
- thermochemical sulfate reduction /
- geochemistry.

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图 1 扬子地块西缘铅锌矿床分布略图

据成都地质矿产研究所(2003).云贵川渝1:250万地质图，略有简化

Fig. 1. Regional geological and distribution map of lead-zinc deposits on western margin of the Yangtze block

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图 2 乌斯河铅锌矿床地质简图

1.第四系；2.奥陶系－二叠系碎屑岩、碳酸盐岩；3.寒武系碎屑岩、碳酸盐岩；4.上震旦统观音崖组碎屑岩－灯影组白云岩；5.南华系苏雄组陆相火山岩、碎屑岩；6.中元古界峨边群变质岩；7.铅锌矿(化)层；8.断层；9.地质界线；10.河流；11.晋宁期花岗岩；据四川地矿局207地质队(2006) 略有修改

Fig. 2. Geological sketch of the Wusihe lead-zinc deposit

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图 3 不同成矿期成矿阶段野外照片

a.沉积期形成的纹层-条带状矿石；b.热液期多金属硫化物将沉积期形成的纹层状矿石角砾胶结；c.热液期第Ⅱ阶段形成的矿石被第Ⅲ阶段的方铅矿脉切穿；d.第Ⅲ阶段切层和顺层的方铅矿脉；e.热液期第Ⅱ、Ⅲ阶段形成的矿脉破碎后，呈角砾状，被第Ⅳ阶段沥青+方解石+石英胶结; f.热液期第Ⅳ阶段的沥青粗脉；Bit.沥青；Cc.方解石；Dol.白云石；Gn.方铅矿；Py.黄铁矿；Q.石英；Sp.闪锌矿

Fig. 3. Photographs showing different stages of the Wusihe deposit

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图 4 乌斯河矿床流体包裹体特征

a.热液期第Ⅰ阶段的闪锌矿和白云石中包裹体发育；b.热液期第Ⅱ阶段，浅黄-浅黄白相间闪锌矿发育生长环带，L+V型原生流体包裹体沿生长环带发育，次生包裹体呈线状切穿生长环带; c.热液期第Ⅲ阶段，红棕色闪锌矿内部发育有定向排列的L+V型流体包裹体；d.热液期第Ⅲ阶段方解石内两种成分不同的L+V型；e.热液期第Ⅲ阶段，淡紫色萤石内的L+V型流体包裹体，包裹体颜色为无色透明，边缘清晰；f.热液期第Ⅱ阶段石英中的V型流体包裹体

Fig. 4. Photomicrographs of fluid inclusions in the Wusihe deposit

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图 5 流体包裹体的均一温度-盐度直方图

a.沉积期，闪锌矿、白云石和石英中流体包裹体均一温度直方图；b.沉积期流体包裹体盐度直方图；c.热液期第Ⅰ成矿阶段，闪锌矿、白云石和石英中流体包裹体均一温度直方图；d.热液期第Ⅰ成矿阶段流体包裹体盐度直方图；e.热液期第Ⅱ成矿阶段，闪锌矿和石英中流体包裹体均一温度直方图；f.热液期第Ⅱ成矿阶段流体包裹体盐度直方图；g.热液期第Ⅲ成矿阶段，闪锌矿、方解石、萤石和石英中流体包裹体均一温度直方图；h.热液期第Ⅲ成矿阶段盐度直方图; i.热液期第Ⅳ成矿阶段，方解石和石英中流体包裹体均一温度直方图；j.热液期第Ⅳ成矿阶段流体包裹体盐度直方图

Fig. 5. Histograms of microthermometric and salinity for each stage

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图 6 乌斯河矿床包裹体激光拉曼图谱

a.闪锌矿内包裹体，含有CH₄和N₂，其中CH₄特征峰值为2 914.8 cm^-1，N₂特征峰值为2 327.5 cm^-1；b.闪锌矿内包裹体，含有C₂H₂和H₂O，其中C₂H₂特征峰值为1 961.6 cm^-1，H₂O特征峰值为3 386.9 cm^-1；c.石英内包裹体，含有CH₄和H₂O，其中CH₄特征峰值为2 914.7 cm^-1，H₂O特征峰值为3 544.3 cm^-1；d.石英内包裹体，含有NH₃和H₂O，其中NH₃特征峰值为3 339.7 cm^-1，H₂O特征峰值为3 618.2 cm^-1；e.闪锌矿内包裹体，含H₂S，特征峰值为2 614.4 cm^-1；f.白云石内包裹体，含有C₂H₆，其中C₂H₆特征峰值为2 975.2 cm^-1

Fig. 6. Raman spectra of fluid inclusions from the Wusihe deposit

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图 7 乌斯河矿床成矿压力估算

a.热液期第Ⅰ成矿阶段，闪锌矿包裹体的等容线分布在ρ=0.90和ρ=0.79之间的红色区域，结合平均温度250 ℃投影，获得的最小捕获压力为32 MPa；b.热液期第Ⅱ成矿阶段，闪锌矿包裹体的等容线分布在ρ=0.97和ρ=0.87之间的红色区域，结合平均温度207 ℃投影，获得的最小捕获压力为58 MPa；c.热液期第Ⅲ成矿阶段，闪锌矿包裹体的等容线分布在ρ=1.07和ρ=0.92之间的红色区域，结合平均温度172 ℃投影，获得的最小捕获压力为68 MPa

