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Heterogeneous strong asperities and tectonic complexity control irregular cascading ruptures

Chuanchao Huang, Wenbin Xu, Roland Bürgmann, Lei Xie, Guangcai Feng, Baojun Shan, Zhiwei Li, Yosuke Aoki, Yijun Zhang, Jianjun Zhu, Xiaoge Liu

2025Science Advances7 citationsDOIOpen Access PDF

Abstract

Rupture characteristics and heterogeneity of large earthquakes are essential for seismic hazard assessments. We use relocated aftershocks, geodetic measurements, and seismic waveform data to distinguish contributions from closely separated fault structures of the 2024 M w 7.5 Noto earthquake. We find that the initial rupture triggered slip on a complex fault of a preceding swarm and led to bilateral slow rupture there. The earthquake ruptured two fault segments with contrasting dip angles along the eastern and western segments. Aftershocks continued to rupture the preexisting swarm faults. A delayed rupture occurred southwest of the hypocenter, implying that substantial resistance caused by a barrier temporally hindered rupture propagation. Additional stress from surrounding slip eventually overcame the strength of the barrier fault section, leading to a compound rupture. The mainshock triggered a small earthquake swarm, in which the relatively larger events were not followed by abundant aftershocks. Our findings demonstrate the influence of strong asperities and complex geometry in the progression of cascading ruptures.

Topics & Concepts

TectonicsGeologySeismologyComputer scienceearthquake and tectonic studiesRock Mechanics and ModelingHigh-pressure geophysics and materials