The role of autoreduction and of oxygen mobility in N2O decomposition over Fe-ZSM-5

The mechanism of N2O decomposition was studied on a series of Fe-ZSM-5 catalysts prepared by ion exchange (IE) and chemical vapor deposition (CVD). N2O decomposition activity depends strongly on the extent of autoreduction of the catalyst during the pretreatment in He at high temperatures. The extent of autoreduction is significantly lower for catalysts prepared by CVD compared with that for catalysts prepared by aqueous ion exchange. As a result, the global turnover frequencies of the ion-exchanged catalysts are significantly higher. If the activity is normalized by the concentration of Fe2+ sites, however, then the CVD catalyst is the most active sample. This is attributed to the fact that high iron loading favors the surface migration and recombination of surface oxygen atoms to O2, which is the rate-limiting step of the reaction. O2 formation by slow recombination of two surface oxygen atoms is the dominating mechanism even for IE samples with very low iron loadings.