Open AccessDemystifying the Atomistic Origin of the Electric Field Effect on Methane Oxidation
Author(s) -
Christopher Panaritis,
Yasmine M. Hajar,
Laureline Treps,
Carine Michel,
Elena A. Baranova,
Stephan N. Steinmann
Publication year - 2020
Publication title -
the journal of physical chemistry letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.563
H-Index - 203
ISSN - 1948-7185
DOI - 10.1021/acs.jpclett.0c01485
Subject(s) - catalysis , methane , electric field , electrochemistry , anaerobic oxidation of methane , oxide , polarization (electrochemistry) , platinum , chemical physics , materials science , oxygen , electrode , faraday efficiency , inorganic chemistry , chemistry , metal , density functional theory , chemical engineering , computational chemistry , organic chemistry , metallurgy , physics , quantum mechanics , engineering
Understanding the role of an electric field on the surface of a catalyst is crucial in tuning and promoting the catalytic activity of metals. Herein, we evaluate the oxidation of methane over a Pt surface with varying oxygen coverage using density functional theory. The latter is controlled by the electrode polarization, giving rise to the non-Faradaic modification of catalytic activity phenomenon. At -1 V, the Pt(111) surface is present, while at 1 V, α-PtO 2 on Pt(111) takes over. Our results demonstrate that the alteration of the platinum oxide surface under the influence of an electrochemical potential promotes the catalytic activity of the metal oxides by lowering the activation energy barrier of the reaction.
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