Mechanisms of fluid degassing in shallow magma chambers control the formation of porphyry deposits

IF 2.7 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

American Mineralogist Pub Date : 2024-03-28 DOI:10.2138/am-2023-9091

Zixuan Wang, Yuanchuan Zheng, Bo Xu, Zengqian Hou, Ya-hui Shen, Aiping Zhang, Lu Wang, Chang-da Wu, Qingfeng Guo

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Abstract

Magmatic fluid degassing within shallow magma chambers underneath the ore bodies is critical to the formation of porphyry Cu-Au deposits (PCDs). Yet, it remains unclear that how the ways of fluid degassing influence on the development of PCDs. Here, geochemical data of apatite, amphibole and plagioclase from ore-forming and coeval barren porphyries have been analyzed in Sanjiang metallogenic belt, China. The ore-forming porphyries normally exhibit high and wide XF/XCl (31.76-548.12) and XF/XOH (0.779-7.370) ratios of apatites, which are evidently higher than those of the barren porphyries (XF/XCl of 1.03-26.58; XF/XOH of 0.686-3.602). Combined with the continuous variation features of Cl/OH ratios and H2O contents of melts calculated by amphiboles, as well as fluid migration models, we constrained the mechanisms of fluid degassing within shallow magma chambers underneath PCDs. There are three different ways of fluid degassing, while only fluid degassing via fluid channel stage can migrate and focus the metal-rich fluids effectively, conducive to the development of PCDs. The mechanisms of magmatic fluid degassing processes are further controlled by the storage depths of magma chambers and initial H2O contents of the magmas revealed by the compositions of amphibole, plagioclase and thermodynamic modelling. Magmas, with shallower storage depth and higher initial H2O content, are more likely to experience extensive and focused fluid degassing, leading to the generation of PCDs. This study demonstrates the potential utility of integrated mineral analyses, the thermodynamic modelling for investigating the mechanisms of magmatic fluid degassing in porphyry systems, as well as identifying prospective buried PCDs.

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浅岩浆室流体脱气机制控制斑岩矿床的形成

矿体下方浅岩浆腔内的岩浆流体脱气对斑岩型铜金矿床（PCD）的形成至关重要。然而，流体脱气的方式如何影响斑岩型铜金矿床的形成仍不清楚。本文分析了中国三江成矿带成矿斑岩和共生贫瘠斑岩中磷灰石、闪石和斜长石的地球化学数据。成矿斑岩中磷灰石的XF/XCl（31.76-548.12）和XF/XOH（0.779-7.370）比值高且宽，明显高于贫瘠斑岩（XF/XCl为1.03-26.58；XF/XOH为0.686-3.602）。结合闪长岩计算的熔体中Cl/OH比值和H2O含量的连续变化特征，以及流体迁移模型，我们对PCD地下浅岩浆腔内流体脱气机制进行了约束。流体脱气有三种不同的方式，而只有通过流体通道阶段的流体脱气才能有效地迁移和集中富含金属的流体，有利于PCD的发育。岩浆流体脱气过程的机制还受岩浆室的储存深度和岩浆中闪石、斜长石成分及热力学模型所揭示的初始 H2O 含量的控制。储存深度较浅、初始 H2O 含量较高的岩浆更有可能经历广泛而集中的流体脱气，从而产生 PCD。这项研究证明了综合矿物分析和热力学建模在研究斑岩系统岩浆流体脱气机制以及确定潜在埋藏的多孔质结核方面的潜在用途。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

American Mineralogist 地学-地球化学与地球物理

CiteScore

5.20

自引率

9.70%

发文量

276

审稿时长

1 months

期刊介绍： American Mineralogist: Journal of Earth and Planetary Materials (Am Min), is the flagship journal of the Mineralogical Society of America (MSA), continuously published since 1916. Am Min is home to some of the most important advances in the Earth Sciences. Our mission is a continuance of this heritage: to provide readers with reports on original scientific research, both fundamental and applied, with far reaching implications and far ranging appeal. Topics of interest cover all aspects of planetary evolution, and biological and atmospheric processes mediated by solid-state phenomena. These include, but are not limited to, mineralogy and crystallography, high- and low-temperature geochemistry, petrology, geofluids, bio-geochemistry, bio-mineralogy, synthetic materials of relevance to the Earth and planetary sciences, and breakthroughs in analytical methods of any of the aforementioned.