Investigations of the Effect of H2 in CO Oxidation over Ceria Catalysts

The preferential CO oxidation (so-called CO-PROX) is the selective CO oxidation amid H2-rich atmospheres, a process where ceria-based materials are consolidated catalysts. This article aims to disentangle the potential CO–H2 synergism under CO-PROX conditions on the low-index ceria surfaces (111), (...

Full description

Saved in:
Bibliographic Details
Published in:Catalysts 2021-12, Vol.11 (12), p.1556
Main Authors: Davó-Quiñonero, Arantxa, López-Rodríguez, Sergio, Chaparro-Garnica, Cristian, Martín-García, Iris, Bailón-García, Esther, Lozano-Castelló, Dolores, Bueno-López, Agustín, García-Melchor, Max
Format: Article
Language:English
Subjects:
Adsorption
Carbon monoxide
Carbonates
Carbonation
Catalysts
Cerium oxides
Chemical reactions
CO oxidation
CO-PROX
Density functional theory
Depletion
DFT calculations
DRIFTS
Fourier transforms
Hydroxyl groups
Hypotheses
Kinetics
nano-shaped ceria
Nanorods
Oxidation
reaction mechanism
Room temperature
Spectrum analysis
Surface defects
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The preferential CO oxidation (so-called CO-PROX) is the selective CO oxidation amid H2-rich atmospheres, a process where ceria-based materials are consolidated catalysts. This article aims to disentangle the potential CO–H2 synergism under CO-PROX conditions on the low-index ceria surfaces (111), (110) and (100). Polycrystalline ceria, nanorods and ceria nanocubes were prepared to assess the physicochemical features of the targeted surfaces. Diffuse reflectance infrared Fourier-transformed spectroscopy (DRIFTS) shows that ceria surfaces are strongly carbonated even at room temperature by the effect of CO, with their depletion related to the CO oxidation onset. Conversely, formate species formed upon OH + CO interaction appear at temperatures around 60 °C and remain adsorbed regardless the reaction degree, indicating that these species do not take part in the CO oxidation. Density functional theory calculations (DFT) reveal that ceria facets exhibit high OH coverages all along the CO-PROX reaction, whilst CO is only chemisorbed on the (110) termination. A CO oxidation mechanism that explains the early formation of carbonates on ceria and the effect of the OH coverage in the overall catalytic cycle is proposed. In short, hydroxyl groups induce surface defects on ceria that increase the COx–catalyst interaction, revealed by the CO adsorption energies and the stabilization of intermediates and readsorbed products. In addition, high OH coverages are shown to facilitate the hydrogen transfer to form less stable HCOx products, which, in the case of the (110) and (100), is key to prevent surface poisoning. Altogether, this work sheds light on the yet unclear CO–H2 interactions on ceria surfaces during CO-PROX reaction, providing valuable insights to guide the design of more efficient reactors and catalysts for this process.
ISSN:2073-4344
2073-4344
DOI:10.3390/catal11121556