Postseismic deformation due to the 2021 MW 7.4 Maduo (China) earthquake and implications for regional rheology and seismic hazards around the Bayan Har block

IF 4.8 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Earth and Planetary Science Letters Pub Date : 2024-10-10 DOI:10.1016/j.epsl.2024.119059

Zhen Tian , Jeffrey T. Freymueller , Yang He , Guofeng Ji , Shidi Wang , Zhenhong Li

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Abstract

GPS and InSAR observations of the first ∼1.5 years of postseismic deformation caused by the 2021 M_W 7.4 Maduo earthquake provide a valuable opportunity to investigate fault interactions and regional rheological structure, as well as the future seismic potential around the Bayan Har block, northeastern Tibetan Plateau. We develop an integrated model to simulate the afterslip and viscoelastic relaxation contributions to the observed postseismic displacements, and found that afterslip driven by the coseismic stress is concentrated downdip of rupture, and dominates the postseismic deformation in the early stage (∼0.4 year after the event). Because afterslip decays quickly over time, viscoelastic relaxation should become the main postseismic mechanism as time goes on. The two mechanisms produce similar displacements during 0.4–1.5 years after the earthquake, but at 1.5 years after the earthquake the velocity caused by viscoelastic relaxation is larger than that caused by afterslip. Viscoelastic models assuming either a Burgers body or power-law rheology produce very similar predictions, with the Burgers body model having a slightly lower overall misfit. The rheological structure constrained by the postseismic observations supports the 35-km thick elastic upper crust overlying a Burgers body viscoelastic lower curst with a Maxwell viscosity of 3 × 10¹⁹ Pa s (5 - 50 × 10¹⁸ Pa s at 95% confidence), assuming the Kelvin viscosity is equal to 10% of that value. This is different from the regional rheology inferred by the postseismic investigations on the 2001 M_W 7.8 Kokoxili and the 2008 M_W 7.8 Wenchuan events, and the preferred thickness of the elastic crust is also different from that inferred from magnetotelluric profiles deployed in previous studies. We thus infer that the rheological structure within the Bayan Har block is possibly heterogeneous from west to east. Finally, the normal stress changes triggered by the coseismic rupture and postseismic process are estimated to be negative, but the shear stress changes to be positive on the western Kunlun fault, the eastern Dari fault and Bayan-Har Mountain fault. However, the current observations and studies are quite insufficient on those fault segments, therefore, we need to focus on their faulting behavior and seismic risk in the future.

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2021 年中国玛多 7.4 级地震引起的震后形变及其对巴彦哈尔区块周边地区流变学和地震灾害的影响

对2021年玛多7.4级地震引起的震后1∼1.5年的GPS和InSAR观测为研究青藏高原东北部巴颜哈尔地块周围的断层相互作用和区域流变结构以及未来的地震潜力提供了宝贵的机会。我们建立了一个综合模型来模拟后滑动和粘弹性松弛对观测到的震后位移的贡献，发现共震应力驱动的后滑动集中在破裂的下倾，并在早期阶段（震后 0.4 年）主导震后变形。随着时间的推移，粘弹性松弛应成为主要的震后机制。这两种机制在震后 0.4-1.5 年期间产生的位移相似，但在震后 1.5 年，粘弹性松弛引起的速度大于余震引起的速度。假设布尔格斯体或幂律流变学的粘弹性模型产生的预测结果非常相似，布尔格斯体模型的总体误差略低。震后观测所制约的流变结构支持35千米厚的弹性上地壳覆盖着布格斯体粘弹性下地壳，麦克斯韦粘度为3×1019帕秒（95%置信度为5-50×1018帕秒），假设开尔文粘度等于该值的10%。这与 2001 年 MW 7.8 可可西里事件和 2008 年 MW 7.8 汶川事件震后调查推断出的区域流变学不同，弹性地壳的首选厚度也与之前研究中部署的磁能图谱推断出的厚度不同。因此，我们推断巴彦哈拉地块内部的流变结构可能是自西向东的异质结构。最后，在西部昆仑断层、东部达里断层和巴颜哈拉山断层上，共震断裂和震后过程引发的法向应力变化估计为负值，而剪应力变化则为正值。然而，目前对这些断层段的观测和研究还很不够，因此，我们需要在未来重点研究它们的断层行为和地震风险。

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来源期刊

Earth and Planetary Science Letters 地学-地球化学与地球物理

CiteScore

10.30

自引率

5.70%

发文量

475

审稿时长

2.8 months

期刊介绍： Earth and Planetary Science Letters (EPSL) is a leading journal for researchers across the entire Earth and planetary sciences community. It publishes concise, exciting, high-impact articles ("Letters") of broad interest. Its focus is on physical and chemical processes, the evolution and general properties of the Earth and planets - from their deep interiors to their atmospheres. EPSL also includes a Frontiers section, featuring invited high-profile synthesis articles by leading experts on timely topics to bring cutting-edge research to the wider community.