Dynamic Rupture Modeling and Ground-Motion Simulations of the 2022 Mw 6.6 Luding Earthquake

IF 2.6 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

Seismological Research Letters Pub Date : 2023-08-30 DOI:10.1785/0220230110

Yuhao Gu, Zhenguo Zhang, Wenqiang Wang, Zhongqiu He

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Abstract

The 2022 Mw 6.6 Luding earthquake occurred on the Xianshuihe fault, one of China’s most active faults. Revealing the rupture process of the Luding earthquake and exploring the distribution of high intensities is important for earthquake hazard reduction around the active Xianshuihe fault in the future. Therefore, we modeled the dynamic rupture and ground motions of the Luding earthquake. The dynamic rupture modeling demonstrates that the maximum slip of the fault plane is ∼1.34 m, and the ground-motion simulations show the highest intensity attained is IX. In addition, we conducted a comparative analysis between synthetic data and station observation records, illustrating that our simulation results are compatible with the seismic station observations. We investigated the influence of geometric complexities on the Xianshuihe fault rupture and found that varying the dip angle of the southern segment may lead to premature rupture termination and constrain the rupture propagation. Our study provides insights into the complex geometry’s effect on the physical process of large earthquakes on the Xianshuihe fault.

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2022年泸定6.6 Mw地震的动态破裂模型和地面运动模拟

2022年泸定6.6级地震发生在中国最活跃的断层之一淡水河断层上。揭示泸定地震的破裂过程，探索高烈度的分布规律，对于今后减少淡水河断裂活动区的地震危险性具有重要意义。因此，我们对泸定地震的动力破裂和地面运动进行了模拟。动态断裂建模表明，断层面的最大滑移为~1.34 m，地面运动模拟显示达到的最高强度为IX。此外，我们对合成数据和台站观测记录进行了比较分析，表明我们的模拟结果与地震台站观测结果相一致。研究了几何复杂性对淡水河断裂破裂的影响，发现改变南段的倾角可能导致断裂提前终止，并限制断裂的扩展。我们的研究为复杂几何结构对淡水河断裂大地震物理过程的影响提供了见解。

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