Quartz textures, trace elements, fluid inclusions, and in-situ oxygen isotopes from Aktogai porphyry Cu deposit, Kazakhstan

IF 2.7 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

American Mineralogist Pub Date : 2024-06-13 DOI:10.2138/am-2023-8931

Changhao Li, Ping Shen, R. Seltmann, Di Zhang, H. Pan, Eleonora Yusupovha Seitmuratova

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Abstract

The Paleozoic Aktogai Group in Kazakhstan ranks among the thirty largest porphyry Cu deposits globally. The Aktogai deposit is the largest one in the Aktogai Group and is characterized by intensive potassic alteration where the dominant orebody occurred. However, its mineralization processes remain unclear. Our investigation focused on the texture, trace elements, fluid inclusions, and in-situ oxygen isotopes of the quartz from the ore-related tonalite porphyry and associated potassic alteration at Aktogai to trace the deposit’s mineralization processes. Ti-in-quartz thermobarometry, fluid inclusion microthermometry, and geological characteristics indicate that the ore-related magma at Aktogai originated from a shallow magma chamber at ~1.9±0.5 kbar (~7.2±1.9 km) and intruded as the tonalite porphyry stock at ~1.7-2.4 km. The potassic alteration and associated Cu mineralization comprise five types of veins (A1, A2, B1, B2, and C) and two types of altered rocks (biotite and K-feldspar). Among them, nine types of hydrothermal quartz were identified from early to late: (1) VQA1 in A1 veins and RQbt in biotite altered rocks, (2) VQA2 in A2 veins and RQkfs in K-feldspar altered rocks, (3) VQB1 in B1 veins and VQB2E in B2 veins, and (4) quartz associated with Cu-Fe sulfides (VQB2L, VQBC, and VQC) in B and C veins. Titanium contents of the quartz decreased, while Al/Ti ratios increased from early to late. Fluid inclusion microthermometry and mineral thermometers reveal that VQA1, RQbt, and hydrothermal biotite formed under high-temperature (~470-560 °C) and ductile conditions. VQA2, RQkfs, VQB1, and hydrothermal K-feldspar formed during the transition stage from ductile to brittle, with temperatures of ~350-540 °C. The rapid decrease in pressure from lithostatic to hydrostatic pressure led to fluid boiling and minor involvement of meteoric water (~11-14 %) in the mineralizing fluid. Extensive recrystallization in VQA1 to VQB1 was associated with repeated cleavage and healing of the intrusion. With cooling, K-feldspar decomposition and hydrolysis increased. Fluid cooling and water-rock reactions resulted in the co-precipitation of Cu-Fe sulfides, white mica, chlorite, VQBC, and VQC, with temperatures of ~275-370 °C and brittle conditions. The Paleozoic Aktogai deposit exhibits formation depths and fluid evolution processes similar to Mesozoic and Cenozoic PCDs worldwide. The close association between Cu-Fe sulfides and later quartz formed under intermediate-temperature conditions at Aktogai implies that Cu-Fe sulfides are not precipitated during early high-temperature conditions in porphyry Cu deposits.

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哈萨克斯坦 Aktogai 斑岩铜矿床的石英纹理、微量元素、流体包裹体和原位氧同位素

哈萨克斯坦的古生代 Aktogai 组跻身全球三十个最大斑岩铜矿床之列。Aktogai 矿床是 Aktogai 组中最大的一个矿床，其主要矿体的特征是密集的钾盐蚀变。然而，其成矿过程仍不清楚。我们的研究主要集中在 Aktogai 与矿石相关的斑岩和相关钾盐蚀变中的石英的质地、微量元素、流体包裹体和原位氧同位素，以追溯该矿床的成矿过程。Ti-石英热压、流体包裹体微测温和地质特征表明，Aktogai 与矿石相关的岩浆源于~1.9±0.5 千巴（~7.2±1.9 千米）的浅岩浆腔，并在~1.7-2.4 千米处侵入成为辉绿斑岩。钾盐蚀变和相关的铜矿化包括五种类型的矿脉（A1、A2、B1、B2 和 C）和两种类型的蚀变岩（黑云母和 K 长石）。其中，从早期到晚期共发现了九种热液石英：（1）A1 矿脉中的 VQA1 和生物岩蚀变岩中的 RQbt；（2）A2 矿脉中的 VQA2 和 K 长石蚀变岩中的 RQkfs；（3）B1 矿脉中的 VQB1 和 B2 矿脉中的 VQB2E；（4）B 和 C 矿脉中与铜铁硫化物伴生的石英（VQB2L、VQBC 和 VQC）。石英中的钛含量从早期到晚期有所下降，而铝/钛比值则有所上升。流体包裹体微测温和矿物温度计显示，VQA1、RQbt和热液生物岩是在高温（约470-560 °C）和韧性条件下形成的。VQA2、RQkfs、VQB1和热液K长石形成于从韧性到脆性的过渡阶段，温度约为350-540 °C。压力从岩石静压迅速下降到静水压力，导致流体沸腾，成矿流体中含有少量陨水（约 11-14%）。VQA1至VQB1的广泛再结晶与侵入体的反复劈裂和愈合有关。随着冷却，钾长石的分解和水解增加。流体冷却和水岩反应导致铜铁硫化物、白云母、绿泥石、VQBC 和 VQC 的共沉淀，温度约为 275-370 °C，条件较脆。古生代Aktogai矿床的形成深度和流体演化过程与全球中生代和新生代PCD相似。Aktogai 矿床在中温条件下形成的铜铁硫化物与后期石英之间的密切联系意味着，铜铁硫化物并不是在斑岩铜矿床的早期高温条件下沉淀的。

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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.