Thesis Abstract

Abstract
This thesis presents a comprehensive study on the analysis of seismic data for subsurface imaging and reservoir characterization. Seismic data plays a crucial role in the exploration and development of hydrocarbon resources, providing valuable insights into the subsurface structure and properties. The primary objective of this research is to utilize advanced seismic data processing and interpretation techniques to enhance the understanding of subsurface geology and reservoir characteristics. The study begins with an introduction that outlines the importance of seismic data in the oil and gas industry, highlighting its role in identifying potential hydrocarbon reservoirs and optimizing drilling operations. The background of the study provides a detailed overview of seismic data acquisition methods, processing workflows, and interpretation techniques commonly used in the industry. The problem statement identifies the challenges and limitations associated with traditional seismic data analysis approaches, such as data quality issues, imaging artifacts, and uncertainties in reservoir characterization. The research aims to address these challenges by implementing state-of-the-art seismic processing algorithms and advanced interpretation methodologies. The objectives of the study include improving the resolution and accuracy of subsurface imaging, characterizing reservoir properties such as porosity and fluid saturation, and optimizing drilling decisions based on seismic data analysis. The limitations of the study are discussed, including data quality constraints, computational limitations, and uncertainties associated with seismic interpretation. The scope of the study encompasses the analysis of 3D seismic data from a real-world oil and gas field, focusing on the identification of structural features, stratigraphic relationships, and potential hydrocarbon-bearing zones. The significance of the study lies in its potential to enhance the efficiency and effectiveness of hydrocarbon exploration and production activities, leading to improved reservoir management and economic benefits. The structure of the thesis is outlined, detailing the organization of chapters and key sections that cover the literature review, research methodology, discussion of findings, and conclusion. The definitions of key terms used throughout the thesis are provided to ensure clarity and understanding of technical concepts. The literature review chapter presents a comprehensive analysis of previous studies and industry practices related to seismic data analysis, subsurface imaging, and reservoir characterization. Key topics covered include seismic data acquisition technologies, processing workflows, interpretation methods, and case studies demonstrating the application of seismic data in hydrocarbon exploration. The research methodology chapter describes the data collection process, seismic data processing workflows, interpretation techniques, and analytical tools used in the study. The methodology includes a detailed explanation of the software applications, algorithms, and workflows employed to analyze the seismic data and extract meaningful insights about the subsurface geology and reservoir properties. The discussion of findings chapter presents the results of the seismic data analysis, highlighting key observations, interpretations, and insights gained from the study. The findings include detailed descriptions of structural features, stratigraphic relationships, and reservoir properties identified from the seismic data, along with implications for reservoir management and exploration strategies. In conclusion, this thesis provides a comprehensive analysis of seismic data for subsurface imaging and reservoir characterization, demonstrating the potential of advanced seismic processing and interpretation techniques to enhance the understanding of subsurface geology and improve reservoir management practices in the oil and gas industry. The study contributes valuable insights and recommendations for future research and industry applications in the field of geophysics. Word count 497

Thesis Overview