Atomic observation of catalysis-induced nanopore coarsening of nanoporous gold

Takeshi Fujita; Tomoharu Tokunaga; Ling Zhang; Dongwei Li; Luyang Chen; Shigeo Arai; Yuta Yamamoto; Akihiko Hirata; Nobuo Tanaka; Yi Ding; Mingwei Chen

doi:10.1021/nl403895s

Atomic observation of catalysis-induced nanopore coarsening of nanoporous gold

Takeshi Fujita, Tomoharu Tokunaga, Ling Zhang, Dongwei Li, Luyang Chen, Shigeo Arai, Yuta Yamamoto, Akihiko Hirata, Nobuo Tanaka, Yi Ding, Mingwei Chen

Advanced Institute for Materials Research (AIMR)

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

102 Citations (Scopus)

Abstract

Dealloyed nanoporous metals have attracted much attention because of their excellent catalytic activities toward various chemical reactions. Nevertheless, coarsening mechanisms in these catalysts have not been experimentally studied. Here, we report in situ atomic-scale observations of the structural evolution of nanoporous gold during catalytic CO oxidation. The catalysis-induced nanopore coarsening is associated with the rapid diffusion of gold atoms at chemically active surface steps and the surface segregation of residual Ag atoms, both of which are stimulated by the chemical reaction. Our observations provide the first direct evidence that planar defects hinder nanopore coarsening, suggesting a new strategy for developing structurally stable and highly active heterogeneous catalysts.

Original language	English
Pages (from-to)	1172-1177
Number of pages	6
Journal	Nano Letters
Volume	14
Issue number	3
DOIs	https://doi.org/10.1021/nl403895s
Publication status	Published - 2014 Mar 12

Keywords

CO oxidation
In situ TEM
environmental transmission electron microscopy
heterogeneous catalyst
nanoporous metal

ASJC Scopus subject areas

Bioengineering
Chemistry(all)
Materials Science(all)
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl403895s

Cite this

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abstract = "Dealloyed nanoporous metals have attracted much attention because of their excellent catalytic activities toward various chemical reactions. Nevertheless, coarsening mechanisms in these catalysts have not been experimentally studied. Here, we report in situ atomic-scale observations of the structural evolution of nanoporous gold during catalytic CO oxidation. The catalysis-induced nanopore coarsening is associated with the rapid diffusion of gold atoms at chemically active surface steps and the surface segregation of residual Ag atoms, both of which are stimulated by the chemical reaction. Our observations provide the first direct evidence that planar defects hinder nanopore coarsening, suggesting a new strategy for developing structurally stable and highly active heterogeneous catalysts.",

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author = "Takeshi Fujita and Tomoharu Tokunaga and Ling Zhang and Dongwei Li and Luyang Chen and Shigeo Arai and Yuta Yamamoto and Akihiko Hirata and Nobuo Tanaka and Yi Ding and Mingwei Chen",

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doi = "10.1021/nl403895s",

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TY - JOUR

T1 - Atomic observation of catalysis-induced nanopore coarsening of nanoporous gold

AU - Fujita, Takeshi

AU - Tokunaga, Tomoharu

AU - Zhang, Ling

AU - Li, Dongwei

AU - Chen, Luyang

AU - Arai, Shigeo

AU - Yamamoto, Yuta

AU - Hirata, Akihiko

AU - Tanaka, Nobuo

AU - Ding, Yi

AU - Chen, Mingwei

PY - 2014/3/12

Y1 - 2014/3/12

N2 - Dealloyed nanoporous metals have attracted much attention because of their excellent catalytic activities toward various chemical reactions. Nevertheless, coarsening mechanisms in these catalysts have not been experimentally studied. Here, we report in situ atomic-scale observations of the structural evolution of nanoporous gold during catalytic CO oxidation. The catalysis-induced nanopore coarsening is associated with the rapid diffusion of gold atoms at chemically active surface steps and the surface segregation of residual Ag atoms, both of which are stimulated by the chemical reaction. Our observations provide the first direct evidence that planar defects hinder nanopore coarsening, suggesting a new strategy for developing structurally stable and highly active heterogeneous catalysts.

AB - Dealloyed nanoporous metals have attracted much attention because of their excellent catalytic activities toward various chemical reactions. Nevertheless, coarsening mechanisms in these catalysts have not been experimentally studied. Here, we report in situ atomic-scale observations of the structural evolution of nanoporous gold during catalytic CO oxidation. The catalysis-induced nanopore coarsening is associated with the rapid diffusion of gold atoms at chemically active surface steps and the surface segregation of residual Ag atoms, both of which are stimulated by the chemical reaction. Our observations provide the first direct evidence that planar defects hinder nanopore coarsening, suggesting a new strategy for developing structurally stable and highly active heterogeneous catalysts.

KW - CO oxidation

KW - In situ TEM

KW - environmental transmission electron microscopy

KW - heterogeneous catalyst

KW - nanoporous metal

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Atomic observation of catalysis-induced nanopore coarsening of nanoporous gold

Abstract

Keywords

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