大地震的动态破坏过程与断层摩擦定律

Michel Campillo , Raul Madariaga
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引用次数: 2

摘要

我们利用1992年6月28日加州兰德斯地震的观测资料研究了一组活动断层上破裂传播的物理特性。这一记录完好的事件提供了大量关于地震断层破裂传播细节的信息,从根本上改变了地球科学中非常流行的简单的地震破裂模型。本文讨论了不同的方法来反演地震和大地测量数据,以了解破裂过程的细节,并将其投入工作,以便建立兰德斯地震的模型,该模型基本上解释了波长约3公里的所有可用数据。我们的研究表明,地震传播非常迅速,但传播方式非常复杂和曲折。断裂历史的运动学描述用于约束断层上的摩擦参数。数值模拟完全再现了源的特性,包括波辐射。摩擦减弱的结果是在破裂扩展之前存在一个起始阶段。这个阶段与特定的长度和时间特征相关联。研究表明,大地震时断层上的明显摩擦是断层段之间复杂相互作用的结果。因此,弱化速率是一个依赖于尺度的性质,这取决于断层系统在不同尺度上的几何性质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Processus de rupture dynamique d'un grand séisme et loi de friction sur les failles

We study the physics of rupture propagation on a set of active faults using observations of the 28 June 1992 Landers earthquake in California. This very well recorded event provides a wealth of information about the details of rupture propagation on earthquake faults that modify in a fundamental way the simple naive models of earthquake rupture that have been so popular in Earth Sciences. Different methods to invert seismic and geodetic data for the details of the rupture process are discussed and put to work in order to make a model of the Landers earthquake that explains essentially all available data down to a wavelength of about 3 km. It emerges from our studies that earthquakes propagate very rapidly but in a very complex and tortuous way. The kinematic description of the rupture history is used to constrain the parameters of friction on the fault. The numerical simulation completely reproduces the source properties, including wave radiation. A consequence of friction weakening is the existence of a phase of initiation prior to rupture propagation. This phase is associated with specific length and time characteristics. We show that the apparent friction on the fault during large earthquakes is the result of complex interactions between the fault segments. The weakening rate is therefore a scale-dependant property depending on the geometrical properties of the fault system at different scales.

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