来自Sentinel - 1A InSAR图像的2021年1月26日伊拉克北部和叙利亚东北部Sinjar - Hasakah地区地震的地表变形

IF 3.7 3区地球科学 Q2 ENVIRONMENTAL SCIENCES

Egyptian Journal of Remote Sensing and Space Sciences Pub Date : 2025-02-07 DOI:10.1016/j.ejrs.2025.02.001

Jamal A.H. Doski

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引用次数: 0

摘要

地震引起的地表变形是构造活动地区的重要地质灾害。本研究调查了2021年1月26日发生在Sinjar - Hasakah地区（伊拉克北部和叙利亚东北部）的中低震级地震（Mw 4.9）的影响。这次地震是研究区48年来最严重的一次地震。地震矩张量解表明存在右侧（右）走滑断层。利用DInSAR技术对4幅Sentinel-1A SAR图像进行处理，分析了2021年1月26日地震的地表变形和发震断层。这些活动断层沿上升轨道的最大变形范围为- 7.56 cm（沉降）至+ 3.75 cm（隆升），沿视线（LOS）下降轨道的最大变形范围为- 4.56 cm（沉降）至+ 4.61 cm（隆升）。推断Hasakah发震断层是造成2021年1月26日地震的原因。该断裂是一条北西向陡倾地震活动的右旋走滑基底断裂，形成于晚上新世构造反转时期。它从西北部的哈塞卡市附近延伸120多公里，进入东南部的震中地区，穿过辛贾尔和阿卜杜勒·阿齐兹隆起之间的边界。此外，这条发震断层与一条活跃的e向、s向逆冲基底断层相交，该断层穿过Abd El Aziz和Sinjar背斜的北支。

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Surface deformation of the 26 January 2021 earthquake in the Sinjar – Hasakah Area, N Iraq and NE Syria, from Sentinel‑1A InSAR images

The deformation of Earth’s surface caused by earthquakes stands as a critical geological hazard in regions characterized by active tectonic structures. This study investigates the impact of a low-to-moderate magnitude earthquake (Mw 4.9) that occurred on January 26, 2021, in the Sinjar – Hasakah area (N Iraq and NE Syria). This seismic event marks the most significant occurrence in the study area over the past 48 years. The earthquake’s moment tensor solution suggests the presence of a right-lateral (dextral) strike-slip fault. 4 Sentinel-1A SAR images were processed by the DInSAR technique to analyze the surface deformation and identify the seismogenic fault of the 26 January 2021 earthquake. The most significant deformation observed along these active faults ranged from – 7.56 cm (subsidence) to + 3.75 cm (uplift) in the ascending orbit, and from – 4.56 cm (subsidence) to + 4.61 cm (uplift) in the descending orbit along the Line of Sight (LOS). It is inferred that the Hasakah seismogenic fault is responsible for the 26 January 2021 earthquake. This fault is a NW-trending, steeply dipping seismically active dextral strike-slip basement fault that formed during the Late Pliocene structural inversion. It extends over 120 km from the vicinity of Hasakah city in the northwest into the epicentral area in the southeast, traversing the boundary between the Sinjar and Abd El Aziz uplifts. Moreover, this seismogenic fault intersects with an active E-trending, S-dipping thrust basement fault that cuts through the northern limbs of both the Abd El Aziz and Sinjar anticlines.

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来源期刊

Egyptian Journal of Remote Sensing and Space Sciences Multiple-

CiteScore

8.10

自引率

0.00%

发文量

审稿时长

48 weeks

期刊介绍： The Egyptian Journal of Remote Sensing and Space Sciences (EJRS) encompasses a comprehensive range of topics within Remote Sensing, Geographic Information Systems (GIS), planetary geology, and space technology development, including theories, applications, and modeling. EJRS aims to disseminate high-quality, peer-reviewed research focusing on the advancement of remote sensing and GIS technologies and their practical applications for effective planning, sustainable development, and environmental resource conservation. The journal particularly welcomes innovative papers with broad scientific appeal.