Role of small Pd ensembles in boosting CO oxidation in AuPd alloys

Hyung Chul Ham; J. Adam Stephens; Gyeong S. Hwang; Jonghee Han; Suk Woo Nam; Tae Hoon Lim

doi:10.1021/jz201585q

Role of small Pd ensembles in boosting CO oxidation in AuPd alloys

Hyung Chul Ham, J. Adam Stephens, Gyeong S. Hwang^*, Jonghee Han, Suk Woo Nam, Tae Hoon Lim

^*Corresponding author for this work

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

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Abstract

We present a theoretical explanation on how PdAu alloy catalysts can enhance the oxidation of CO molecules based on density functional theory calculations of CO adsorption and oxidation on AuPd/Pd(111) surfaces. Our study suggests that the enhanced activity is largely attributed to the possible existence of "partially-poisoned" Pd ensembles that accommodate fewer CO molecules than Pd atoms. Whereas the oxidation of preadsorbed CO is likely governed by O ₂ trapping, our study shows that small Pd ensembles such as dimers and compact trimers tend to provide more active sites than larger ensembles; CO adsorbed on a Pd monomer is found to react hardly with O ₂ to form CO ₂. In addition, we find the tendency of CO-induced Pd agglomeration, which may in turn facilitate CO oxidation by creating more dimers and compact trimers as compared with the adsorbate-free surface where monomers are likely prevailing.

Original language	English
Pages (from-to)	566-570
Number of pages	5
Journal	Journal of Physical Chemistry Letters
Volume	3
Issue number	5
DOIs	https://doi.org/10.1021/jz201585q
Publication status	Published - 2012 Mar 1

ASJC Scopus subject areas

General Materials Science
Physical and Theoretical Chemistry

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title = "Role of small Pd ensembles in boosting CO oxidation in AuPd alloys",

abstract = "We present a theoretical explanation on how PdAu alloy catalysts can enhance the oxidation of CO molecules based on density functional theory calculations of CO adsorption and oxidation on AuPd/Pd(111) surfaces. Our study suggests that the enhanced activity is largely attributed to the possible existence of {"}partially-poisoned{"} Pd ensembles that accommodate fewer CO molecules than Pd atoms. Whereas the oxidation of preadsorbed CO is likely governed by O 2 trapping, our study shows that small Pd ensembles such as dimers and compact trimers tend to provide more active sites than larger ensembles; CO adsorbed on a Pd monomer is found to react hardly with O 2 to form CO 2. In addition, we find the tendency of CO-induced Pd agglomeration, which may in turn facilitate CO oxidation by creating more dimers and compact trimers as compared with the adsorbate-free surface where monomers are likely prevailing.",

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AU - Ham, Hyung Chul

AU - Stephens, J. Adam

AU - Hwang, Gyeong S.

AU - Han, Jonghee

AU - Nam, Suk Woo

AU - Lim, Tae Hoon

PY - 2012/3/1

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N2 - We present a theoretical explanation on how PdAu alloy catalysts can enhance the oxidation of CO molecules based on density functional theory calculations of CO adsorption and oxidation on AuPd/Pd(111) surfaces. Our study suggests that the enhanced activity is largely attributed to the possible existence of "partially-poisoned" Pd ensembles that accommodate fewer CO molecules than Pd atoms. Whereas the oxidation of preadsorbed CO is likely governed by O 2 trapping, our study shows that small Pd ensembles such as dimers and compact trimers tend to provide more active sites than larger ensembles; CO adsorbed on a Pd monomer is found to react hardly with O 2 to form CO 2. In addition, we find the tendency of CO-induced Pd agglomeration, which may in turn facilitate CO oxidation by creating more dimers and compact trimers as compared with the adsorbate-free surface where monomers are likely prevailing.

AB - We present a theoretical explanation on how PdAu alloy catalysts can enhance the oxidation of CO molecules based on density functional theory calculations of CO adsorption and oxidation on AuPd/Pd(111) surfaces. Our study suggests that the enhanced activity is largely attributed to the possible existence of "partially-poisoned" Pd ensembles that accommodate fewer CO molecules than Pd atoms. Whereas the oxidation of preadsorbed CO is likely governed by O 2 trapping, our study shows that small Pd ensembles such as dimers and compact trimers tend to provide more active sites than larger ensembles; CO adsorbed on a Pd monomer is found to react hardly with O 2 to form CO 2. In addition, we find the tendency of CO-induced Pd agglomeration, which may in turn facilitate CO oxidation by creating more dimers and compact trimers as compared with the adsorbate-free surface where monomers are likely prevailing.

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Role of small Pd ensembles in boosting CO oxidation in AuPd alloys

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