Controlling Moisture for Enhanced Ozone Decomposition: A Study of Water Effects on CeO2 Surfaces and Catalytic Activity

Abstract

This study investigates the catalytic degradation of ground-level ozone on low-index stoichiometric and reduced CeO2 surfaces using first-principles calculations. The presence of oxygen vacancies on the surface enhances the interaction between ozone and catalyst by serving as active sites for adsorption and decomposition. Our results suggest that the 111 surface has superior ozone decomposition performance due to unstable oxygen species resulting from reaction with catalysts. However, when water is present, it competes with ozone molecules for these active sites, resulting in reduced catalytic activity or water poisoning. A possible solution could be heat treatment that reduces the vacancy concentration, thereby increasing the available adsorption sites for ozone molecules while minimizing competitive adsorption by water molecules. These results suggest that controlling moisture content during operation is crucial for the efficient use of CeO2-based catalysts in industrial applications to reduce ground-level ozone pollution.