Thesis Abstract

Abstract
The design and synthesis of novel metal-organic frameworks (MOFs) for gas storage applications have garnered significant attention in recent years due to the potential of these materials to address energy and environmental challenges. This thesis presents a comprehensive investigation into the development of MOFs tailored specifically for gas storage, with a focus on enhancing gas adsorption capacity and selectivity. The research methodology employed a combination of computational modeling, synthesis techniques, and characterization methods to design and fabricate MOFs with optimized properties. Chapter One provides an introduction to the research topic, outlining the background of the study, the problem statement, objectives, limitations, scope, significance, and the structure of the thesis. The definitions of key terms used throughout the thesis are also provided to establish a common understanding of the concepts discussed. Chapter Two offers a detailed literature review encompassing ten key areas related to MOFs, gas storage, adsorption mechanisms, synthesis strategies, and applications. This section synthesizes existing knowledge in the field and identifies gaps that the current research aims to address. Chapter Three delves into the research methodology employed in this study, covering eight essential aspects such as computational modeling techniques, MOF synthesis methodologies, characterization techniques, gas adsorption measurements, and data analysis procedures. The systematic approach adopted in this research ensures the reliability and reproducibility of the results obtained. Chapter Four presents a thorough discussion of the findings obtained from the synthesis and characterization of the novel MOFs. The results are analyzed in relation to the research objectives, highlighting the key properties that influence gas adsorption performance. The chapter also explores the implications of the findings in advancing the field of MOFs for gas storage applications. Chapter Five serves as the conclusion and summary of the thesis, encapsulating the key findings, implications, and recommendations for future research directions. The contributions of this study to the field of MOF design for gas storage applications are highlighted, underscoring the significance of the novel frameworks developed and the potential impact on addressing energy and environmental challenges. In conclusion, this thesis contributes to the advancement of MOF research by designing and synthesizing novel frameworks tailored for enhanced gas storage applications. The insights gained from this study pave the way for further exploration in optimizing MOF properties for specific gas adsorption requirements, opening new avenues for sustainable energy storage solutions.

Thesis Overview