Thesis Abstract

Abstract
The study on the "Application of Electrical Resistivity Tomography for Subsurface Imaging" aimed to investigate the effectiveness of this geophysical method in imaging subsurface structures and materials. The research was motivated by the need for accurate subsurface imaging techniques in various fields such as environmental studies, geotechnical engineering, mineral exploration, and archaeology. The primary objective was to assess the capabilities of electrical resistivity tomography (ERT) in mapping subsurface features and to determine its limitations and challenges. The thesis begins with an introduction that provides an overview of the research background, problem statement, objectives, limitations, scope, significance, structure of the thesis, and definition of terms. The literature review in Chapter Two covers ten key aspects related to ERT, including principles of resistivity imaging, instrumentation, data acquisition, data processing, interpretation techniques, applications in different fields, case studies, advantages, limitations, and current trends in ERT technology. Chapter Three details the research methodology employed in the study, including the selection of study areas, data collection procedures, equipment used, data processing and interpretation methods, quality control measures, and validation techniques. The chapter also discusses the challenges faced during data collection and analysis and the strategies adopted to overcome them. The research methodology section comprises eight key contents that provide a comprehensive overview of the experimental procedures and analytical techniques used in the study. Chapter Four presents a detailed discussion of the findings obtained from the application of ERT in subsurface imaging. The results are analyzed and interpreted to evaluate the effectiveness of ERT in mapping subsurface structures, identifying anomalies, and characterizing different geological formations. The chapter also discusses the limitations and uncertainties associated with ERT data interpretation and proposes recommendations for improving the accuracy and reliability of ERT imaging results. The concluding chapter, Chapter Five, summarizes the key findings of the study and provides insights into the implications of the research outcomes. The conclusion highlights the strengths and weaknesses of ERT as a subsurface imaging technique and discusses the potential areas for further research and development in this field. The thesis concludes with recommendations for future studies and practical applications of ERT in subsurface imaging projects. In conclusion, the thesis on the "Application of Electrical Resistivity Tomography for Subsurface Imaging" contributes to the existing knowledge on geophysical methods for subsurface investigation and provides valuable insights into the capabilities and limitations of ERT technology. The research findings have significant implications for various disciplines that rely on subsurface imaging techniques, and the recommendations made in this study can guide future research and development in the field of geophysics.

Thesis Overview