Differential synthetic aperture radar (SAR) interferometry for detection land subsidence in Derna City, Libya

IF 1.2 Q4 REMOTE SENSING

Journal of Applied Geodesy Pub Date : 2024-01-04 DOI:10.1515/jag-2023-0087

Heba Basyouni Ibrahim, Mahmoud Salah, F. Zarzoura, Mahmoud El-Mewafi

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引用次数: 0

Abstract

Abstract The country of Libya, situated on the Mediterranean fault zone, has a distinctive geodynamic regime due to the interplay between the Eurasian and African plates, which governs its tectonic evolution. In addition to its seismological significance, Libya is characterized by numerous subsidence and slope instabilities in regions with steep terrain. These geological phenomena have significant consequences for the built environment, as they pose an immediate danger to entire towns and essential infrastructure. Furthermore, infrequent weather phenomena, such as intense precipitation and thunderstorms, when coupled with the geological characteristics of some regions and the presence of seismically active terrain, have the potential to trigger landslide and land subsidence, resulting in significant harm to vital infrastructure. The current study utilizes the DInSAR technology to identify distinct subsidence occurrences that were induced by intense precipitation in coastal regions of Libya, specifically in Derna. These areas experienced significant flooding resulting in collapses during September 2023. A total of six pairs of co-event Interferometric Synthetic Aperture Radar (SAR) were utilized to generate displacement maps in the vertical, north-east, and north-west directions for the purpose of analysing the deformations. The aforementioned activities are conducted via Sentinel-1A images, which is freely accessible through the Copernicus program. Additionally, flood-prone zones were defined using Sentinel-1 GRD imagery. The Interferometric processing revealed multiple areas of subsidence. Subsidence rates of up to −14 cm were found in Derna city’s urban cores after flood. The findings suggest that subsidence may have an effect on the flood-proneness of the region of Derna City as Ground subsidence also occurred in the period immediately before the earthquake, at a rate of −14 cm.

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利用差分合成孔径雷达（SAR）干涉测量法探测利比亚德尔纳市的土地沉降情况

摘要利比亚位于地中海断裂带上，由于欧亚板块和非洲板块之间的相互作用，其构造演化具有独特的地球动力机制。除了地震学意义之外，利比亚地形陡峭的地区还存在许多沉降和斜坡不稳定现象。这些地质现象对建筑环境有重大影响，因为它们对整个城镇和重要基础设施构成直接威胁。此外，强降水和雷暴等不常见的天气现象，再加上某些地区的地质特征和地震活跃地形的存在，都有可能引发山体滑坡和地面沉降，对重要的基础设施造成重大损害。本研究利用 DInSAR 技术确定了利比亚沿海地区，特别是德尔纳的强降水引发的明显沉降现象。这些地区在 2023 年 9 月经历了导致塌方的严重洪灾。为分析变形情况，共使用了六对同向事件干涉合成孔径雷达（SAR）来生成垂直、东北和西北方向的位移图。上述活动是通过哥白尼计划免费提供的哨兵-1A 图像进行的。此外，还利用 Sentinel-1 GRD 图像确定了洪水易发区。干涉测量处理显示了多个沉降区域。洪水过后，德尔纳市城市中心区的沉降率高达-14 厘米。研究结果表明，地面沉降可能对德尔纳市地区的洪水易发性有影响，因为在地震前的一段时间内也发生了地面沉降，沉降速率为-14 厘米。

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来源期刊

Journal of Applied Geodesy REMOTE SENSING-

CiteScore

2.30

自引率

7.10%

发文量