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瑞士采尔马特俯冲蛇纹岩中叶蛇纹石+水镁石与橄榄石反应的作用

The role of the antigorite + brucite to olivine reaction in subducted serpentinites (Zermatt, Switzerland).

作者信息

Kempf Elias D, Hermann Jörg, Reusser Eric, Baumgartner Lukas P, Lanari Pierre

机构信息

Institute of Geological Sciences, University of Bern, Baltzerstrasse 1+3, 3012 Bern, Switzerland.

Institute of Geochemistry and Petrology, ETH Zurich, Clausiusstrasse 25, 8092 Zurich, Switzerland.

出版信息

Swiss J Geosci. 2020;113(1):16. doi: 10.1186/s00015-020-00368-0. Epub 2020 Oct 26.

DOI:10.1186/s00015-020-00368-0
PMID:33132816
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7588401/
Abstract

Metamorphic olivine formed by the reaction of antigorite + brucite is widespread in serpentinites that crop out in glacier-polished outcrops at the Unterer Theodulglacier, Zermatt. Olivine overgrows a relic magnetite mesh texture formed during ocean floor serpentinization. Serpentinization is associated with rodingitisation of mafic dykes. Metamorphic olivine coexists with magnetite, shows high Mg# of 94-97 and low trace element contents. A notable exception is 4 µg/g Boron (> 10 times primitive mantle), introduced during seafloor alteration and retained in metamorphic olivine. Olivine incorporated 100-140 µg/g HO in Si-vacancies, providing evidence for low SiO-activity imposed by brucite during olivine growth. No signs for hydrogen loss or major and minor element diffusional equilibration are observed. The occurrence of olivine in patches within the serpentinite mimics the former heterogeneous distribution of brucite, whereas the network of olivine-bearing veins and shear zones document the pathways of the escaping fluid produced by the olivine forming reaction. Relic Cr-spinels have a high Cr# of 0.5 and the serpentinites display little or no clinopyroxene, indicating that they derive from hydrated harzburgitic mantle that underwent significant melt depletion. The enrichment of Mg and depletion of Si results in the formation of brucite during seafloor alteration, a pre-requisite for later subduction-related olivine formation and fluid liberation. The comparison of calculated bulk rock brucite contents in the Zermatt-Saas with average IODP serpentinites suggests a large variation in fluid release during olivine formation. Between 3.4 and 7.2 wt% HO is released depending on the magnetite content in fully serpentinized harzburgites (average oceanic serpentinites). Thermodynamic modelling indicates that the fluid release in Zermatt occurred between 480 °C and 550 °C at 2-2.5 GPa with the Mg# of olivine varying from 68 to 95. However, the majority of the fluid released from this reaction was produced within a narrow temperature field of < 30 °C, at higher pressures 2.5 GPa and temperatures 550-600 °C than commonly thought. Fluids derived from the antigorite + brucite reaction might thus trigger eclogite facies equilibration in associated metabasalts, meta-gabbros, meta-rodingites and meta-sediments in the area. This focused fluid release has the potential to trigger intermediate depths earthquakes at 60-80 km in subducted oceanic lithosphere.

摘要

由叶蛇纹石与水镁石反应形成的变质橄榄石广泛存在于采尔马特下特奥多尔冰川冰川打磨露头处露出的蛇纹岩中。橄榄石在海底蛇纹石化过程中形成的残余磁铁矿网格状结构上生长。蛇纹石化与镁铁质岩脉的透辉石化有关。变质橄榄石与磁铁矿共生,具有94 - 97的高镁#值和低微量元素含量。一个显著的例外是4μg/g的硼(比原始地幔高10倍以上),它在海底蚀变过程中被引入并保留在变质橄榄石中。橄榄石在硅空位中包含100 - 140μg/g的H₂O,这为橄榄石生长过程中水镁石施加的低SiO₂活性提供了证据。未观察到氢损失或主微量元素扩散平衡的迹象。蛇纹岩中橄榄石斑块的出现模拟了水镁石以前的不均匀分布,而含橄榄石的脉体和剪切带网络记录了橄榄石形成反应产生的逃逸流体的路径。残余的铬尖晶石具有0.5的高铬#值,蛇纹岩几乎没有或没有单斜辉石,这表明它们源自经历了显著熔体亏损的水化方辉橄榄岩地幔。镁的富集和硅的亏损导致海底蚀变过程中水镁石的形成,这是后来与俯冲相关的橄榄石形成和流体释放的先决条件。将采尔马特 - 萨斯地区计算的块状岩石水镁石含量与国际大洋发现计划(IODP)平均蛇纹岩进行比较表明,橄榄石形成过程中流体释放存在很大差异。根据完全蛇纹石化的方辉橄榄岩(平均大洋蛇纹岩)中的磁铁矿含量,释放出3.4至7.2 wt%的H₂O。热力学模拟表明,采尔马特的流体释放在2 - 2.5 GPa、480°C至550°C之间发生,橄榄石的镁#值在68至95之间变化。然而,该反应释放的大部分流体是在小于℃30的狭窄温度范围内产生的,压力高于2.5 GPa,温度在550 - 600°C之间,比通常认为的要高。因此,源自叶蛇纹石与水镁石反应的流体可能会触发该地区相关变玄武岩、变辉长岩、变透辉石岩和变沉积物中的榴辉岩相平衡。这种集中的流体释放有可能在俯冲的大洋岩石圈中60 - 80 km深处引发中等深度地震。

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