Ore-forming fluid evolution and metal precipitation mechanism at Xierqu Fe–Cu deposit, East Tianshan (NW China): Integrated constraints from fluid inclusions and garnet geochemistry

IF 3.6 2区地球科学 Q1 GEOLOGY

Ore Geology Reviews Pub Date : 2025-08-19 DOI:10.1016/j.oregeorev.2025.106843

Xihui Cheng , Mingxing Ling , Li Yun , Pinghui Liu , Jiao Zhao , Fuquan Yang

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Abstract

The newly discovered Xierqu deposit signifies a Devonian Fe–Cu mineralization event, challenging the Carboniferous-dominated submarine volcanic-hosted Fe(Cu) metallogenic model in East Tianshan, NW China. Its ore-forming fluid evolution and metal precipitation mechanisms require clarification. Mineralization is spatially confined to skarn at the quartz diorite porphyry-Dananhu Formation limestone interface. Four ore-forming stages are identified. Fluid inclusion (FI) petrography reveals three assemblages: liquid-dominated (L-type), vapor-dominated (V-type), and multiphase with daughter minerals (S-type). The prograde skarn stage contains high-temperature (343–481°C), variable salinity L-type (6.3–14.2 wt% NaCl eqv.) and very high-salinity S-type (39.8–43.6 wt% NaCl eqv. at 449–491°C) FIs. The retrograde epidote stage shows L-type and V-type FIs with moderate temperatures (L-type: 304–351°C, 5.2–7.7 wt%; V-type: 285–353°C, 5.7–9.1 wt% NaCl eqv.). A significant cooling and dilution trend characterizes the quartz-sulfide stage, evidenced by primary L-type (Th 246–304°C; salinity 3.2–6.7 wt%) and V-type (Th 241–324°C; salinity 3.1–6.3 wt%) FIs in quartz. Calcite stage FIs (L-type: Th 132–201°C, salinity 1.1–2.6 wt%; V-type: Th 150–213°C, salinity 1.4–2.7 wt%) confirm substantial external fluid influx. Pronounced Fe/(Na + K) ratio variations from early high-salinity to retrograde medium–low-salinity fluids indicate significant Fe precipitation. The maximum Cu/(Na + K) ratio occurs near 470°C in prograde skarn; subsequent cooling to ∼ 250°C in the quartz-sulfide stage causes a dramatic ratio drop, triggering chalcopyrite precipitation. Combined microthermometry and Laser-ablation inductively coupled plasma-mass spectrometry (LA–ICP–MS) data reveal Fe precipitation resulted from destabilization of Fe-chloride complexes via hydrothermal cooling and boiling. Cu mineralization coincided with concurrent cooling and fluid mixing. High U contents and HREE-enriched patterns in Grt-1A/B dark zones indicate near-neutral pH and low fO₂ fluids. An expanded Y/Ho range and LREE enrichment in Grt-2 demonstrate mixing between evolved magmatic fluid and an external fluid with mildly acidic pH and elevated oxygen fugacity. This study advances understanding of Devonian Fe–Cu mineralization in the East Tianshan.

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东天山下二渠铁铜矿床成矿流体演化与金属沉淀机制：流体包裹体与石榴石地球化学的综合约束

新发现的下二曲矿床标志着泥盆系铁（铜）成矿事件，对东天山石炭纪海底火山岩为主的铁（铜）成矿模式提出了挑战。成矿流体演化和金属沉淀机制有待进一步研究。成矿空间上局限于石英闪长斑岩—大南湖组灰岩界面处的矽卡岩。确定了四个成矿阶段。流体包裹体（FI）岩石学显示了三种组合：液体为主（l型）、蒸汽为主（v型）和多相含子矿物（s型）。进阶西卡岩阶段包括高温（343 ~ 481℃）、变盐度l型（6.3 ~ 14.2 wt% NaCl eqv）和高盐度s型（39.8 ~ 43.6 wt% NaCl eqv）。（449-491°C）。逆行绿绿岩阶段为l型和v型fi，温度适中（l型：304 ~ 351℃，5.2 ~ 7.7 wt%； v型：285 ~ 353℃，5.7 ~ 9.1 wt% NaCl eqv）。石英-硫化物阶段具有明显的冷却和稀释趋势，主要表现为石英中的l型（Th 241 ~ 324℃，盐度为3.2 ~ 6.7 wt%）和v型（Th 241 ~ 324℃，盐度为3.1 ~ 6.3 wt%）矿物矿物。方解石阶段FIs （l型：温度为132-201°C，盐度为1.1-2.6 wt%； v型：温度为150-213°C，盐度为1.4-2.7 wt%）证实大量外部流体流入。Fe/(Na + K)比值从早期高盐度流体到中低盐度逆行流体的显著变化表明有明显的铁沉淀。在顺行矽卡岩中，Cu/(Na + K)比值在470℃附近最大；随后在石英-硫化物阶段冷却至~ 250℃，导致比值急剧下降，引发黄铜矿析出。结合显微测温和激光烧蚀电感耦合等离子体质谱（LA-ICP-MS）数据表明，铁沉淀是由水热冷却和沸腾使氯化铁络合物失稳引起的。铜成矿与冷却和流体混合同时发生。Grt-1A/B暗区U含量高，富3模式表明pH接近中性，fO2含量低。Grt-2的Y/Ho范围扩大，LREE富集，表明演化的岩浆流体与pH值偏酸性、氧逸度升高的外部流体混合。该研究有助于对东天山泥盆系铁铜成矿作用的认识。

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来源期刊

Ore Geology Reviews 地学-地质学

CiteScore

6.50

自引率

27.30%

发文量

546

审稿时长

22.9 weeks

期刊介绍： Ore Geology Reviews aims to familiarize all earth scientists with recent advances in a number of interconnected disciplines related to the study of, and search for, ore deposits. The reviews range from brief to longer contributions, but the journal preferentially publishes manuscripts that fill the niche between the commonly shorter journal articles and the comprehensive book coverages, and thus has a special appeal to many authors and readers.