Dr. Wang receives CAREER Award
In the chemical industry, controlling selectivity of a chemical conversion process is important because the presence of multiple products may complicate the separation process, leading to intensive energy cost. Dissipation of energy drives chemical transformation in a catalytic process, such as ammonia synthesis. In most cases, however, it is challenging to control the flow of thermal energy into a specific location, such as a chemical bond for its reaction.
“The DOE Early Career award is partly in recognition of the important work that Bin has already done in the field of computational modeling of complex chemical systems. It is one of the highest honors a young faculty member can receive. We look forward to him doing great things in the future,” said Brian P. Grady, CBME director.
Dr. Wang’s research will deliver essential details that will allow for design of an all-optical process of chemical transformation at low temperatures with high chemical selectivity. His research will provide fundamental understanding of the light-driven reaction at the molecular level. Using modern computational theory, he proposes to control precisely both energies and locations of the positive and negative charges by positioning them in microporous materials and liquid solvents. These varied environments may help localize the positive and negative charges that accelerate bond dissociation and formation.
Introduction of the light-sensitive solid materials into catalysis provides a powerful strategy for reaching high selectivity. In this process, positive and negative charges stimulate the dynamics of the chemical bonds in the reactants. In addition, the light-driven reaction can be operated at lower temperature compared to thermal reactions. For more information about Dr. Wang’s DOE Early Career Research Program award and his research contact wang_cbme@ou.edu.
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