Metamorphically-induced rheological heterogeneity and the deep tremor source in subduction zones

Japan Geoscience Union Pub Date : 2017-03-10 DOI:10.1130/ABS/2017AM-299672

W. Behr, A. Kotowski, K. Ashley

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引用次数: 1

Abstract

We present data from an exhumed subduction interface that closely resembles the geologic environment of modern deep episodic tremor and slow slip (ETS). We focus on Eocene high pressure metamorphic rocks from the Cycladic Blueschist Unit on Syros Island in Greece. Metabasalts on Syros consist of intercalated blueschists and eclogites that record prograde deformation at 12-16 kbar (35-50 km) and 450-550 C-PT conditions that overlap with the deep ETS source in warm subduction zones such as Cascadia. Textural observations, Si-in-phengite concentrations, and quartz-inclusion-in-garnet barometry indicate that all of the mineral assemblages are in equilibrium, suggesting that variations in metamorphic facies reflect protolith bulk compositions rather than significant differences in PT conditions. Furthermore, field observations reveal that the coexistence of blueschists and eclogites sets up an important rheological contrast between the two metamorphic assemblages. The blueschists exhibit planar ductile deformation fabrics, whereas eclogites distributed within the blueschist matrix exhibit boudinage, brittle shear fracturing, and veins commonly filled with quartz and high pressure minerals. We interpret the high pressure brittle deformation and veining in eclogites to reflect fluid sealing and overpressurization: the high fluid-pressures drive brittle shear and extension in strong eclogitic layers that is dampened viscously into the weaker blueschist matrix. Our observations are inconsistent with models of deep ETS that invoke changes in rate-and-state friction parameters along a narrow planar fault zone, but are consistent with the inferred prominent role of high fluid pressures from geophysical and modeling studies. We suggest a conceptual model in which ETS is controlled by coupled brittle-viscous deformation in partially eclogitized basalts embedded within high-fluid-pressure patches along the plate interface.

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俯冲带变质流变非均质性与深部震颤源

我们提供了一个与现代深部幕式震颤和慢滑(ETS)的地质环境非常相似的俯冲界面的数据。本文研究了希腊锡罗斯岛基克拉迪蓝片岩单元始新世高压变质岩。Syros上的变质玄武岩由夹层蓝片岩和榴辉岩组成，记录了12-16 kbar (35-50 km)和450-550 C-PT条件下的递进变形，与Cascadia等温暖俯冲带的深部ETS源重叠。结构观测、硅辉石浓度和石榴石石英包裹体气压测量表明，所有矿物组合都处于平衡状态，表明变质相的变化反映了原岩体组成，而不是PT条件的显著差异。此外，野外观测表明，蓝片岩和榴辉岩的共存在两个变质组合之间建立了重要的流变学对比。蓝片岩表现为平面韧性变形组构，蓝片岩基质内榴辉岩表现为边界断裂、脆性剪切破碎、脉状充填石英和高压矿物。我们将榴辉岩中的高压脆性变形和脉纹解释为流体密封和超压的反映:高压驱动强榴辉岩层中的脆性剪切和伸展，这些剪切和伸展被粘滞到较弱的蓝片岩基质中。我们的观测结果与深层ETS的模型不一致，该模型利用了沿狭窄平面断裂带速率和状态摩擦参数的变化，但与地球物理和模拟研究推断的高流体压力的突出作用一致。我们提出了一个概念模型，其中ETS是由沿板块界面嵌入高流体压力斑块的部分榴辉化玄武岩的脆性-粘性耦合变形控制的。

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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Japan Geoscience Union

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