Oxygen effect in NO direct decomposition over K/Co-Mg-Mn-Al mixed oxide catalyst–Temperature programmed desorption study.

Pacultová, K.; Klegová, A.; Karásková, K.; Fridrichová, D.; Bílková, T.; Koštejn, Martin; Obalová, L.

doi:https://dx.doi.org/10.1016/j.mcat.2021.111695

Number of the records: 1

Oxygen effect in NO direct decomposition over K/Co-Mg-Mn-Al mixed oxide catalyst–Temperature programmed desorption study.

1.

SYSNO ASEP	0543504
Document Type	J - Journal Article
R&D Document Type	Journal Article
Subsidiary J	Článek ve WOS
Title	Oxygen effect in NO direct decomposition over K/Co-Mg-Mn-Al mixed oxide catalyst–Temperature programmed desorption study.
Author(s)	Pacultová, K. (CZ) Klegová, A. (CZ) Karásková, K. (CZ) Fridrichová, D. (CZ) Bílková, T. (CZ) Koštejn, Martin (UCHP-M)_{RID, SAI, ORCID} Obalová, L. (CZ)
Article number	111695
Source Title	Molecular Catalysis. - : Elsevier - ISSN 2468-8231 Roč. 510, JUN 2021 (2021)
Number of pages	16 s.
Language	eng - English
Country	NL - Netherlands
Keywords	mechanism ; mixed oxide ; oxygen effect ; NO
Subject RIV	CI - Industrial Chemistry, Chemical Engineering
OECD category	Chemical process engineering
R&D Projects	GA18-19519S GA ČR - Czech Science Foundation (CSF)
Method of publishing	Open access with time embargo (01.07.2023)
Institutional support	UCHP-M - RVO:67985858
UT WOS	000713699300002
EID SCOPUS	85108300444
DOI	10.1016/j.mcat.2021.111695
Annotation	Co-Mg-Mn-Al mixed oxide with or without K was prepared and characterized by XPS, TPR H2, TPD NO, TPD O2 and TPD NO+O2. NO decomposition was performed over catalyst activated in different atmosphere (N2, He, O2). Presence of oxygen during activation changed the course of surface stabilization but did not affect NO conversion achieved at steady state. O2 desorbed as a reaction product does not affect the reaction rate for NO inlet concentration of 400 - 8000 ppm, but presence of O2 in inlet gas mixture (0.05 - 3 mol.%) has significant inhibiting effect. Transition metals in octahedral coordination represent sites for NO chemisorption, while potassium ensures NO oxidation to surface nitrites, which are indispensable reactive species. Oxygen desorption was the slowest reaction step, while N2 desorption was fast. Oxygen inhibition was ascribed to oxidation of NO* species on the octahedral Co3+ and Mn3+ to more stable surface nitrates making NO* species as limiting reactant.
Workplace	Institute of Chemical Process Fundamentals
Contact	Eva Jirsová, jirsova@icpf.cas.cz, Tel.: 220 390 227
Year of Publishing	2022
Electronic address	http://hdl.handle.net/11104/0320699

Number of the records: 1