胶东金翅岭金矿床黄铁矿原位微量元素和硫同位素特征及对矿床成因的指示

朱照先; 赵新福; 林祖苇; 赵少瑞

doi:10.3799/dqkx.2019.057

胶东金翅岭金矿床黄铁矿原位微量元素和硫同位素特征及对矿床成因的指示

doi: 10.3799/dqkx.2019.057

中国地质大学资源学院, 湖北武汉 430074

基金项目:

科技部重点研发计划 2016YFC0600104

国家自然科学基金项目 41822203

国家自然科学基金项目 91514303

中央高校基本科研业务费专项资金 CUG140618

详细信息

作者简介:
朱照先(1994-), 男, 硕士研究生, 矿物学、岩石学、矿床学专业

通讯作者:
赵新福

中图分类号: P611
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出版历程
- 收稿日期: 2019-02-11
- 刊出日期: 2020-03-15

In Situ Trace Elements and Sulfur Isotope Analysis of Pyrite from Jinchiling Gold Deposit in the Jiaodong Region: Implications for Ore Genesis

School of Earth Resources, China University of Geosciences, Wuhan 430074, China

摘要

摘要: 位于招远-莱州金成矿带中西部的金翅岭金矿床是胶东地区典型的石英脉型高品位金矿，但其成矿流体来源和矿床成因一直存在争议.在详细的矿相学和黄铁矿显微结构研究基础上，利用LA-ICP-MS技术原位分析与成矿有关黄铁矿的微量元素特征，结合原位硫同位素分析成矿流体来源，为进一步认识矿床成因提供制约.成矿阶段的黄铁矿划分为2种类型（PyI和PyII），PyI产在石英-黄铁矿阶段，PyII产在石英-多金属硫化物阶段，伴随大量可见金的出现.根据背散射的核-边结构，PyII可细分为含有较多硫化物的核部PyIIa和表面较为干净的边部PyIIb，但二者有明显溶蚀结构.LA-ICP-MS分析结果显示PyI含有一定量的Au（< 0.015×10^-6~2.18×10^-6，均值0.62×10^-6）和As（78.98×10^-6~857×10^-6，均值542×10^-6），但Pb、Zn等其他元素含量较低.核部PyIIa和PyI微量元素分布特征较为相似，但Au（< 0.015×10^-6~0.59×10^-6，均值0.11×10^-6）和As（0.62×10^-6~198×10^-6，均值35.81×10^-6）的含量相对下降.边部PyIIb较核部PyIIa明显富集Au（< 0.015×10^-6~19.71×10^-6，均值5.91×10^-6）和As（399×10^-6~18 153×10^-6，均值6 412×10^-6），且Au与As表现出良好的正相关性.PyI和核部PyIIa原位δ³⁴S的分布范围较为一致，集中在3.0‰~4.9‰；而边部PyIIb的原位δ³⁴S值较高（5.2‰~6.6‰）.根据黄铁矿结构、微量元素和硫同位素特征，推断在主成矿期富³⁴S和富Au-As的热液流体加入形成了边部PyIIb且与核部的PyIIa发生了交代作用，同时大量可见金直接从热液中沉淀形成.该研究表明多期次富Au-As成矿流体的注入可能是高品位石英脉矿床形成的主要机制.
- 含As黄铁矿 /
- 黄铁矿结构 /
- 微量元素 /
- 激光原位硫同位素 /
- 金翅岭金矿床 /
- 地球化学 /
- 矿床学
Abstract: The Jinchiling gold deposit,located in the central and western part of Zhaoyuan-Laizhou gold metallogenic belt,is a typical lode gold deposit hosted in Late Jurassic Linglong granitoids in the Jiaodong region. The source of its ore-forming fluids and ore genesis,however,are still in debate. Based on the detailed study of mineralogy and microstructure of pyrite,trace elements and sulfur isotopes of gold bearing pyrite are analyzed by LA-(MC)-ICP-MS to constrain the source of ore-forming fluids and ore genesis. Two types (PyI and PyII) of gold-bearing pyrite can be identified. PyI is hosted in the quartz-pyrite stage,and PyII occurs in the quartz-polymetallic sulfide stage,which is associated with abundant visible gold. BSE images show that PyII commonly has core-rim texture. The PyIIa core contains many sulfide inclusions,whereas PyIIb rim is relatively clean. LA-ICP-MS analyses show that PyI contains medium contents of Au (< 0.015×10^-6-2.18×10^-6,mean 0.62×10^-6) and As (78.98×10^-6-857×10^-6,mean 542×10^-6),but very low contents of other metal elements (Pb and Zn). PyIIa has trace elements similar to those of PyI,but lower Au (< 0.015×10^-6-0.59×10^-6,mean 0.11×10^-6) and As (0.62×10^-6-198×10^-6,mean 35.81×10^-6). However,PyIIb has significantly high Au (< 0.015×10^-6-19.71×10^-6,mean 5.91×10^-6) and As (399×10^-6-18 153×10^-6,mean 6 412×10^-6),which shows a positive correlation. In addition,PyI and PyIIa have consistent in situ δ³⁴S values,ranging from 3.0‰ to 4.9‰,whereas PyIIb is higher (5.2‰-6.6‰). Our data thus suggest that a new pulse of Au-As enriched ore-formed fluids were input into the mineralizing vein system during quartz-polymetallic sulfide stage,inducing the metasomatism of PyIIa and deposition of abundant visible gold. Our study hence implies that multiple phases of ore-forming fluids may be involved in the formation of high-grade lode gold deposits in Jiaodong.
- As-bearing pyrite /
- pyrite texture /
- trace element /
- in situ sulfur isotope /
- Jinchiling gold deposit /
- geochemistry /
- ore deposit

