Thesis Abstract

Abstract
The utilization of Ground-Penetrating Radar (GPR) in environmental site assessment has gained significant attention in recent years due to its non-invasive nature and high-resolution imaging capabilities. This thesis explores the application of GPR technology in detecting subsurface features for environmental site assessment purposes. The study aims to assess the effectiveness of GPR in identifying potential underground contaminants, geological structures, and archaeological artifacts within a given site. The research methodology involved a comprehensive literature review to understand the principles and applications of GPR technology, as well as its limitations and challenges. Field experiments were conducted using a GPR system to collect data at various test sites with known subsurface features. Data processing techniques, including signal analysis and imaging, were applied to interpret the GPR results and identify subsurface anomalies. The findings from the study revealed that GPR technology is a valuable tool for detecting subsurface features in environmental site assessment. The high-resolution images generated by the GPR system provided detailed information about the subsurface layers, including the depth and spatial distribution of anomalies. The study also highlighted the importance of proper data interpretation and integration with other geophysical methods to enhance the accuracy and reliability of the results. The discussion of the findings emphasized the significance of GPR technology in environmental site assessment, particularly in identifying potential environmental hazards and archaeological resources. The limitations of GPR technology, such as depth penetration and data interpretation challenges, were also addressed, highlighting the need for careful consideration and validation of results. In conclusion, the study demonstrates the effectiveness of GPR technology in detecting subsurface features for environmental site assessment. The thesis contributes to the existing body of knowledge on the application of GPR in environmental studies and provides valuable insights for future research and practical applications. Overall, the findings support the use of GPR as a reliable and efficient tool for non-invasive subsurface investigation in environmental site assessment projects.

Thesis Overview

The research project titled "Application of Ground-Penetrating Radar (GPR) in Detecting Subsurface Features for Environmental Site Assessment" focuses on the utilization of Ground-Penetrating Radar technology in the field of geophysics for environmental site assessment purposes. Ground-Penetrating Radar (GPR) is a non-invasive geophysical method that uses electromagnetic radiation to image the subsurface features without the need for excavation. This technology has been widely used in various fields such as geology, archaeology, civil engineering, and environmental science. The primary objective of this research is to investigate the effectiveness and reliability of GPR in detecting subsurface features relevant to environmental site assessment. The study aims to explore how GPR can be employed to identify potential environmental hazards, map underground structures, and assess soil and groundwater conditions. By utilizing GPR technology, the research seeks to enhance the accuracy, efficiency, and cost-effectiveness of environmental site assessments compared to traditional methods. The research will include a comprehensive literature review to examine existing studies, methodologies, and applications of GPR in environmental site assessment. The methodology will involve field surveys using GPR equipment at selected test sites to gather data on subsurface features. Data processing and analysis techniques will be employed to interpret the GPR results and generate subsurface images for further evaluation. The findings of this research will contribute to the body of knowledge in geophysics and environmental science by providing insights into the capabilities and limitations of GPR technology for environmental site assessment. The results will be used to assess the potential environmental benefits of using GPR as a tool for detecting subsurface features, identifying contamination sources, and evaluating remediation strategies. Overall, this research project aims to demonstrate the significance of Ground-Penetrating Radar technology in enhancing environmental site assessment practices. By integrating GPR into the assessment process, environmental professionals can make more informed decisions regarding land use, site development, and environmental management strategies.