Thesis Abstract

Abstract
The demand for efficient gas adsorption materials has significantly increased due to environmental concerns and the need for sustainable energy sources. Metal-organic frameworks (MOFs) have emerged as promising candidates for gas adsorption applications, offering high surface areas and tunable properties. This thesis focuses on the synthesis and characterization of novel MOFs tailored for gas adsorption applications. The introduction sets the stage by highlighting the importance of MOFs in gas adsorption and outlining the objectives of the study. The background of the study provides a detailed overview of MOFs, their structures, and properties, emphasizing their potential in gas adsorption. The problem statement addresses the existing challenges in gas adsorption materials and the need for developing novel MOFs with enhanced adsorption properties. The objectives of the study aim to synthesize novel MOFs with specific properties conducive to gas adsorption, characterize their structures using various analytical techniques, and evaluate their performance in gas adsorption applications. The limitations of the study are acknowledged, including potential challenges in the synthesis and characterization of MOFs. The scope of the study encompasses the synthesis of MOFs using different metal ions and organic ligands, characterization using techniques such as X-ray diffraction and gas adsorption measurements, and evaluation of gas adsorption capacities for environmentally relevant gases. The significance of the study lies in the potential impact of novel MOFs on gas separation, storage, and catalysis, contributing to sustainable energy solutions. The structure of the thesis is outlined, detailing the chapters and their respective contents. The definitions of key terms used in the study provide clarity on terminology related to MOFs, gas adsorption, and characterization techniques. The literature review explores previous research on MOFs for gas adsorption, highlighting key findings, challenges, and advancements in the field. It discusses the synthesis methods, structural properties, and gas adsorption capacities of different MOFs reported in the literature. The research methodology section describes the experimental procedures for MOF synthesis, characterization techniques employed, and gas adsorption measurements conducted. It outlines the steps taken to achieve the objectives of the study, including materials used, experimental setup, and data analysis methods. The discussion of findings chapter presents the results of MOF synthesis and characterization, including structural analyses, surface area measurements, and gas adsorption isotherms. The findings are interpreted in relation to the study objectives, highlighting the performance of the synthesized MOFs in gas adsorption applications. In conclusion, the study contributes to the field of gas adsorption materials by synthesizing and characterizing novel MOFs tailored for specific gas adsorption applications. The summary highlights the key findings, implications of the study, and potential future research directions in the development of MOFs for gas adsorption. Overall, this thesis advances the understanding of MOFs for gas adsorption and demonstrates the potential of novel MOFs in addressing challenges in gas separation and storage, paving the way for sustainable energy solutions.

Thesis Overview