1. LNAPL migration processes based on time-lapse electrical resistivity tomography.
- Author
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Li, Zhi-ping, Liu, Yu, Zhao, Gui-zhang, Liu, Shao-kang, and Liu, Wen-hui
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ELECTRICAL resistivity , *NONAQUEOUS phase liquids , *WATER table , *WATER levels , *GROUNDWATER remediation , *TOMOGRAPHY , *ELECTRICAL resistance tomography - Abstract
Contamination from light non-aqueous phase liquids (LNAPLs) and their derivatives, arising from exploration, production, and transportation, has become a prevalent pollution source. This poses direct threats to human health. However, conventional investigative methods face limitations when applied to studying the extent and migration process of LNAPL contamination, as well as the redistribution of LNAPL during groundwater level fluctuations. Conventional methods lack the ability to rapidly, efficiently, and in real-time acquire information about contaminated areas. Therefore, this study utilizes time-lapse electrical resistivity tomography to investigate the migration mechanism of LNAPL under unsaturated conditions, constant groundwater levels, and groundwater level reductions. A relationship between resistivity and water and oil contents was established and used for inverse calculation of LNAPL content via resistivity inversion. Time-lapse electrical resistivity tomography revealed LNAPL migration in a "concave" shape across three conditions. Groundwater presence notably slowed migration, hindering downward movement and leading to a floating oil band. A robust mathematical model was established to derive the relationship between resistivity and water and oil contents. Finally, LNAPL distribution under unsaturated conditions was inversely obtained from resistivity data, showing highest content at the top leak point, obstructed area, and bottom of soil column. Consequently, time-lapse electrical resistivity tomography demonstrates a notable capacity to characterize the LNAPL migration process. This technique constitutes an effective geophysical method for monitoring and describing the characteristics of LNAPL migration. Its significance lies in enhancing our understanding of remediation for LNAPL-induced groundwater and land contamination. • Establish the empirical formula between resistivity, LNAPL concentration and water content. • In this experiment, time-lapse resistivity imaging technology was used to study the migration process of LNAPL. • This study highlights the influence of groundwater table on LNAPL migration. • According to the resistivity and water content inversion the LNAPL concentration in the medium is obtained. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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