Acetaldehyde production in the direct ethanol fuel cell: Mechanistic elucidation by density functional theory

Richard Kavanagh; Xiao Ming Cao; Wenfeng Lin; Christopher Hardacre; P. Hu

doi:10.1021/jp210789s

Acetaldehyde production in the direct ethanol fuel cell: Mechanistic elucidation by density functional theory

Richard Kavanagh, Xiao Ming Cao, Wenfeng Lin^*, Christopher Hardacre, P. Hu

^*Corresponding author for this work

Queen's University Belfast

Research output: Contribution to journal › Article › peer-review

Abstract

This study employs density functional theory (DFT) calculations to examine the mechanism by which acetaldehyde is formed on platinum in a typical direct ethanol fuel cell (DEFC). A pathway is found involving the formation of a strongly hydrogen-bonded complex between adsorbed ethanol and the surface hydroxyl (OH) species, followed by the facile Î±-dehydrogenation of ethanol, with spontaneous weakening of the hydrogen bond in favor of adsorbed acetaldehyde and water. This mechanism is found to be comparably viable on both the close-packed surface and the monatomic steps. Comparison of further reactions on these two sites strongly indicates that the steps act as net removers of acetaldehyde from the product stream, while the flat surface acts as a net producer.

Original language	English
Pages (from-to)	7185-7188
Number of pages	4
Journal	Journal of Physical Chemistry C
Volume	116
Issue number	12
DOIs	https://doi.org/10.1021/jp210789s
Publication status	Published - 29 Mar 2012

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abstract = "This study employs density functional theory (DFT) calculations to examine the mechanism by which acetaldehyde is formed on platinum in a typical direct ethanol fuel cell (DEFC). A pathway is found involving the formation of a strongly hydrogen-bonded complex between adsorbed ethanol and the surface hydroxyl (OH) species, followed by the facile {\^I}±-dehydrogenation of ethanol, with spontaneous weakening of the hydrogen bond in favor of adsorbed acetaldehyde and water. This mechanism is found to be comparably viable on both the close-packed surface and the monatomic steps. Comparison of further reactions on these two sites strongly indicates that the steps act as net removers of acetaldehyde from the product stream, while the flat surface acts as a net producer.",

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AU - Kavanagh, Richard

AU - Cao, Xiao Ming

AU - Lin, Wenfeng

AU - Hardacre, Christopher

AU - Hu, P.

PY - 2012/3/29

Y1 - 2012/3/29

N2 - This study employs density functional theory (DFT) calculations to examine the mechanism by which acetaldehyde is formed on platinum in a typical direct ethanol fuel cell (DEFC). A pathway is found involving the formation of a strongly hydrogen-bonded complex between adsorbed ethanol and the surface hydroxyl (OH) species, followed by the facile Î±-dehydrogenation of ethanol, with spontaneous weakening of the hydrogen bond in favor of adsorbed acetaldehyde and water. This mechanism is found to be comparably viable on both the close-packed surface and the monatomic steps. Comparison of further reactions on these two sites strongly indicates that the steps act as net removers of acetaldehyde from the product stream, while the flat surface acts as a net producer.

AB - This study employs density functional theory (DFT) calculations to examine the mechanism by which acetaldehyde is formed on platinum in a typical direct ethanol fuel cell (DEFC). A pathway is found involving the formation of a strongly hydrogen-bonded complex between adsorbed ethanol and the surface hydroxyl (OH) species, followed by the facile Î±-dehydrogenation of ethanol, with spontaneous weakening of the hydrogen bond in favor of adsorbed acetaldehyde and water. This mechanism is found to be comparably viable on both the close-packed surface and the monatomic steps. Comparison of further reactions on these two sites strongly indicates that the steps act as net removers of acetaldehyde from the product stream, while the flat surface acts as a net producer.

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DO - 10.1021/jp210789s

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SP - 7185

EP - 7188

JO - Journal of Physical Chemistry C

JF - Journal of Physical Chemistry C

IS - 12

ER -

Acetaldehyde production in the direct ethanol fuel cell: Mechanistic elucidation by density functional theory

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