Research

A significant portion of my research is dedicated to advancing CO2 capture technologies, specifically through the development of functionalized mesoporous materials. These materials are designed to selectively adsorb and convert CO2 from ambient air or industrial emissions. My work explores the use of amine-impregnated materials and ionic liquids, optimizing adsorption capacity, selectivity, and regeneration processes. Through my contributions, I aim to facilitate the large-scale capture and conversion of CO2 into valuable products, such as fuels and chemicals, as part of a sustainable carbon cycle. 

In parallel, my research focuses on hydrogen energy, particularly in the areas of hydrogen production, storage, and fuel cell technology. I have worked extensively on hydrogen generation from ammonia borane and the development of materials that enhance hydrogen separation in fuel cells. By improving the efficiency of hydrogen production methods and developing new membranes for selective gas separation, my goal is to contribute to the development of cleaner, more efficient hydrogen energy systems.

Beyond material development, I have contributed to the design and development of new instruments aimed at improving the efficiency and selectivity of gas separation processes. This innovative approach allows for more precise control over experimental parameters and enhances the overall performance of gas separation membranes used in various applications, including CO2 capture and hydrogen production.