Project Abstract

This project aims to develop and investigate a new class of metal-organic frameworks (MOFs) for efficient gas adsorption and storage applications. Metal-organic frameworks are a rapidly growing class of porous materials that have garnered significant attention due to their exceptional surface areas, tunable pore sizes, and diverse chemical compositions, making them highly promising for a wide range of applications, including gas storage, catalysis, and environmental remediation. The increasing global demand for clean and sustainable energy sources, coupled with the need to mitigate the environmental impact of greenhouse gas emissions, has driven the search for efficient and cost-effective gas storage solutions. Traditional gas storage methods, such as high-pressure cylinders or cryogenic liquefaction, often suffer from limitations in terms of energy efficiency, safety, and scalability. In this context, MOFs offer a promising alternative, as their unique structural and chemical properties can be engineered to enhance the adsorption and storage of various gases, including hydrogen, methane, and carbon dioxide. The primary objective of this project is to synthesize and characterize novel MOFs with tailored properties for efficient gas adsorption and storage. The research will focus on the design and synthesis of MOFs with high surface areas, tunable pore sizes, and selective gas adsorption characteristics. A systematic approach will be adopted, involving the exploration of different metal centers, organic linkers, and synthetic conditions to optimize the MOF structures and their performance. The project will employ a range of advanced characterization techniques, such as X-ray diffraction, gas adsorption analysis, and spectroscopic methods, to elucidate the structural, textural, and chemical properties of the synthesized MOFs. These characterization studies will provide crucial insights into the underlying mechanisms governing the gas adsorption and storage capabilities of the MOFs. Additionally, the project will investigate the scalability and practical applicability of the developed MOFs. This will involve assessing their stability, recyclability, and performance under relevant operating conditions, as well as exploring potential strategies for large-scale production and integration into real-world gas storage systems. The successful completion of this project is expected to contribute significantly to the advancement of MOF-based technologies for efficient gas adsorption and storage. The novel MOFs developed in this study could pave the way for the development of safer, more cost-effective, and environmentally friendly gas storage solutions, with potential applications in the energy, transportation, and industrial sectors. Furthermore, the insights gained from this research can be leveraged to further expand the design and optimization of MOFs for a broader range of applications, such as catalysis, water purification, and carbon capture and utilization. The project's findings will be disseminated through peer-reviewed publications and presentations at scientific conferences, ensuring that the knowledge generated is shared with the scientific community and contributes to the ongoing progress in the field of MOF research and development.

Project Overview