2022 年哈尔湖地震序列凸显青藏高原东北部祁连山西部的复杂断层系统

Wei Xiong, Caijun Xu, Wei Chen, Bin Zhao, Yangmao Wen
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摘要

2022 年哈尔湖地震序列始于 2022 年 1 月,持续了 70 天,震中位于青藏高原东北部祁连山西部的哈尔湖地区。地震序列中发生了两次 Mw>5.5 的地震,其中 3 月 25 日发生的 Mw5.8 地震被认为是该地区有记录以来最大的地震。然而,由于缺乏地质数据和近场地震观测,确定地震序列的发震断层以及详细的断裂特征十分困难。在本研究中,我们利用 Sentinel-1 合成孔径雷达(SAR)数据获得了共震形变场,确定了可能的破裂断层和相关断层几何特征,并进一步估算了两次 Mw>5.5 地震的详细共震滑移模型。结果表明,1 月 23 日 Mw5.6 地震(地震 A)发生在一条 N15°W-倾角为 ∼ 61°的向斜断层上。对于 3 月 25 日发生的 Mw5.8 地震(地震 B),干涉合成孔径雷达(InSAR)数据可描述为一条 ∼N-S 走向的右旋-滑动断层或一条 ∼E-W 走向的正弦-滑动断层。N-S走向的断层更好地描述了余震分布,而E-W走向的模型则更符合区域地质环境。我们认为,多断层系统中复杂的共震破裂是由祁连山西部广泛的 NE-SW 走向压缩所驱动的。这项研究证明了综合大地测量和地震学观测以捕捉中等地震全部复杂性的重要性,并进一步提示了哈湖地区潜在的地震危险。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The 2022 Har Lake earthquake sequence highlights a complex fault system in the western Qilian Shan, northeastern Tibetan Plateau
The 2022 Har Lake earthquake sequence, which began in January 2022 and lasted for ∼70 days, jolted the Har Lake area, which is located in the western Qilian Shan, northeastern Tibetan Plateau. Two Mw>5.5 earthquakes occurred during the earthquake sequence, among which the March 25 Mw5.8 event is considered the largest event recorded in the area. However, determining the seismogenic faults of the earthquake sequence, as well as the detailed rupture features, is difficult due to the lack of geological data and near-field seismological observations. In this study, we use Sentinel-1 synthetic aperture radar (SAR) data to obtain the coseismic deformation field, identify possible ruptured faults and associated fault geometries, and further estimate detailed coseismic slip models of the two Mw>5.5 earthquakes. The results show that the January 23 Mw5.6 earthquake (Earthquake A) occurred on a N15°W-trending dextral-slip fault with a dip angle of ∼61°. For the March 25 Mw5.8 earthquake (Earthquake B), the interferometric synthetic aperture radar (InSAR) data can be described by either an ∼N–S-trending dextral-slip fault or an ∼E–W-trending sinistral-slip fault. The ∼N–S-trending fault better describes the aftershock distribution, while the ∼E–W-trending model is more consistent with the regional geological setting. We suggest that the complex coseismic ruptures in the multiple-fault system are driven by widespread NE–SW-trending compression in the western Qilian Shan. This study demonstrates the importance of integrating geodetic and seismological observations to capture the full complexity of moderate earthquakes and further suggests potential seismic hazards in the Har Lake area.
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