Core surprise: What's inside a plate boundary?

JULY 2020 Pub Date : 2020-07-01 DOI:10.1144/geosci2020-092

Lucy McKay, Z. Shipton, R. Lunn

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Abstract

Despite the fact that 90% of global seismicity occurs at plate boundary faults, our understanding of their internal structure is lacking. It’s not easy to see inside a plate boundary fault – typically composed of a high-strain fault core surrounded by a fractured damage zone – and when we can, it often requires expensive drilling projects that yield limited information on the internal structure of the whole fault. Understanding the internal structure of large faults is crucial, because their chemical and mechanical properties control how and where earthquakes rupture, nucleate and propagate. This in turn limits the size of the earthquake or the amount of radiated seismic energy, and consequently the severity of surface damage. The 1999 magnitude 7.7 earthquake along the Chelungpu plate boundary fault, for example – the second deadliest earthquake in Taiwan’s recorded history – saw significant variations in slip and ground motion at different locations along the fault which resulted in large local variations in casualties and damage. Subsequent field investigations related these variations to changes in the fault’s structure (i.e., clay width, geometry), which in turn controlled how the fault moved.

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核心惊喜:板块边界里面有什么?

尽管90%的全球地震活动发生在板块边界断层，但我们对其内部结构的了解还很缺乏。观察板块边界断层的内部并不容易——通常是由一个被断裂破坏带包围的高应变断层核心组成——即使我们能看到，也往往需要昂贵的钻探项目，而这些项目只能获得有限的整个断层内部结构的信息。了解大断层的内部结构是至关重要的，因为它们的化学和机械特性控制着地震破裂、成核和传播的方式和位置。这反过来又限制了地震的规模或辐射地震能量的数量，从而限制了地表破坏的严重程度。例如，1999年发生在车隆堡板块边界断层的7.7级地震是台湾有记录以来伤亡人数第二多的地震，在断层不同位置的滑动和地面运动发生了显著变化，导致了当地伤亡和损失的巨大变化。随后的现场调查将这些变化与断层结构的变化(即粘土宽度、几何形状)联系起来，这些变化反过来又控制了断层的移动方式。

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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JULY 2020

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