Exceptional Low-Temperature CO Oxidation over Noble-Metal-Free Iron-Doped Hollandites: An In-Depth Analysis of the Influence of the Defect Structure on Catalytic Performance

International audience ; A family of iron-doped manganese-related hollandites, K x Mn 1−y Fe y O 2−δ (0 ≤ y ≤ 0.15), with high performance in CO oxidation have been prepared. Among them, the most active catalyst, K 0.11 Mn 0.876 Fe 0.123 O 1.80 (OH) 0.09 , is able to oxidize more than 50% of CO at room temperature. Detailed compositional and structural characterization studies, using a wide battery of thermogravimetric, spectroscopic, and diffractometric techniques, both at macroscopic and microscopic levels, have provided essential information about this never-reported behavior, which relates... Mehr ...

Verfasser: Gómez-Recio, Isabel
Pan, Huiyan
Azor-Lafarga, Alberto
Ruiz-González, María Luisa
Hernando, María
Parras, Marina
Fernández-Díaz, María Teresa
Delgado, Juan, J
Chen, Xiaowei
Goma Jiménez, Daniel
Portehault, David
Sanchez, Clément
Cabero, Mariona
Martínez-Arias, Arturo
González-Calbet, José, M
Calvino, José, J
Dokumenttyp: Artikel
Erscheinungsdatum: 2021
Verlag/Hrsg.: HAL CCSD
Schlagwörter: hollandites / Fe modification / CO oxidation / defect structure / atomic scale analysis / [CHIM]Chemical Sciences / [CHIM.CATA]Chemical Sciences/Catalysis / [CHIM.MATE]Chemical Sciences/Material chemistry
Sprache: Englisch
Permalink: https://search.fid-benelux.de/Record/base-29079256
Datenquelle: BASE; Originalkatalog
Powered By: BASE
Link(s) : https://hal.science/hal-03561017

International audience ; A family of iron-doped manganese-related hollandites, K x Mn 1−y Fe y O 2−δ (0 ≤ y ≤ 0.15), with high performance in CO oxidation have been prepared. Among them, the most active catalyst, K 0.11 Mn 0.876 Fe 0.123 O 1.80 (OH) 0.09 , is able to oxidize more than 50% of CO at room temperature. Detailed compositional and structural characterization studies, using a wide battery of thermogravimetric, spectroscopic, and diffractometric techniques, both at macroscopic and microscopic levels, have provided essential information about this never-reported behavior, which relates to the oxidation state of manganese. Neutron diffraction studies evidence that the above compound stabilizes hydroxyl groups at the midpoints of the tunnel edges as in isostructural β-FeOOH. The presence of oxygen and hydroxyl species at the anion sublattice and Mn 3+ , confirmed by electron energy loss spectroscopy, appears to play a key role in the catalytic activity of this doped hollandite oxide. The analysis of these detailed structural features has allowed us to point out the key role of both OH groups and Mn 3+ content in these materials, which are able to effectively transform CO without involving any critical, noble metal in the catalyst formulation.