Thesis Abstract

Abstract
The demand for efficient gas storage and separation technologies has driven the exploration of novel materials with tailored properties. Metal-organic frameworks (MOFs) have emerged as promising candidates due to their tunable structures and high surface areas. This thesis focuses on the synthesis and characterization of novel MOFs for gas adsorption applications, with a primary goal of enhancing gas storage capacities and selectivities. The introductory chapter provides an overview of the research background, highlighting the significance of MOFs in gas adsorption and the existing challenges in current gas storage technologies. The problem statement underscores the need for developing MOFs with improved gas adsorption properties to address the limitations of traditional materials. The objectives of this study include the synthesis of new MOFs with specific structural features optimized for gas adsorption, the characterization of these materials using various analytical techniques, and the evaluation of their gas adsorption capacities and selectivities. The limitations and scope of the study are outlined to define the boundaries and focus of the research. Chapter two presents a comprehensive literature review covering key concepts related to MOFs, gas adsorption mechanisms, and recent advancements in the synthesis and characterization of MOFs for gas storage applications. The review highlights the importance of optimizing MOF properties to enhance gas adsorption performance. Chapter three details the research methodology employed in this study, encompassing the synthesis of MOFs using different precursors and synthetic routes, the characterization of these materials through techniques such as X-ray diffraction, scanning electron microscopy, and gas adsorption measurements. The experimental procedures and data analysis methods are described in detail. Chapter four presents a detailed discussion of the findings obtained from the synthesis and characterization of the novel MOFs. The results of gas adsorption experiments are analyzed to assess the performance of the synthesized materials in terms of gas storage capacities and selectivities. The influence of MOF structure on gas adsorption properties is thoroughly examined. Finally, chapter five concludes the thesis by summarizing the key findings, discussing the implications of the research outcomes, and proposing future directions for advancing the field of MOF-based gas adsorption materials. The significance of the study in contributing to the development of efficient gas storage technologies is emphasized. In conclusion, this thesis contributes to the advancement of gas adsorption applications through the synthesis and characterization of novel MOFs with tailored properties. The insights gained from this research have the potential to pave the way for the design of next-generation materials for efficient gas storage and separation processes.

Thesis Overview