Abstract
With the growing population and the adverse effects of climate change, the pressure on coastal aquifers is increasing, leading to a larger risk of saltwater intrusion (SI). SI is often complex and difficult to characterize from well data only. In this context, electrical resistivity tomography (ERT) can provide high-resolution qualitative information on the lateral and vertical distribution of salinity. However, the quantitative interpretation of ERT remains difficult because of the uncertainty of petrophysical relationships, the limitations of inversion, and the heterogeneity of aquifers. In this contribution, we propose a methodology for the semiquantitative interpretation of ERT when colocated well data are not available. We first use existing wells to identify freshwater zones and characterize the resistivity response of clayey deposits. Then, we approximate the formation factor from water samples collected in the vicinity of ERT data to derive a resistivity threshold to interpret the saline boundary. We applied the methodology in the shallow aquifers of the Luy River in the Binh Thuan province, Vietnam, where water resources are under pressure due to agricultural, aquacultural, and industrial production. Twenty-one ERT profiles were collected and revealed a much larger intrusion zone, compared to the previous study. Saltwater is present in lowland areas of the left bank over almost the whole thickness of the aquifer, while the right bank is constituted of sand dunes that are filled with freshwater. At a larger distance from the sea, a complex distribution between fresh and saltwater is observed. Our methodology could be applied to other heterogeneous aquifers in the absence of a dense monitoring network.
Highlights
IntroductionThe complex combination of potential natural and anthropogenic impacts has placed coastal aquifers under intense pressure by salinity contamination
We developed a new methodology to interpret electrical resistivity tomography (ERT) data in terms of salinity in a heterogeneous aquifer in the absence of colocated data
We defined a conservative threshold of resistivity to interpret semiquantitatively saline and fresh boundaries
Summary
The complex combination of potential natural and anthropogenic impacts has placed coastal aquifers under intense pressure by salinity contamination. Geological conditions, such as the presence of confining layers combined with paleohydrological conditions, can yield complex saltwater distributions related to ancient seawater trapped in sediments [5]. Geological heterogeneity is identified as one of the most important factors affecting the spatiotemporal dynamics of saltwater in coastal aquifers [1,6]. It affects the evolution of SI through creating preferential flow paths and makes the conceptualization of SI more difficult by preventing the generalization of the processes. Often, monitoring well networks at a regional or catchment scale is not sufficient to obtain a comprehensive view of SI, and the relatively large distance between boreholes makes it difficult to characterize the underlying spatially dependent processes
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