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图 1 胶东区域地质图

据Yang et al.（2016）修改

Fig. 1. Simplified geological map of the Jiaodong region

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图 2 金翅岭地区地质特征简图（a）、金翅岭金矿矿区矿脉分布（b）和9B勘探线剖面图（c）

图a和c据杨柳（2014）修改；图b据杜高峰等（2012）修改

Fig. 2. Simplified geological map of the Jinchiling region (a), the distribution of ore-bodies (b) and cross section of No. 9B exploration line (c) in the Jinchiling gold deposit

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图 3 金翅岭矿床矿脉接触关系及典型热液蚀变

a.早期黄铁矿-石英穿插在钾化的围岩；b.产在基性脉岩中的黄铁绢英岩化被石英-黄铁矿脉和石英-多金属硫化物脉穿插；c.围岩发生钾化和黄铁绢英岩化，构造膨大的位置被石英-黄铁矿细脉和多金属硫化物脉充填；d.钾长石发生强烈的绢云母化；e.硅化、黄铁矿化，钾长石发生绢云母化；f.强烈的绢云母化、黄铁矿化及绿泥石化.Py.黄铁矿；Q.石英；Kfs.钾长石；Ser.绢云母；Chl.绿泥石；Gn.方铅矿；Sph.闪锌矿

Fig. 3. The cross cutting relationships of ore-bodies and typical hydrothermal alteration in the Jinchiling gold deposit

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图 4 金翅岭金矿床中可见金的典型镜下照片

a.产在PyII边缘的裂隙金及在方铅矿中的包体金；b.产在硫化物闪锌矿和黄铜矿边部的可见金以及在石英颗粒中的包体金；c.产在PyII颗粒之间的粒间金；d.产在PyII中的包体金和硫化物之间的粒间金. Py.黄铁矿；Au.金；Sph.闪锌矿；Ccp.黄铜矿；Gn.方铅矿；Q.石英

Fig. 4. Typical reflected-light micrographs of visible gold in the Jinchiling gold deposit

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图 5 不同成矿阶段典型载金黄铁矿的显微结构

a.产在石英-黄铁矿阶段的黄铁矿（PyI），表面见有石英或者方铅矿等包体，发育裂隙；b、c.石英-黄铁矿阶段的粗粒黄铁矿（PyI），背散射下较为均一；d~i.产在石英-多金属硫化物阶段的黄铁矿（PyII）.图e~f及h~i发育明显的核-边结构，核部PyIIa有较多的硫化物包体（方铅矿等）、石英包体或者孔洞，边部PyIIb发育一定的生长环带（图i），核-边之间可见微细包体金（图e）且边界清晰而不规则，具有溶蚀边现象. Py.黄铁矿；Gn.方铅矿；Sph.闪锌矿；Ccp.黄铜矿；Q.石英；Au.金

Fig. 5. Reflected-light and backscattered electron (BSE) micrographs of the typical gold-bearing pyrite in the different stages of mineralization

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图 6 金翅岭金矿床金成矿阶段黄铁矿微量元素的LA-ICP-MS剥蚀曲线

Fig. 6. Time resolved laser ablation depth profiles of representative grains of mineralization stage of pyrites from the Jinchiling gold deposit

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图 7 金翅岭金矿床金成矿阶段黄铁矿微量元素含量变化

Fig. 7. Comparative box plot of trace element concentrations in the mineralization stage of pyrites

