Project Abstract

This project aims to develop an innovative and comprehensive approach to hydrocarbon exploration in offshore sedimentary basins, leveraging the synergistic integration of various geophysical techniques. The exploration and successful exploitation of hydrocarbon resources in offshore environments are critical for meeting the growing global energy demand and ensuring energy security. However, the complex geological settings and challenging environmental conditions associated with offshore basins often pose significant challenges in accurately identifying and characterizing hydrocarbon-bearing formations. The primary objective of this project is to establish a robust and efficient workflow that combines multiple geophysical methods to enhance the accuracy and reliability of hydrocarbon exploration in offshore sedimentary basins. The proposed approach will integrate seismic reflection data, gravity and magnetic surveys, electromagnetic (EM) methods, and other complementary geophysical techniques to provide a comprehensive understanding of the subsurface geology and identify potential hydrocarbon reservoirs. The project will begin with a thorough review of existing geophysical methodologies and their applications in offshore hydrocarbon exploration. This will involve a critical analysis of the strengths, limitations, and complementary nature of different geophysical techniques, as well as an assessment of the latest advancements in data acquisition, processing, and interpretation. The team will then develop a tailored workflow that optimizes the integration of these methods, taking into account the specific geological and environmental characteristics of the target offshore sedimentary basins. A key component of the project will be the development of advanced data integration and interpretation algorithms. By leveraging machine learning and data fusion techniques, the project aims to create a robust decision-making framework that can effectively synthesize the disparate geophysical data sets and provide a more accurate and reliable identification of hydrocarbon-bearing formations. This will involve the development of novel data-driven models and the incorporation of geological and geochemical constraints to enhance the overall interpretation process. The project will be validated through comprehensive field trials in selected offshore sedimentary basins, where the integrated geophysical approach will be implemented and evaluated. The field trials will involve extensive data acquisition campaigns, data processing and integration, and the validation of the interpreted results against actual drilling and production data. This validation process will not only demonstrate the efficacy of the proposed approach but also provide valuable insights into the specific geological and environmental challenges associated with the target offshore basins. The successful completion of this project will have significant implications for the hydrocarbon exploration industry. The integration of multiple geophysical techniques will lead to improved success rates in identifying viable hydrocarbon reservoirs, reduce the risks and costs associated with exploratory drilling, and contribute to the sustainable development of offshore energy resources. Furthermore, the project's findings and the developed methodologies will have broader applications in the fields of basin analysis, structural geology, and offshore resource management, ultimately enhancing our understanding of the complex geological systems that underlie the world's offshore sedimentary basins.

Project Overview