Nitrous oxide decomposition and temperature programmed desorption tests on Fe–ZSM-5 and Fe–silicalite show that the catalytic conversion mechanism of N2O into N2 and O2 over Fe–zeolites is more complex than expected. Nitrogen oxides are formed as byproducts of the catalytic process with the major part consisting in NO2 species adsorbed on the iron sites. FTIR spectroscopy of adsorbed N2O, NO, and NO2 has been used to investigate the structure and environment of the iron active species of the Fe–MFI catalysts before and after atomic oxygen deposition. The interactions of NO and N2O probes on activated Fe–ZSM-5 have evidenced two families of mononuclear Fe(II) centers (FeA and FeB) differing in the coordination state of Fe. N2O also interacts with Brønsted sites of Fe–ZSM-5 via hydrogen bonding. This type of interaction is nearly absent in Fe–silicalite. Polynuclear species (clusters) and iron oxide particles, whose concentrations are strongly influenced by the iron content and by the preparation methods are also present. When oxidized samples (by N2O) are considered, the ability of FeA and FeB centers to adsorb N2O and NO is strongly depressed. On the contrary, the surface chemistry of iron particles is not appreciably influenced. These results represent an indirect proof of the preferential presence of adsorbed oxygen on isolated Fe centers. NO titration of oxidized Fe–ZSM-5 results in the formation of a complex network of interplaying neutral (NO, NO2, N2O4) and ionic species (NO+, , ). The cooperation of sites between Brønsted and iron active sites is demonstrated. The last observation is fully confirmed by the experiments performed using NO2 probe that titrates both Brønsted and iron sites. On the basis of the comparison of catalytic results of N2O decomposition and of spectroscopic results concerning the titration of surface sites with N2O, NO, and NO2 obtained on the same samples (which form the main scope of the paper), it clearly emerges that mononuclear sites characterized by lowest coordination are the most active in N2O decomposition. Under the adopted conditions, low or negligible activity is shown by FexOy clusters and Fe2O3 particles.
Reactivity of nitrogen oxides (NO2, NO, N2O) on Fe-zeolites
RIVALLAN, MICKAEL;RICCHIARDI, Gabriele;BORDIGA, Silvia;ZECCHINA, Adriano
2009-01-01
Abstract
Nitrous oxide decomposition and temperature programmed desorption tests on Fe–ZSM-5 and Fe–silicalite show that the catalytic conversion mechanism of N2O into N2 and O2 over Fe–zeolites is more complex than expected. Nitrogen oxides are formed as byproducts of the catalytic process with the major part consisting in NO2 species adsorbed on the iron sites. FTIR spectroscopy of adsorbed N2O, NO, and NO2 has been used to investigate the structure and environment of the iron active species of the Fe–MFI catalysts before and after atomic oxygen deposition. The interactions of NO and N2O probes on activated Fe–ZSM-5 have evidenced two families of mononuclear Fe(II) centers (FeA and FeB) differing in the coordination state of Fe. N2O also interacts with Brønsted sites of Fe–ZSM-5 via hydrogen bonding. This type of interaction is nearly absent in Fe–silicalite. Polynuclear species (clusters) and iron oxide particles, whose concentrations are strongly influenced by the iron content and by the preparation methods are also present. When oxidized samples (by N2O) are considered, the ability of FeA and FeB centers to adsorb N2O and NO is strongly depressed. On the contrary, the surface chemistry of iron particles is not appreciably influenced. These results represent an indirect proof of the preferential presence of adsorbed oxygen on isolated Fe centers. NO titration of oxidized Fe–ZSM-5 results in the formation of a complex network of interplaying neutral (NO, NO2, N2O4) and ionic species (NO+, , ). The cooperation of sites between Brønsted and iron active sites is demonstrated. The last observation is fully confirmed by the experiments performed using NO2 probe that titrates both Brønsted and iron sites. On the basis of the comparison of catalytic results of N2O decomposition and of spectroscopic results concerning the titration of surface sites with N2O, NO, and NO2 obtained on the same samples (which form the main scope of the paper), it clearly emerges that mononuclear sites characterized by lowest coordination are the most active in N2O decomposition. Under the adopted conditions, low or negligible activity is shown by FexOy clusters and Fe2O3 particles.
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