Thesis Abstract

Abstract
Seismic wave attenuation is a crucial parameter in understanding the behavior of seismic waves as they propagate through various geological formations. This study focuses on analyzing the seismic wave attenuation characteristics in different geological formations to enhance the understanding of wave propagation mechanisms and improve seismic data interpretation. The research employs a combination of theoretical analysis, field measurements, and numerical modeling techniques to investigate the attenuation properties of seismic waves. Chapter One provides an introduction to the research topic, highlighting the significance of studying seismic wave attenuation and outlining the objectives of the study. The background of the study explores the existing knowledge about seismic wave attenuation and its implications for geophysical exploration. The problem statement identifies the gaps in current understanding and the need for further research in this area. The objectives of the study are to quantify the attenuation characteristics in different geological formations, identify factors influencing wave attenuation, and assess the implications for seismic data interpretation. Chapter Two presents a comprehensive literature review on seismic wave attenuation, covering key concepts, theories, and previous studies on the topic. The review examines different methods used to measure and analyze seismic wave attenuation, as well as the factors affecting attenuation in various geological materials. The literature review also discusses the importance of understanding seismic wave attenuation in seismic exploration and its applications in subsurface imaging. Chapter Three details the research methodology employed in this study, including field measurements, laboratory experiments, and numerical simulations. The chapter outlines the procedures for collecting seismic data, processing the data, and analyzing the attenuation characteristics of seismic waves in different geological formations. The research methodology aims to provide a systematic approach to investigating wave attenuation properties and validating the results through various experimental and computational techniques. Chapter Four presents a detailed discussion of the findings from the research, highlighting the variation in seismic wave attenuation across different geological formations. The chapter examines the influence of factors such as rock type, porosity, saturation, and frequency on wave attenuation properties. The discussion also addresses the implications of these findings for seismic data interpretation and the potential applications of seismic wave attenuation analysis in geophysical exploration. Chapter Five concludes the thesis by summarizing the key findings, discussing the implications of the research results, and suggesting directions for future studies. The conclusion highlights the significance of understanding seismic wave attenuation in improving seismic data quality and enhancing subsurface imaging capabilities. The study contributes valuable insights into the behavior of seismic waves in different geological formations and advances the knowledge of wave propagation mechanisms in geophysics. Overall, this thesis provides a comprehensive analysis of seismic wave attenuation in different geological formations, offering valuable insights into the factors influencing wave attenuation properties and their implications for geophysical exploration. The research findings contribute to the advancement of seismic data interpretation techniques and enhance the understanding of wave propagation characteristics in complex geological environments.

Thesis Overview