Project Abstract

This project aims to develop a new class of metal-organic frameworks (MOFs) with exceptional gas adsorption and separation capabilities. MOFs are a rapidly growing class of porous materials that have garnered significant attention due to their versatility, tunable structures, and potential applications in various fields, including gas storage, separation, catalysis, and sensing. The importance of this project lies in the pressing need for efficient and sustainable technologies to address global challenges related to energy, environmental protection, and industrial processes. Conventional gas separation methods, such as cryogenic distillation and pressure-swing adsorption, often suffer from high energy consumption, limited selectivity, and operational complexity. The development of novel MOF-based materials offers a promising solution to these challenges, as they can be designed to selectively adsorb and separate a wide range of gaseous species, including carbon dioxide, hydrogen, methane, and other industrially relevant gases. In this project, we will employ a rational design approach to synthesize and characterize a series of novel MOFs with tailored pore structures, surface functionalities, and adsorption properties. The synthesis will involve the use of carefully selected metal ions and organic linkers, allowing for the precise control of the MOF's structural and chemical features. A range of advanced characterization techniques, such as X-ray diffraction, nitrogen adsorption-desorption analysis, and spectroscopic methods, will be employed to thoroughly investigate the physicochemical properties of the synthesized MOFs. A key focus of this project will be the evaluation of the MOFs' gas adsorption and separation performance. Detailed studies will be conducted to assess the materials' capacity, selectivity, and kinetics for the adsorption of target gases, such as carbon dioxide, methane, and hydrogen. Particular attention will be paid to the development of MOFs with improved selectivity and high working capacities, crucial for practical applications in areas like carbon capture, natural gas purification, and hydrogen storage. Furthermore, the project will explore innovative strategies to enhance the stability and recyclability of the MOF adsorbents, ensuring their long-term viability and sustainability. This may involve incorporating functional groups, encapsulating active sites, or developing composite materials that combine the advantages of MOFs with other porous materials or membranes. The successful completion of this project will contribute to the advancement of MOF-based technologies for efficient gas adsorption and separation. The developed materials and knowledge gained through this research can have a significant impact on various industries, from energy and petrochemicals to environmental remediation and healthcare. The project's findings will be disseminated through peer-reviewed publications, conference presentations, and collaborations with industrial partners, fostering the translation of this research into practical applications. In summary, this project aims to push the boundaries of MOF design and development, creating novel materials that can revolutionize the way we approach gas separation and storage challenges. By leveraging the unique properties of MOFs, this research holds the potential to contribute to a more sustainable and efficient future.

Project Overview