External Electric Field Catalyzed N2O Decomposition on Mn-Embedded Graphene

Adsorption ability and reaction rate are two essential parameters that define the efficiency of a catalyst. Herein, we study the effects of the external electric field F on the catalytic decomposition of N2O on a Mn-embedded graphene system (Mn/graphene) based on density functional theory calculatio...

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Bibliographic Details
Published in:Journal of physical chemistry. C 2012-09, Vol.116 (38), p.20342-20348
Main Authors: Song, E. H, Yan, J. M, Lian, J. S, Jiang, Q
Format: Article
Language:English
Online Access:Get full text
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Summary:Adsorption ability and reaction rate are two essential parameters that define the efficiency of a catalyst. Herein, we study the effects of the external electric field F on the catalytic decomposition of N2O on a Mn-embedded graphene system (Mn/graphene) based on density functional theory calculations. Our study demonstrates that Mn/graphene has a better adsorption ability than the corresponding typical catalysts, such as platinum group metals, while the appropriate positive F can make the N2O decomposition spontaneously occur via a two-step mechanism of N2O → N2 + O and N2O + O → N2 + O2. In addition, F simultaneously facilitates O2 desorption and regeneration of the Mn/graphene system, completing the whole catalytic cycle. The high synergetic catalytic effect may be attributed to that F induces an enhancement of the charge transfer between N2O and Mn/graphene. Thus, the Mn/graphene system together with the synergy of F is a good candidate for N2O adsorptive decomposition.
ISSN:1932-7447
1932-7455
DOI:10.1021/jp304757f