Cold deep subduction of Indian continental crust and release of ultrahigh-pressure fluid during initial exhumation: Insights from coesite-bearing eclogite-vein systems in Kaghan Valley, Pakistan

IF 3.5 2区 地球科学 Q1 GEOLOGY Journal of Metamorphic Geology Pub Date : 2024-02-07 DOI:10.1111/jmg.12760
Shun Guo, Anping Chen, Xirun Cai, Yi Chen, Pan Tang, Qiuli Li
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Abstract

The ultrahigh-pressure (UHP) eclogites from the Kaghan Valley in Pakistan, which formed by the deep subduction of the Indian plate beneath the Asian plate in the Eocene, contain complex metamorphic vein systems (including both isolated veins and vein networks), with mineral assemblages of epidote + quartz + kyanite + phengite ± omphacite ± garnet. The investigations on the Kaghan UHP eclogite-vein systems provide important insights into the mechanism and timing of metamorphic dehydration, fluid flow, and fluid–rock interaction in the deeply subducted Indian continental slab as well as the chemical characteristics of slab-derived, aqueous fluids. Abundant lawsonite pseudomorphs, characterized by prismatic aggregates of epidote, kyanite, and quartz porphyroblasts, are first recognized in the Kaghan eclogites. This observation, in combination with the occurrence of coesite pseudomorphs in epidote porphyroblasts as well as the coexistence of epidote and coesite in the eclogite zircon, indicates the previous existence of UHP lawsonite in these eclogites. Petrological studies and phase equilibrium modelling reveal clockwise PT trajectories for the Kaghan eclogites that are featured by prograde vectors in lawsonite-stability regions with peak conditions of 3.0–3.4 GPa/650–690°C, followed by isothermal decompression and lawsonite breakdown under UHP conditions during the initial exhumation stage. The results of metamorphic evolution, together with in situ epidote and bulk Sr isotopic analyses, indicate that the fluids responsible for vein systems are most likely derived from the breakdown of UHP lawsonite in the eclogites. SIMS U–Pb dating of metamorphic zircons from the eclogites, integrated with the Raman analysis of inclusions in zircons, indicates that the UHP dehydration of eclogites occurred at 46.4 ± 1.2 and 46.8 ± 0.9 Ma. Analyses of hydrothermal zircons from the veins yielded slightly younger ages of 44.7 ± 1.0 and 44.9 ± 1.4 Ma, which represent the timing of fluid flow and/or vein crystallization during exhumation of the UHP rocks. Mass-balance calculation results, in combination with the vein compositions, show that the fluid flow and fluid-eclogite interaction led to the transfer of Si, Al, Ca, K, and incompatible trace elements from the eclogites into the fluids, from which the vein systems crystallized. This study indicates cold deep subduction of Indian continental crust along low geothermal gradients (6–7°C/km). The UHP fluid liberation and channelized fluid flow occurred during the initial exhumation of the cold Indian slab and are expected to induce the transfer of H2O and incompatible trace elements from the Indian slab to the Asian lithosphere, which potentially contributes to the formation of post-collisional magmas. Moreover, we suggest that metamorphic vein systems in UHP lawsonite eclogites offer important constraints on the occurrence and timing of fast slab exhumation in continental subduction-collision zones.

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印度大陆地壳的冷深俯冲和初始掘起过程中的超高压流体释放:巴基斯坦卡汗河谷含薏苡岩的蚀变岩脉系统的启示
巴基斯坦卡汗山谷的超高压(UHP)斜长岩是始新世印度板块深俯冲到亚洲板块之下形成的,其中含有复杂的变质岩脉系统(包括孤立的岩脉和岩脉网络),矿物组合为闪石+石英+黝帘石+黝帘石±辉石±石榴石。对卡格汉超高压蚀变岩脉系的研究为了解印度大陆板块深俯冲变质脱水、流体流动和流体-岩石相互作用的机制和时间,以及板块衍生水性流体的化学特征提供了重要信息。在卡汗斜长岩中首次发现了大量的洛桑石假形体,其特征是表土、闪长玢岩和石英斑岩的棱柱状集合体。这一观察结果,结合闪石斑岩中出现的薏苡岩假形体,以及斜长岩锆石中闪石和薏苡岩的共存,表明这些斜长岩中以前存在过超高压劳桑石。岩石学研究和相平衡建模揭示了卡汗斜长岩的顺时针 P-T 轨迹,该轨迹的特点是在峰值条件为 3.0-3.4 GPa/650-690°C 的 lawsonite 稳定区域内的顺行矢量,随后是等温减压,以及在最初的掘起阶段超高压条件下的 lawsonite 分解。变质演化的结果以及原位表土和大块锶同位素分析表明,造成矿脉系统的流体很可能来自于辉绿岩中超高压罗宋岩的分解。对斜长岩中的变质锆石进行的 SIMS U-Pb 测定与锆石中包裹体的拉曼分析相结合,表明斜长岩的超高压脱水发生在 46.4 ± 1.2 Ma 和 46.8 ± 0.9 Ma。对矿脉中热液锆石的分析得出的年龄略小,分别为 44.7 ± 1.0 Ma 和 44.9 ± 1.4 Ma,这代表了超高压岩石在出露过程中流体流动和/或矿脉结晶的时间。质量平衡计算结果与岩脉成分相结合表明,流体流动和流体与斜长岩的相互作用导致硅、铝、钙、钾和不相容微量元素从斜长岩转移到流体中,而岩脉系统就是从流体中结晶出来的。这项研究表明,印度大陆地壳沿着低地热梯度(6-7°C/km)进行冷深俯冲。超高压流体的释放和渠化流体流发生在冷印度板坯的初始掘出过程中,预计会诱发H2O和不相容微量元素从印度板坯向亚洲岩石圈的转移,这可能有助于碰撞后岩浆的形成。此外,我们还提出,超高压 lawsonite蚀变岩中的变质岩脉系统为大陆俯冲碰撞带快速板坯排挤的发生和时间提供了重要的制约因素。
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来源期刊
CiteScore
6.60
自引率
11.80%
发文量
57
审稿时长
6-12 weeks
期刊介绍: The journal, which is published nine times a year, encompasses the entire range of metamorphic studies, from the scale of the individual crystal to that of lithospheric plates, including regional studies of metamorphic terranes, modelling of metamorphic processes, microstructural and deformation studies in relation to metamorphism, geochronology and geochemistry in metamorphic systems, the experimental study of metamorphic reactions, properties of metamorphic minerals and rocks and the economic aspects of metamorphic terranes.
期刊最新文献
Issue Information Zircon Coupled Dissolution–Precipitation Replacement During Melt–Rock Interaction Modifies Chemical Signatures Resulting in Misleading Ages Pressure–Temperature–Time Evolution of a Polymetamorphic Paragneiss With Pseudomorphs After Jadeite From the HP–UHP Gneiss-Eclogite Unit of the Variscan Erzgebirge Crystalline Complex, Germany Issue Information Experimental Replacement of Zircon by Melt-Mediated Coupled Dissolution-Precipitation Causes Dispersion in U–Pb Ages
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