Thesis Abstract

Abstract
Metal-organic frameworks (MOFs) have emerged as promising materials for various applications due to their tunable properties and high surface areas. This thesis presents the synthesis and characterization of novel MOFs specifically designed for gas adsorption applications. The research focuses on developing MOFs with enhanced gas adsorption capacities and selectivities for potential use in gas storage, separation, and sensing applications. The introduction section provides a background of MOFs, highlighting their unique structural features and potential applications in gas adsorption. The problem statement underscores the need for novel MOFs with improved gas adsorption properties to address challenges in gas storage and separation technologies. The objectives of the study are outlined to guide the research towards developing MOFs with superior gas adsorption capabilities. The literature review chapter critically evaluates existing research on MOFs for gas adsorption, covering topics such as synthesis methods, characterization techniques, gas adsorption mechanisms, and applications in gas storage and separation. The review identifies gaps in current knowledge and research opportunities for developing advanced MOFs tailored for gas adsorption applications. The research methodology chapter details the experimental procedures employed for the synthesis, characterization, and evaluation of the novel MOFs. It includes information on synthesis techniques, characterization methods (such as X-ray diffraction, scanning electron microscopy, and gas adsorption measurements), and data analysis approaches used to assess the gas adsorption performance of the MOFs. The discussion of findings chapter presents the results of the experimental investigations, including the structural properties, surface areas, pore volumes, and gas adsorption capacities of the synthesized MOFs. The findings are analyzed to elucidate the relationship between MOF structure and gas adsorption performance, highlighting the key factors influencing gas adsorption selectivity and capacity. Finally, the conclusion and summary chapter provide a comprehensive overview of the research outcomes, emphasizing the significance of the developed MOFs for gas adsorption applications. The conclusions drawn from the study contribute to the advancement of MOF research in the field of gas adsorption and provide insights for future research directions and applications of MOFs in gas storage, separation, and sensing technologies. In summary, this thesis presents a systematic study on the synthesis and characterization of novel MOFs tailored for gas adsorption applications. The research outcomes contribute to the development of advanced materials with enhanced gas adsorption properties, offering new opportunities for addressing challenges in gas storage, separation, and sensing applications.

Thesis Overview