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图 8 金翅岭金矿床金成矿阶段黄铁矿原位硫同位素值

Fig. 8. Frequency histogram of in situ sulfur isotope compositions for mineralization stage of pyrites from the Jinchiling gold deposit

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图 9 金翅岭金矿床金成矿阶段黄铁矿的微量元素相关性图解

灰色区域为元素检测限，部分未检测出的元素含量用检测限值的一半表示

Fig. 9. Binary plots of trace elements of pyrites in mineralization stage from the Jinchiling gold deposit

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表 1 金翅岭金矿床金成矿阶段黄铁矿LA-ICP-MS微量元素（10^-⁶）分析结果

Table 1. Trace element (10^-6) results for the mineralization stage of pyrites from Jinchiling gold deposit

样品编号	Py产状	Au	As	Ag	Co	Ni	Cu	Zn	Pb	Sb	Te
检测限		0.015	0.412	0.048	0.012	0.136	0.414	1.045	0.01	0.024	0.233
JCL-501	PyI	1.55	814	0.07	nd	—	1.20	—	3.76	0.55	nd
JCL-502	PyI	0.40	451	0.51	13.68	12.35	4.25	—	31.84	3.39	—
JCL-503	PyI	0.17	669	—	6.69	7.08	0.57	—	4.77	0.59	—
JCL-504	PyI	0.64	840	nd	0.61	0.18	—	—	0.07	nd	0.29
JCL-505	PyI	—	325	—	72.79	30.83	0.49	—	0.19	—	nd
JCL-506	PyI	2.18	857	—	0.05	—	1.02	—	12.01	0.99	—
JCL-507	PyI	—	301	—	22.01	3.36	—	—	0.30	0.04	—
JCL-508	PyI	0.03	78.98	0.15	12.56	10.53	0.74	58.58	7.00	0.08	1.20
JCL-2002	PyIIa	0.34	1.63	4.49	0.03	0.93	207	16 406	33.11	4.33	nd
JCL-2003	PyIIa	0.59	3.38	18.75	0.05	2.16	1709	16 847	48.63	2.82	—
JCL-2004	PyIIa	0.26	1.11	14.33	0.03	2.44	268	16 449	40.05	3.62	nd
JCL-2010	PyIIa	0.09	29.73	1.60	nd	nd	15.35	303	25.11	2.41	—
JCL-2012	PyIIa	0.16	0.62	14.69	—	0.27	52.89	4 053	46.83	6.33	nd
JCL-2013	PyIIa	0.33	64.70	6.04	nd	0.14	27.67	3 611	31.44	4.65	nd
JCL-2701	PyIIa	0.25	59.01	8.17	0.16	4.20	485	3 479	1167	0.82	3.48
JCL-2702	PyIIa	0.16	—	4.76	0.02	—	45.73	2 299	10.38	0.15	0.67
JCL-2704	PyIIa	0.29	3.77	5.72	0.05	0.13	3.61	6.05	23.03	1.58	5.40
JCL-2706	PyIIa	nd	8.67	nd	0.87	1.32	nd	—	0.20	—	nd
JCL-2707	PyIIa	0.02	10.68	nd	2.48	4.87	0.64	—	0.10	nd	nd
JCL-2708	PyIIa	—	154	—	0.31	0.67	—	—	1.13	0.04	—
JCL-2709	PyIIa	0.03	3.88	0.09	0.04	0.56	2.13	1.45	34.70	0.29	0.67
JCL-2710	PyIIa	nd	1.90	0.08	—	—	1.82	844	0.46	0.03	—
JCL-2803	PyIIa	nd	3.60	nd	0.17	2.27	—	1.16	0.09	—	—
JCL-2804	PyIIa	nd	127	0.18	nd	0.60	24.32	4.96	7.76	—	—
JCL-2805	PyIIa	nd	1.04	—	0.04	1.16	—	—	0.03	nd	—
JCL-2806	PyIIa	0.10	98.32	4.70	1.52	7.21	3.34	—	10 295	7.36	6.79
JCL-2807	PyIIa	0.03	95.19	0.37	1.60	2.70	2.95	—	13.30	1.13	1.54
JCL-2809	PyIIa	nd	198	0.006	0.16	0.25	—	—	nd	nd	0.40
JCL-2810	PyIIa	0.27	4.87	5.70	0.05	0.62	729	12 384	25.04	2.25	1.32
JCL-2811	PyIIa	nd	3.97	nd	nd	nd	nd	—	nd	—	nd
JCL-3501	PyIIa	0.03	13.73	0.84	0.56	26.71	81.29	1.67	1.68	0.05	nd
JCL-3504	PyIIa	0.04	41.66	1.85	0.19	76.35	14.10	1.86	10.92	0.17	0.72
JCL-3505	PyIIa	0.03	4.28	0.33	5.16	1.12	7.06	1758	1.83	0.27	3.62
JCL-3506	PyIIa	nd	37.00	nd	1.06	70.97	nd	3.37	0.07	nd	—
JCL-3507	PyIIa	0.11	9.61	0.40	0.69	46.54	0.90	—	1.64	0.06	0.54
JCL-3508	PyIIa	0.02	21.39	0.19	2.73	49.36	0.71	—	0.85	—	—
JCL-2001	PyIIb	0.14	1 192	nd	0.71	0.39	—	—	0.09	—	nd
JCL-2005	PyIIb	6.15	7 003	0.21	0.09	1.55	4.89	1.07	4.84	0.60	nd
JCL-2006	PyIIb	19.71	7 816	0.78	0.02	0.08	16.01	1.22	101	0.46	—
JCL-2007	PyIIb	0.57	2 167	0.35	0.12	2.22	3.29	111	19.88	2.93	—
JCL-2008	PyIIb	13.49	14 668	0.17	2.03	2.51	4.15	1.20	1.46	0.29	nd
JCL-2009	PyIIb	4.32	10 625	0.89	1.77	1.30	11.29	—	14.55	1.86	nd
JCL-2011	PyIIb	5.21	7 169	12.03	—	—	96.71	1 893	54.56	5.15	nd
JCL-2015	PyIIb	14.67	18 153	0.06	13.77	0.57	6.87	—	0.51	0.08	—
JCL-2705	PyIIb	0.70	468	0.20	0.57	0.15	2.80	3.49	26.66	0.58	1.10
JCL-3502	PyIIb	—	7 169	nd	0.03	0.31	—	—	0.03	nd	0.88
JCL-3503	PyIIb	0.08	875	0.30	0.03	1.94	1.23	2.32	7.30	0.41	66.34
注：“—”表示低于检测限；“nd”表示未测出.

