Monitoring of Ground Movement and Groundwater Changes in London Using InSAR and GRACE

Vivek Agarwal,Rachel L Gomes,Amit Kumar,Stuart Marsh

doi:10.3390/app10238599

Vivek Agarwal, Rachel L Gomes + Show 2 more

Open Access

https://doi.org/10.3390/app10238599

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Journal: Applied sciences	Publication Date: Dec 1, 2020
Citations: 15	License type: CC BY 4.0

Affiliation: University of Nottingham

Abstract

Groundwater-induced land movement can cause damage to property and resources, thus its monitoring is very important for the safety and economics of a city. London is a heavily built-up urban area and relies largely on its groundwater resource and thus poses the threat of land subsidence. Interferometric Synthetic Aperture Radar (InSAR) can facilitate monitoring of land movement and Gravity Recovery and Climate Experiment (GRACE) gravity anomalies can facilitate groundwater monitoring. For London, no previous study has investigated groundwater variations and related land movement using InSAR and GRACE together. In this paper, we used ENVISAT ASAR C-band SAR images to obtain land movement using Persistent Scatterer InSAR (PSInSAR) technique and GRACE gravity anomalies to obtain groundwater variations between December 2002 and December 2010 for central London. Both experiments showed long-term, decreasing, complex, non-linear patterns in the spatial and temporal domain. The land movement values varied from −6 to +6 mm/year, and their reliability was validated with observed Global Navigation Satellite System (GNSS) data, by conducting a two-sample t-test. The average groundwater loss estimated from GRACE was found to be 9.003 MCM/year. The ground movement was compared to observed groundwater values obtained from various boreholes around central London. It was observed that when large volumes of groundwater is extracted then it leads to land subsidence, and when groundwater is recharged then surface uplift is witnessed. The results demonstrate that InSAR and GRACE complement each other and can be an excellent source of monitoring groundwater for hydrologists.

Highlights

Groundwater contributes a significant proportion of the Earth’s freshwater and a large part of the urban world is facing groundwater depletion and the problems related to it [1]
To analyse the multi-temporal Interferometric Synthetic Aperture Radar (InSAR) monitoring results, we can look at the statistical deformation results of the entire area through the number of persistent scatterer points (PSNs), mean rate of deformation (MRD), and standard deviation (SD) of deformation (Table 3)
To validate the reliability of results obtained from Persistent Scatterer InSAR (PSInSAR), we studied the PSInSAR results in comparison to Global Navigation Satellite System (GNSS) data obtained from The British Isles continuous GNSS Facility (BIGF)

Summary

Introduction

Groundwater contributes a significant proportion of the Earth’s freshwater and a large part of the urban world is facing groundwater depletion and the problems related to it [1]. One of the major problems associated with over-abstraction of groundwater is land subsidence, resulting from the compression of the sub-surface aquifer system due to loss of pore pressure and/or land uplift, which is caused because of excessive groundwater recharge [3]. This land movement can cause major and recurrent harm to infrastructure, increase in floods, water contamination risks, and nonrecoverable losses in an aquifer’s ability to store water. This is pertinent with globally increasing urbanisation

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Conclusion