Exploring the first steps in core–shell electrocatalyst preparation: in situ characterization of the underpotential deposition of Cu on supported Au nanoparticles
Exploring the first steps in core–shell electrocatalyst preparation: in situ characterization of the underpotential deposition of Cu on supported Au nanoparticles
The underpotential deposition (upd) of a Cu shell on a non-Pt nanoparticle core followed by galvanic displacement of the Cu template shell to form core-shell electrocatalyst materials is one means by which the Pt-based mass activity targets required for commercialization of PEM fuel cells may be reached. In situ EXAFS measurements were conducted at both the Au L(3) and the Cu K absorption edges during deposition of Cu onto a carbon-supported Au electrocatalyst to study the initial stages of formation of such a core shell electrocatalyst. The Au L(3) EXAFS data obtained in 0.5 mol dm(-3) H(2)SO(4) show that the shape of the Au core is potential dependent, from a flattened to a round spherical shape as the Cu upd potential is approached. Following the addition of 2 mmol dm(-3) Cu, the structure was also measured as a function of the applied potential. At +0.2 V vs Hg/Hg(2)SO(4), the Cu(2+) species was found to be a hydrated octahedron. As the potential was made more negative, single-crystal studies predict an ordered bilayer of sulfate anions and partially discharged Cu ions, followed by a complete/uniform layer of Cu atoms. In contrast, the model obtained by fitting the Au L(3) and Cu K EXAFS data corresponds first to partially discharged Cu ions deposited at the defect sites in the outer shell of the Au nanoparticles at -0.42 V, followed by the growth of dusters of Cu atoms at -0.51 V. The absence of a uniform/complete Cu shell, even at the most negative potentials investigated, has implications for the structure, and the activity and/or stability, of the core-shell catalyst that would be subsequently formed following galvanic displacement of the Cu shell.
19448-19458
Price, Stephen W.T.
5d3310d0-cf30-45e6-ba44-4bf87ade3b8d
Speed, Jonathon D.
2855464c-be33-49cb-bbb3-b3996f97ad1e
Kannan, Prabalini
70e2e8f9-c3e0-4dc7-9629-81f9c21825a8
Russell, Andrea E.
b6b7c748-efc1-4d5d-8a7a-8e4b69396169
27 October 2011
Price, Stephen W.T.
5d3310d0-cf30-45e6-ba44-4bf87ade3b8d
Speed, Jonathon D.
2855464c-be33-49cb-bbb3-b3996f97ad1e
Kannan, Prabalini
70e2e8f9-c3e0-4dc7-9629-81f9c21825a8
Russell, Andrea E.
b6b7c748-efc1-4d5d-8a7a-8e4b69396169
Price, Stephen W.T., Speed, Jonathon D., Kannan, Prabalini and Russell, Andrea E.
(2011)
Exploring the first steps in core–shell electrocatalyst preparation: in situ characterization of the underpotential deposition of Cu on supported Au nanoparticles.
Journal of the American Chemical Society, 133 (48), .
(doi:10.1021/ja206763e).
(PMID:22032178)
Abstract
The underpotential deposition (upd) of a Cu shell on a non-Pt nanoparticle core followed by galvanic displacement of the Cu template shell to form core-shell electrocatalyst materials is one means by which the Pt-based mass activity targets required for commercialization of PEM fuel cells may be reached. In situ EXAFS measurements were conducted at both the Au L(3) and the Cu K absorption edges during deposition of Cu onto a carbon-supported Au electrocatalyst to study the initial stages of formation of such a core shell electrocatalyst. The Au L(3) EXAFS data obtained in 0.5 mol dm(-3) H(2)SO(4) show that the shape of the Au core is potential dependent, from a flattened to a round spherical shape as the Cu upd potential is approached. Following the addition of 2 mmol dm(-3) Cu, the structure was also measured as a function of the applied potential. At +0.2 V vs Hg/Hg(2)SO(4), the Cu(2+) species was found to be a hydrated octahedron. As the potential was made more negative, single-crystal studies predict an ordered bilayer of sulfate anions and partially discharged Cu ions, followed by a complete/uniform layer of Cu atoms. In contrast, the model obtained by fitting the Au L(3) and Cu K EXAFS data corresponds first to partially discharged Cu ions deposited at the defect sites in the outer shell of the Au nanoparticles at -0.42 V, followed by the growth of dusters of Cu atoms at -0.51 V. The absence of a uniform/complete Cu shell, even at the most negative potentials investigated, has implications for the structure, and the activity and/or stability, of the core-shell catalyst that would be subsequently formed following galvanic displacement of the Cu shell.
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ja206763e
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Published date: 27 October 2011
Organisations:
Electrochemistry
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Local EPrints ID: 337117
URI: http://eprints.soton.ac.uk/id/eprint/337117
ISSN: 0002-7863
PURE UUID: 62ae94de-d879-4cd6-8771-5834f5b4e7d3
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Date deposited: 18 Apr 2012 13:10
Last modified: 15 Mar 2024 02:58
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Author:
Stephen W.T. Price
Author:
Jonathon D. Speed
Author:
Prabalini Kannan
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