Abstract
Groundwater resources have been exploited and utilized on a large scale in the North China Plain (NCP) since the 1970s. As a result of extensive groundwater depletion, the NCP has experienced significant land subsidence, which threatens geological stability and infrastructure health and exacerbates the risks of other geohazards. In this study, we employed multi-track Synthetic Aperture Radar (SAR) datasets acquired by the Sentinel-1A (S1A) satellite to detect spatial and temporal distributions of surface deformation in the NCP from 2016 to 2018 based on multi-temporal interferometric synthetic aperture radar (MT-InSAR). The results show that the overall ground displacement ranged from −165.4 mm/yr (subsidence) to 9.9 mm/yr (uplift) with a standard variance of 28.8 mm/yr. During the InSAR monitoring period, the temporal pattern of land subsidence was dominated by a decreasing tendency and the spatial pattern of land subsidence in the coastal plain exhibited an expansion trend. Validation results show that the S1A datasets agree well with levelling data, indicating the reliability of the InSAR results. With groundwater level data, we found that the distribution of subsidence in the NCP is spatially consistent with that of deep groundwater depression cones. A comparison with land use data shows that the agricultural usage of groundwater is the dominant mechanism responsible for land subsidence in the whole study area. Through an integrated analysis of land subsidence distribution characteristics, geological data, and previous research results, we found that other triggering factors, such as active faults, precipitation recharge, urbanization, and oil/gas extraction, have also impacted land subsidence in the NCP to different degrees.
Highlights
Groundwater constitutes the main water supply and meets more than 70% of the water needs in the North China Plain (NCP), a major agricultural base and industrial base in China [1]
Rapid urbanization, increased dynamic and static loads, and the development of underground spaces have impacted the occurrence of land subsidence to various degrees [12,13,14,15], and these factors contribute to land subsidence in the NCP [16,17,18,19,20]
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Summary
Groundwater constitutes the main water supply and meets more than 70% of the water needs in the North China Plain (NCP), a major agricultural base and industrial base in China [1]. Similar to several areas around the world [2,3,4,5,6,7,8,9,10,11], the NCP has experienced rapid land subsidence in association with extensive groundwater withdrawal. Subsidence in the NCP has previously been monitored using extensometers, levelling measurements, and global positioning system (GPS) measurements with high precision and space-time restrictions [19,21,22]. Compared with these point-based geodetic methods, interferometric synthetic aperture radar (InSAR) has the ability to monitor large-scale ground subsidence throughout the day under all weather conditions with millimeter-scale precision. The spatial extent, magnitude, and temporal evolution of land subsidence elsewhere in the NCP have not been investigated
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