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表 2 金翅岭金矿床金成矿阶段黄铁矿激光原位硫同位素分析结果

Table 2. Sulfur isotope data of mineralization stage of pyrites from the Jinchiling gold deposit

样品编号	成矿阶段	黄铁矿产状	δ³⁴S值（‰）
JCL-501	石英-黄铁矿	PyI	4.5
JCL-502	石英-黄铁矿	PyI	4.4
JCL-503	石英-黄铁矿	PyI	4.5
JCL-504	石英-黄铁矿	PyI	4.4
JCL-505	石英-黄铁矿	PyI	4.5
JCL-506	石英-黄铁矿	PyI	4.5
JCL-507	石英-黄铁矿	PyI	4.8
JCL-508	石英-黄铁矿	PyI	4.8
JCL-2007	多金属硫化物-核	PyIIa	4.9
JCL-2008	多金属硫化物-核	PyIIa	4.7
JCL-2009	多金属硫化物-核	PyIIa	4.4
JCL-2703	多金属硫化物-核	PyIIa	4.5
JCL-2704	多金属硫化物-核	PyIIa	4.5
JCL-2705	多金属硫化物-核	PyIIa	3.7
JCL-2801	多金属硫化物-核	PyIIa	3.7
JCL-2802	多金属硫化物-核	PyIIa	3.8
JCL-2803	多金属硫化物-核	PyIIa	3.0
JCL-2804	多金属硫化物-核	PyIIa	3.0
JCL-2805	多金属硫化物-核	PyIIa	3.3
JCL-2806	多金属硫化物-核	PyIIa	3.6
JCL-2807	多金属硫化物-核	PyIIa	4.2
JCL-2808	多金属硫化物-核	PyIIa	4.0
JCL-3501	多金属硫化物-核	PyIIa	4.3
JCL-3502	多金属硫化物-核	PyIIa	4.2
JCL-3503	多金属硫化物-核	PyIIa	3.5
JCL-3504	多金属硫化物-核	PyIIa	3.4
JCL-3505	多金属硫化物-核	PyIIa	4.0
JCL-2001	多金属硫化物-边	PyIIb	5.8
JCL-2002	多金属硫化物-边	PyIIb	5.6
JCL-2003	多金属硫化物-边	PyIIb	5.9
JCL-2004	多金属硫化物-边	PyIIb	6.6
JCL-2005	多金属硫化物-边	PyIIb	5.3
JCL-2006	多金属硫化物-边	PyIIb	5.4
JCL-2701	多金属硫化物-边	PyIIb	5.2
JCL-2702	多金属硫化物-边	PyIIb	5.3

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