Abstract: MeOx/CeO2 (Me = Fe, Co, Ni) samples were tested in an 18O2 temperature-programmed isotope exchange and N2O decomposition (deN2O). A decrease in the rate of deN2O in the presence of oxygen evidences the competitive adsorption of N2O and O2 on the same sites. A study of isotope oxygen exchange revealed dissociative oxygen adsorption with the subsequent formation of surface oxygen species. The same species, more probably, result from N2O adsorption and the following N2 evolution to the gas phase. We supposed the same mechanism of O2 formation from surface oxygen species in both reactions, including the stages responsible for its mobility. A detailed analysis of the kinetics of isotope exchange has been performed, and the rates of one-atom (RI) and two-atom (RII) types of exchange were evaluated. The rate of the stage characterizing the mobility of surface oxygen was calculated, supposing the same two-step mechanism was relevant for both types of exchange. The effect of oxygen mobility on the kinetics of deN2O was estimated. An analysis of the possible pathways of isotope transfer from MeOx to CeOx showed that direct oxygen exchange on the Me–Ce interface makes a valuable contribution to the rate of this reaction. The principal role of the Me–Ce interface in deN2O was confirmed with independent experiments on FeOx/CeO2 samples with a different iron content.

Cite: Sadovskaya E. , Pinaeva L. , Skazka V. , Prosvirin I.
Kinetics of Oxygen Exchange and N2O Decomposition Reaction over MeOx/CeO2 (Me = Fe, Co, Ni) Catalysts
Materials. 2023. V.16. 929 :1-21. DOI: 10.3390/ma16030929 WOS Scopus РИНЦ AN PMID OpenAlex

Dates:

Submitted:	Dec 22, 2022
Accepted:	Jan 16, 2023
Published print:	Jan 18, 2023
Published online:	Jan 18, 2023

Identifiers:

Web of science:	WOS:000933751300001
Scopus:	2-s2.0-85147851085
Elibrary:	53952112
Chemical Abstracts:	2023:315137
PMID:	36769936
OpenAlex:	W4317503555

Citing:

DB	Citing
Scopus	4
Web of science	4
Elibrary	3
OpenAlex	4

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