Project Abstract

This project aims to provide a comprehensive approach to groundwater exploration and aquifer characterization using a combination of geophysical techniques. Groundwater is a vital natural resource that plays a crucial role in meeting the water demands of communities, agriculture, and industry worldwide. However, the exploration and management of groundwater resources often face challenges due to the complex and heterogeneous nature of subsurface geological formations. The primary objective of this project is to develop an integrated geophysical methodology that can effectively locate, map, and characterize groundwater aquifers. By employing a suite of complementary geophysical methods, the project seeks to overcome the limitations of individual techniques and provide a more robust and reliable assessment of groundwater resources. The project will commence with a comprehensive literature review to understand the current state of knowledge and best practices in the application of geophysical techniques for groundwater exploration. This will include an analysis of the strengths, weaknesses, and suitability of various geophysical methods, such as electrical resistivity, seismic refraction, ground-penetrating radar, and electromagnetic induction, among others. Building on this foundation, the project will then focus on the selection and integration of the most suitable geophysical techniques for the specific study area. This will involve conducting field surveys to collect high-quality geophysical data, which will be complemented by hydrogeological and geological information, as well as borehole data, where available. The collected data will be subjected to rigorous processing, analysis, and interpretation using advanced computational and modeling techniques. This will include the development of 2D and 3D subsurface models that can provide detailed insights into the geometry, depth, and characteristics of the aquifer systems. Particular attention will be paid to the identification of groundwater recharge and discharge zones, as well as the delineation of aquifer boundaries and potential contamination pathways. The project will also explore the integration of geophysical data with other spatial datasets, such as satellite imagery, digital elevation models, and land use/land cover information. This multidisciplinary approach will enable the researchers to develop a comprehensive understanding of the groundwater system, including its relationship with surface water, climate, and human activities. The project outcomes will be of significant value to water resource managers, planners, and decision-makers. The developed methodology will provide a robust and reliable tool for the exploration, assessment, and sustainable management of groundwater resources. Additionally, the project will contribute to the advancement of geophysical techniques and their application in the field of hydrogeology, ultimately enhancing our ability to address the pressing water challenges faced by communities around the world.

Project Overview