三维地球动力学与动态地震破裂耦合:断层几何、流变学和跨时标应力

Anthony Jourdon, Jorge Nicolas Hayek, Dave A. May, Alice-Agnes Gabriel
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引用次数: 0

摘要

构造变形对地球表面起着至关重要的作用,应变局部化导致剪切带和断层的形成,从而产生巨大的构造位移。地震动态破裂模型为地震力学和地震地面运动提供了宝贵的见解,它依赖于预应力状态和断层几何等初始条件。然而,由于观测条件的限制,这些初始条件往往约束不足。为了应对这些挑战,我们开发了一种新方法,将三维地球动力学模型与三维动态破裂模拟松散地结合起来,为地震分析提供了一个力学上一致的框架。我们的方法不规定断层的几何形状,而是利用中轴变换从底层岩石圈流变学和构造速度中推导出断层的几何形状。我们对一个走向滑动地球动力学系统进行了三个长期地球动力学模型,每个模型涉及不同的大陆地壳流变学。我们将这些模型与九个动态断裂模型联系起来,研究不同断裂能量和塑性应变能量耗散在动态断裂行为中的作用。这些模拟表明,对于我们的断层、长期流变学和地球动力系统,可信的临界线性滑动削弱距离在[0.6,1.5]的Dc范围内。我们的结果表明,长期三维应力场有利于与区域板块运动更一致的断层段的滑移,长期三维应力场的微小变化会强烈影响断裂动力学,为阻止地震传播提供了一种物理机制。我们根据地球动力学建立的地震模型突出表明,要全面了解地震力学,就必须建立跨时间尺度的详细三维断层模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Coupling 3D geodynamics and dynamic earthquake rupture: fault geometry, rheology and stresses across timescales
Tectonic deformation crucially shapes the Earth's surface, with strain localization resulting in the formation of shear zones and faults that accommodate significant tectonic displacement. Earthquake dynamic rupture models, which provide valuable insights into earthquake mechanics and seismic ground motions, rely on initial conditions such as pre-stress states and fault geometry. However, these are often inadequately constrained due to observational limitations. To address these challenges, we develop a new method that loosely couples 3D geodynamic models to 3D dynamic rupture simulations, providing a mechanically consistent framework for earthquake analysis. Our approach does not prescribe fault geometry but derives it from the underlying lithospheric rheology and tectonic velocities using the medial axis transform. We perform three long-term geodynamics models of a strike-slip geodynamic system, each involving different continental crust rheology. We link these with nine dynamic rupture models, in which we investigate the role of varying fracture energy and plastic strain energy dissipation in the dynamic rupture behavior. These simulations suggest that for our fault, long-term rheology, and geodynamic system, a plausible critical linear slip weakening distance falls within Dc in [0.6,1.5]. Our results indicate that the long-term 3D stress field favors slip on fault segments better aligned with the regional plate motion and that minor variations in the long-term 3D stress field can strongly affect rupture dynamics, providing a physical mechanism for arresting earthquake propagation. Our geodynamically informed earthquake models highlight the need for detailed 3D fault modeling across time scales for a comprehensive understanding of earthquake mechanics.
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