Thesis Abstract

Abstract
Metal-organic frameworks (MOFs) have emerged as a fascinating class of porous materials with diverse applications, particularly in the field of gas adsorption. This thesis presents a comprehensive study on the synthesis and characterization of novel MOFs tailored for gas adsorption applications. The primary objective of this research is to design and fabricate MOFs with enhanced gas adsorption properties, focusing on their potential use in environmental remediation and gas storage. The thesis begins with an introduction that provides background information on MOFs and their significance in the field of materials science. The problem statement highlights the current challenges in gas adsorption technologies and the need for advanced materials with improved adsorption capacities. The objectives of the study are outlined to guide the research towards developing MOFs that exhibit superior gas adsorption performance. The limitations and scope of the study are discussed to delineate the boundaries of the research and define the extent to which the findings can be applied. The significance of the study is emphasized in terms of its potential contributions to the field of gas adsorption and environmental sustainability. The structure of the thesis is outlined, detailing the organization of chapters and sub-sections for a coherent presentation of the research work. Additionally, key terms and definitions relevant to the study are provided to enhance understanding. The literature review in Chapter Two critically examines existing research on MOFs for gas adsorption applications, covering topics such as synthesis methods, characterization techniques, and gas adsorption mechanisms. The review synthesizes information from various sources to establish a solid foundation for the current study. Chapter Three focuses on the research methodology employed to synthesize and characterize the novel MOFs. It includes detailed descriptions of the experimental procedures, materials used, and analytical techniques applied for structural and gas adsorption analyses. The chapter also discusses the optimization strategies employed to enhance the gas adsorption properties of the MOFs. In Chapter Four, the findings of the study are comprehensively discussed, highlighting the structural features and gas adsorption performance of the synthesized MOFs. The results are analyzed in relation to the research objectives, and the implications of the findings are discussed in the context of potential applications in gas storage and environmental remediation. Finally, Chapter Five presents the conclusion and summary of the thesis, summarizing the key findings, discussing the implications of the research, and suggesting potential avenues for future work in the field of MOFs for gas adsorption applications. The overall impact of the study on advancing the understanding and practical applications of MOFs in gas adsorption is underscored, concluding with a call to further explore the potential of these materials in addressing global energy and environmental challenges. In conclusion, this thesis contributes to the growing body of knowledge on MOFs and their applications in gas adsorption, offering insights into the design, synthesis, and characterization of novel MOFs for enhanced gas adsorption performance. The findings of this research have the potential to drive advancements in gas storage technologies and environmental sustainability, paving the way for the development of innovative materials with practical implications in various industrial and environmental settings.

Thesis Overview