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Single-Atom Pd Catalyst on a CeO<sub>2</sub> (111) Surface for Methane Oxidation: Activation Barriers and Reaction Pathways

Shalini Tomar, B. S. Bhadoria, Hojin Jeong, Joon Hwan Choi, Seung‐Cheol Lee, Satadeep Bhattacharjee

2024The Journal of Physical Chemistry C12 citationsDOI

Abstract

Employing density functional theory, we delved into the comprehensive pathways for methane oxidation on the Pd single atom supported with CeO 2 (111) encompassing sequential methane dehydrogenation, O 2 dissociation, and oxidation processes. The introduction of a Pd atom into CeO 2 (111) led to a reduction in the barrier for CH 4 dissociation to 0.50 eV. The methane dehydrogenation proceeded through a series of reactions: CH 4 → CH 3 → CH 2 → CH → C, with all dehydrogenation steps being exothermic except the CH 3 → CH 2 step. The O 2 dissociation reaction (O 2 → O* + O*) is thermodynamically exothermic, with a dissociation barrier of 2.12 eV over Pd@CeO 2 . Subsequently, the generation of CO 2 via the C* + O* and CO* + O* reactions is characterized by thermodynamically exothermic processes, with reaction energies of −1.20 and −1.01 eV, respectively. On the other hand, water production occurs through O* + H (an exothermic reaction) and OH* + H (an endothermic reaction) with reaction energies of −0.80 and +0.64 eV, respectively. These findings offer valuable insights into the potential pathways for single-atom catalysis involving transition metals supported on CeO 2 (111) in methane oxidation for industrial application.

Topics & Concepts

CatalysisMethaneAnaerobic oxidation of methaneAtom (system on chip)ChemistryMaterials scienceInorganic chemistryOrganic chemistryComputer scienceEmbedded systemCatalytic Processes in Materials ScienceCatalysis and Oxidation ReactionsElectrocatalysts for Energy Conversion