Abstract
Exploring active and low-cost spinel catalysts for complete methane oxidation is essential for the development of efficient air purification technologies. Herein, a series of spinel oxides ZnNixCo2-xO4 (x = 0–0.8) were synthesized to investigate the origin of their electronic structure dependent activities and mechanisms for methane oxidation. The interplay between O p-band center and Moctd-band center was found to be responsible for the methane oxidation activity. Ni-poor ZnNixCo2-xO4 spinels with the Moctd-band center positioned higher relative to the O p-band center, exhibited greater metal character, indicative of a dissociative adsorbed oxygen featured suprafacial Eley-Rideal (E-R) model. In contrast, Ni-rich ZnNixCo2-xO4 with the O p-band center in a higher position relative to the Moctd-band center, displayed greater oxygen character, predominated by the intrafacial Mars-van-Krevelen (Mv-K) mechanism featuring the involvement of lattice oxygen. These findings may provide steps towards the rational design of better spinel oxides for catalytic oxidation reactions.
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