Integrated seismotectonic model of the 2013 Mw6.6 and 2022 Mw5.8 earthquake sequences in the southwestern section of the longmenshan fault zone, China, and its implication

IF 2.8 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Li-Sheng Xu, Chang-Zai Wang, Zhe Zhang, Li-Hua Fang, Lei Yi, Xu Zhang, Xiang-Yun Guo, Chun-Lai Li
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Abstract

Summary The 2008 Mw7.9 Wenchuan earthquake ruptured the middle and northeastern segments of the Longmenshan Fault Zone (LMSFZ), and the 2013 Mw6.6 Lushan earthquake ruptured a 50km-long fault in the southwestern segment. Subsequently, an Mw5.8 earthquake occurred approximately 10 km distant from the Mw6.6 Lushan earthquake. Therefore, the potential risk for larger earthquakes (>Mw6.6)on the southwestern section must be considered. This study collects the latest seismological and GPS data to construct an integrated seismotectonic model for the two neighboring earthquake sequences. The model integrates the fault planes involved, the mainshock rupture processes, the mainshock-caused Coulomb stress perturbation, the aftershock distribution and the 3-D velocity structure of the source region, providing information for seismic risk evaluation. We find that three fault planes were involved, two of which were related to the mainshocks, and the third was generated by the aftershocks following the first mainshock. The mainshocks were caused by nearly pure thrust faulting on the two planes with dip angles of approximately 45° and almost opposite dipping directions, thereby forming a conjugate angle of around 90°. The third plane was located between the two mainshocks, approximately parallel to the second mainshock's fault plane. Each of the mainshocks primarily ruptured a single asperity, displaying simple time history. The Coulomb stress change of the first mainshock facilitated the generation of the second mainshock and the third fault plane, and the second mainshock increased the stress on the first mainshock's fault plane. The aftershocks were distributed within stratified materials by spatially varying interfaces and characterized by high Vp and Vs velocity and a low Vp/Vs ratio. The atypical dip angles of approximately 45° for thrust faults and the conjugate angle of approximately 90° are indicative of high stress state. The single asperity rupture implies simple stress accumulation. The mainshock-caused Coulomb stress change did not reduce the seismic risk in the source region. The varying interfaces are interpreted as a consequence of long-term horizontal compression. All of these characteristics suggest that the two earthquake sequences were generated by the breakage of three immature faults under strong compression by background stress, and the high stress state remains within the southwestern LMSFZ.
中国龙门山断裂带西南段2013年Mw6.6和2022年Mw5.8地震序列的综合地震构造模型及其影响
摘要 2008 年 Mw7.9 级汶川地震造成龙门山断裂带中段和东北段断裂,2013 年 Mw6.6 级芦山地震造成西南段长 50 公里的断层断裂。随后,在距离 Mw6.6 芦山地震约 10 公里处发生了 Mw5.8 地震。因此,必须考虑西南段发生更大地震(>Mw6.6)的潜在风险。本研究收集了最新的地震学和 GPS 数据,构建了两个相邻地震序列的综合地震构造模型。该模型综合了所涉及的断层面、主震破裂过程、主震引起的库仑应力扰动、余震分布以及震源区的三维速度结构,为地震危险性评估提供了信息。我们发现涉及三个断层面,其中两个与主震有关,第三个由第一次主震后的余震产生。主震是由两个平面上几乎纯粹的推力断层引起的,这两个平面的倾角约为 45°,倾角方向几乎相反,从而形成了一个约 90°的共轭角。第三个平面位于两个主震之间,与第二个主震的断层面大致平行。每一次主震都主要使单个岩体断裂,其时间历程比较简单。第一次主震的库仑应力变化促进了第二次主震和第三个断层面的产生,第二次主震增加了第一次主震断层面的应力。余震通过空间变化的界面分布在层状物质中,其特点是 Vp 和 Vs 速度高,Vp/Vs 比值低。推力断层的非典型倾角约为 45°,共轭角约为 90°,这表明断层处于高应力状态。单端面断裂意味着简单的应力累积。主震引起的库仑应力变化并没有降低震源区的地震风险。不同的界面被解释为长期水平压缩的结果。所有这些特征都表明,这两次地震序列是由三条未成熟断层在背景应力的强压缩作用下断裂产生的,高应力状态仍然存在于 LMSFZ 西南部。
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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来源期刊
Geophysical Journal International
Geophysical Journal International 地学-地球化学与地球物理
CiteScore
5.40
自引率
10.70%
发文量
436
审稿时长
3.3 months
期刊介绍: Geophysical Journal International publishes top quality research papers, express letters, invited review papers and book reviews on all aspects of theoretical, computational, applied and observational geophysics.
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