(363p) Understanding Catalytic Systems By Integrating Experimental and Computational Techniques

In my current research, I delve into the fundamental mechanisms underlying N2O formation on Pt/Al2O3 catalysts, employing a dual approach that encompasses both experimental and computational methodologies. Through experimental techniques such as kinetic measurements and characterization, alongside computational tools including quantum calculations and kinetic modeling, I aim to unravel the intricacies of catalytic processes. This holistic understanding of catalyst systems not only facilitates enhanced reaction system optimization but also augments prediction capabilities, paving the way for more efficient and effective catalytic solutions. Leveraging my leadership experience as a Student Safety Representative on the UVA ChE Safety & Security Committee and my current involvement in the IDEA (Inclusion, Diversity, Equity, and Access) Committee, I advocate for a collaborative and inclusive research environment. I am committed to exploring innovative approaches that promote environmental sustainability and energy efficiency. I am flexible and adaptable, capable of contributing to interdisciplinary research efforts spanning both experimental and computational fields. I firmly believe that my adaptability and aptitude for rapid skill acquisition would position me as an asset in collaborative research initiatives aimed at developing advanced materials and processes that drive progress towards a cleaner and more sustainable future.

Research Interests: Looking forward, my research interests extend towards sustainable energy technologies, particularly in the realms of hydrogen combustion engines, battery research, fuel cells, and the broader field of fundamental catalysis.