Project Abstract

This project aims to unravel the complex subsurface geological structure of a region known for its intricate tectonic history and diverse lithological assemblage. The study area is characterized by a complicated geology, including the presence of faults, folds, and igneous intrusions, which have significantly influenced the region's geomorphology and hydrogeological characteristics. Understanding the subsurface architecture of this area is crucial for various applications, such as mineral exploration, groundwater management, and geohazard assessment. To achieve a comprehensive understanding of the subsurface geology, the project will employ an integrated geophysical approach, combining multiple complementary techniques. This approach will involve the acquisition and interpretation of high-resolution geophysical data, including gravity, magnetic, and seismic surveys, in conjunction with available geological and geochemical information. The gravity and magnetic surveys will be used to map the regional-scale variations in the subsurface density and magnetic properties, respectively. These data will provide insights into the distribution and geometry of major geological units, including igneous intrusions and fault zones. The seismic surveys, on the other hand, will be designed to delineate the depth and configuration of specific geological features, such as sedimentary basins, thrust faults, and crustal-scale structures. The integration of these geophysical datasets, along with the incorporation of borehole logs and geological maps, will enable the development of a comprehensive 3D model of the subsurface geology. This model will elucidate the complex tectonic evolution of the region, including the timing and kinematics of deformation events, as well as the interplay between magmatic and sedimentary processes. The project will also explore the potential for using geophysical techniques to identify and characterize specific geological targets of interest, such as mineral deposits or potential groundwater aquifers. By integrating the geophysical data with other geological and geochemical information, the research team will strive to develop a robust exploration strategy that can guide future targeted investigations and field-based studies. The outcomes of this project will have far-reaching implications for the scientific understanding of the region's geological history and the potential for its natural resource development. The 3D subsurface model generated through this research will serve as a valuable reference for various stakeholders, including geologists, mining companies, and government agencies responsible for land-use planning and resource management. Furthermore, the project will contribute to the advancement of integrated geophysical methodologies, demonstrating the synergistic application of multiple techniques to unravel the complexities of subsurface geology in challenging environments. The research findings and the developed workflows will be disseminated through peer-reviewed publications and presentations at scientific conferences, fostering knowledge exchange and collaborations within the geoscientific community. Overall, this project represents a comprehensive and innovative approach to investigating the subsurface geological structure of a geologically complex region, with the potential to yield significant scientific and practical implications for the understanding and management of the region's natural resources and geohazards.

Project Overview