Fig. 7. Estimation for the metallogenic pressure of Wusihe deposit

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表 1 各成矿阶段流体包裹体显微测温数据

Table 1. Summary of fluid inclusion data from each stage of mineralization

成矿期成矿阶段(测试个数)		寄主矿物	初熔温度(℃)	均一温度(℃)	冰点(℃)	盐度(% NaCl eqv)	密度(g/cm³)
沉积期 n=36		白云石	-33.8	181~221	-6.5~-2.9	3.6~9.9	0.90~0.97
		闪锌矿	-21.6~-19.1	132~223	-10.8~-4.1	6.5~14.8	0.91~1.02
		石英		191~194	/	/	/
热液期	Ⅰ n=73	白云石	-41.6	216~266	-8.7~-7.2	10.7~12.5	0.87~0.93
		石英	-16.3	203~291	-18.9~-4.2	6.7~21.6	0.84~0.97
		闪锌矿	-23.8~-17.8	217~282	-10.3~-3.3	5.4~14.3	0.79~0.90
	Ⅱ n=79	石英		178~269	-9.0~-2.5	4.2~12.9	0.85~0.96
	Ⅱ n=79	闪锌矿	-25.1~-19.7	168~238	-9.1~-4.3	6.9~13.0	0.87~0.98
	Ⅲ n=65	萤石		159~227	-9.2~-3.9	6.3~14.0	0.94~1.00
		闪锌矿	-25.4~-20.6	133~211	-19.2~-4.8	7.6~21.8	0.92~1.07
		方解石		208~218	-14.5~-10.1	14.0~18.2	0.96~0.99
		石英		154~229	-8.2~-5.0	7.9~11.9	0.91~0.97
	3Ⅳ n=35	石英	-18.1	141~199	-10.4~-1.6	2.7~14.4	0.90~1.01
	3Ⅳ n=35	方解石	-22.4	102~197	-13.5~-3.0	5.0~15.2	0.89~1.02

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表 2 热液期流体包裹体激光拉曼测试结果

Table 2. Raman spectra of fluid inclusions from the hydrothermal stage

序号	成矿阶段	主矿物	包裹体类型	测试对象	成分	拉曼特征峰(cm^-1)	采样位置
1	第Ⅰ阶段	石英	L+V型	气相	N₂	2 339.4	角砾岩带
2	第Ⅰ阶段	石英	L+V型	气相	C₂H₆	2 974.0	角砾岩带
3	第Ⅰ阶段	白云石	L+V型	气相	C₂H₆	2 975.2	麦地坪上矿段
4	第Ⅰ阶段	白云石	L+V型	气相	CH₄	2 912.3	麦地坪上矿段
5	第Ⅰ阶段	白云石	L+V型	气相	N₂	2 330.5	麦地坪上矿段
6	第Ⅰ阶段	闪锌矿	L+V型	气相	CH₄和N₂	2 914.8和2 327.5	麦地坪上矿段
7	第Ⅱ阶段	闪锌矿	L+V型	气相	C₂H₂和H₂O	1 961.6和3 386.9	麦地坪上矿段
8	第Ⅱ阶段	闪锌矿	L+V型	液相	H₂O	3 443.3	麦地坪上矿段
9	第Ⅱ阶段	闪锌矿	L+V型	气相	N₂	2 329.2	麦地坪上矿段
10	第Ⅱ阶段	石英	L+V型	气相	CH₄和H₂O	2 914.7和3 544.3	麦地坪上矿段
11	第Ⅱ阶段	石英	L+V型	气相	NH₃和H₂O	3 339.7和3 618.2	麦地坪上矿段
12	第Ⅲ阶段	闪锌矿	L+V型	气相	H₂S	2 614.4	麦地坪上矿段
13	第Ⅲ阶段	闪锌矿	L+V型	气相	CH₄	2 914.7	麦地坪下矿段
14	第Ⅲ阶段	石英	V型	气相	CH₄	2 915.9	麦地坪下矿段

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表 3 乌斯河铅锌矿床金属硫化物硫同位素

Table 3. δ³⁴S values of sulfides in the Wusihe lead-zinc deposit

样品编号	矿物	δ³⁴SCDT(‰)	资料来源	送样号	矿物	δ³⁴SCDT (‰)	资料来源
Hx001	闪锌矿	+14.83		Hx003	方铅矿	+14.41
Hx003	闪锌矿	+14.53		Hx006	方铅矿	+13.99
Hx005	闪锌矿	+12.65		Hx015	方铅矿	+13.92
Hx006	闪锌矿	+14.82		Hx001	方铅矿	+11.78	林方成，2005b
Hx052	闪锌矿	+12.82		Hx044	方铅矿	+12.07
Hx044	闪锌矿	+10.48	林方成，2005b	Hx052	方铅矿	+8.85
Hx055	闪锌矿	+10.43		Hx055	方铅矿	+11.20
Hx020	闪锌矿	+8.52		Wh-1	闪锌矿	+8.61
Hx021	闪锌矿	+7.48		Wh-2	闪锌矿	+14.05	李同柱等，2007
Hx025	闪锌矿	+13.13		Wh-3	闪锌矿	+13.75
Hx041	黄铁矿	+15.51

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