DFT and kinetic evidences of the preferential CO oxidation pattern of manganese dioxide catalysts in hydrogen stream (PROX)

The oxidation functionality of Mn(IV) sites has been assessed by density functional theory (DFT) analysis of adsorption and activation energies of CO, H-2 and O-2 on a model Mn4O8 cluster. DFT calculations indicate that Mn (IV) atoms prompt an easy CO conversion to CO2 via a reaction path involving both catalyst and gas-phase oxygen species, while much greater energy barriers hinder H-2 oxidation. Accordingly, a MnCeOx catalyst (Mn-at/Ce-at, 5) with large exposure of Mn(IV) sites shows a remarkable CO oxidation performance at T >= 293 K and no H-2 oxidation activity below 393 K. Empiric kinetics disclose that the catalyst-oxygen abstraction step determines both CO and H-2 oxidation rate, although different activation energies favor the preferential oxidation (PROX) pattern of the studied catalyst (353-423 K). Conversion-selectivity of 100%, high stability during 72 h reaction time and moderate inhibiting effects of water and CO2 feeding reveal the potential of MnO2 materials as efficient, low-cost and robust PROX catalysts.

Automated summary

The study revealed that Mn(IV) sites facilitate the conversion of CO to CO2, with MnCeOx catalysts having a high exposure of Mn(IV) sites showing exceptional CO oxidation performance. However, the oxidation activity of H-2 is limited. Empirical findings suggest that MnO2 materials have the potential to be efficient and robust PROX catalysts.