Thesis Abstract

Abstract
The demand for efficient gas separation technologies has become increasingly significant in industrial processes, environmental protection, and energy production. Metal-organic frameworks (MOFs) have emerged as promising materials for gas separation applications due to their tunable structures and exceptional properties. This thesis focuses on the synthesis and characterization of novel MOFs tailored for gas separation purposes. The primary objective is to explore the potential of these MOFs in enhancing gas separation efficiency and selectivity. The introductory chapter provides a comprehensive overview of the research context, highlighting the importance of gas separation technologies, the limitations of existing methods, and the potential of MOFs in addressing these challenges. The background of the study delves into the fundamental principles of MOFs, their unique properties, and their applications in gas separation processes. The problem statement identifies the gaps in current gas separation technologies and sets the stage for the research objectives. The objectives of the study aim to synthesize novel MOFs with enhanced gas separation properties, characterize their structural and adsorption properties, evaluate their performance in gas separation experiments, and compare them with existing materials. The limitations of the study acknowledge the constraints and challenges encountered during the experimental work, while the scope of the study defines the boundaries and focus of the research. The significance of the study lies in the potential impact of the developed MOFs on improving the efficiency and sustainability of gas separation processes in various industries. By elucidating the structure-property relationships of the synthesized MOFs, this research contributes to the fundamental understanding of MOF-based gas separation mechanisms. The literature review chapter critically examines existing studies on MOFs for gas separation applications, covering topics such as synthesis methods, characterization techniques, gas adsorption mechanisms, and separation performance metrics. The research methodology chapter outlines the experimental procedures, materials, instruments, and analytical techniques used in synthesizing and characterizing the novel MOFs. The findings discussion chapter presents a detailed analysis of the experimental results, including the structural properties, gas adsorption capacities, selectivity, and permeability of the synthesized MOFs. The discussion highlights the key insights gained from the study and compares the performance of the novel MOFs with benchmark materials. In conclusion, this thesis demonstrates the successful synthesis and characterization of novel MOFs tailored for gas separation applications. The results indicate that the developed MOFs exhibit promising gas separation performance, with enhanced selectivity and adsorption capacities. The potential of these MOFs to address the challenges of current gas separation technologies is evident, laying the foundation for further research and development in this field.

Thesis Overview