Unraveling the Surface State Evolution of IrO<sub>2</sub> in Ethane Chemical Looping Oxidative Dehydrogenation
Lulu Ping, Yuan Zhang, Baojun Wang, Maohong Fan, Lixia Ling, Riguang Zhang
Abstract
Based on the advantages of favorable thermodynamics and coking resistance of ethane oxidative dehydrogenation and the challenge of low ethylene selectivity, chemical looping oxidative dehydrogenation (CL-ODH) over the IrO 2 catalyst was examined, including the dehydrogenation and regeneration processes. The stoichiometric S-IrO 2 and reduced R-IrO 2 catalysts as two extreme states of the IrO 2 surface structure with dynamic changes were considered. Density functional theory (DFT) calculations and kinetic Monte Carlo simulations showed that the mechanisms of ethane dehydrogenation over S-IrO 2 and R-IrO 2 catalysts were quite different. Over the S-IrO 2 catalyst, ethane oxidative dehydrogenation to C 2 H 4 (g) with H 2 O(g), CO(g), and CO 2 (g) taking away surface lattice oxygen, followed by lattice oxygen migration from the bulk to the surface, leads to the reduction of the S-IrO 2 catalyst. Over the R-IrO 2 catalyst, ethane directly dehydrogenates to C 2 H 4 (g) and H 2 (g). Furthermore, the oxidation degree in the regeneration process is greater than the O v concentration in the dehydrogenation process, which can easily achieve oxygen replenishment in the regeneration process. More importantly, the IrO 2 catalyst can be neither completely reduced in the dehydrogenation process nor completely oxidized in the regeneration process, both S-IrO 2 and R-IrO 2 simultaneously exist for the IrO 2 catalyst, and both 750 K and 0.8 bar C 2 H 6 (g) pressure were obtained to be the optimal reaction conditions; thus, for ethane CL-ODH over the IrO 2 catalyst, the proposed mechanism starts from the oxidative dehydrogenation process; with the consumption of surface lattice oxygen and the oxygen migration from the bulk to the surface, the oxidative and nonoxidative dehydrogenations occur simultaneously until the regeneration. The present study broadens the understanding of ethane CL-ODH over metal oxide catalysts and provides valuable information for the optimization of the CL-ODH process and the development of other high-performance metal oxide catalysts in other alkane CL-ODH processes.