Rhodium-Tin Binary Nanoparticle - A Strategy to Develop an Alternative Electrocatalyst for Oxygen Reduction

Minjeh Ahn; In Young Cha; Jinwon Cho; Hyung Chul Ham; Yung Eun Sung; Sung Jong Yoo

doi:10.1021/acscatal.7b02402

Rhodium-Tin Binary Nanoparticle - A Strategy to Develop an Alternative Electrocatalyst for Oxygen Reduction

Minjeh Ahn, In Young Cha, Jinwon Cho, Hyung Chul Ham, Yung Eun Sung, Sung Jong Yoo

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

30 Scopus citations

Abstract

A Rh-Sn nanoparticle is achieved by combinatorial approaches for application as an active and stable electrocatalyst in the oxygen reduction reaction. Both metallic Rh and metallic Sn exhibit activities too low to be utilized for electrocatalytic reduction of oxygen. However, a clean and active Rh surface can be activated by incorporation of Sn into a Rh nanoparticle through the combined effects of lateral repulsion, bifunctional mechanism, and electronic modification. The corrosion-resistant property of Rh contributes to the construction of a stable catalyst that can be used under harsh fuel cell conditions. Based on both theoretical and experimental research, Rh-Sn nanoparticle designs with inexpensive materials can be a potential alternative catalyst in terms of the economic feasibility of commercialization and its facile and simple surfactant-free microwave-assisted synthesis.

Original language	English
Pages (from-to)	5796-5801
Number of pages	6
Journal	ACS Catalysis
Volume	7
Issue number	9
DOIs	https://doi.org/10.1021/acscatal.7b02402
State	Published - 1 Sep 2017
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2017 American Chemical Society.

Keywords

electrocatalyst
fuel cells
nanomaterial
oxygen reduction
rhodium-tin

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10.1021/acscatal.7b02402

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abstract = "A Rh-Sn nanoparticle is achieved by combinatorial approaches for application as an active and stable electrocatalyst in the oxygen reduction reaction. Both metallic Rh and metallic Sn exhibit activities too low to be utilized for electrocatalytic reduction of oxygen. However, a clean and active Rh surface can be activated by incorporation of Sn into a Rh nanoparticle through the combined effects of lateral repulsion, bifunctional mechanism, and electronic modification. The corrosion-resistant property of Rh contributes to the construction of a stable catalyst that can be used under harsh fuel cell conditions. Based on both theoretical and experimental research, Rh-Sn nanoparticle designs with inexpensive materials can be a potential alternative catalyst in terms of the economic feasibility of commercialization and its facile and simple surfactant-free microwave-assisted synthesis.",

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AU - Ahn, Minjeh

AU - Cha, In Young

AU - Cho, Jinwon

AU - Ham, Hyung Chul

AU - Sung, Yung Eun

AU - Yoo, Sung Jong

PY - 2017/9/1

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N2 - A Rh-Sn nanoparticle is achieved by combinatorial approaches for application as an active and stable electrocatalyst in the oxygen reduction reaction. Both metallic Rh and metallic Sn exhibit activities too low to be utilized for electrocatalytic reduction of oxygen. However, a clean and active Rh surface can be activated by incorporation of Sn into a Rh nanoparticle through the combined effects of lateral repulsion, bifunctional mechanism, and electronic modification. The corrosion-resistant property of Rh contributes to the construction of a stable catalyst that can be used under harsh fuel cell conditions. Based on both theoretical and experimental research, Rh-Sn nanoparticle designs with inexpensive materials can be a potential alternative catalyst in terms of the economic feasibility of commercialization and its facile and simple surfactant-free microwave-assisted synthesis.

AB - A Rh-Sn nanoparticle is achieved by combinatorial approaches for application as an active and stable electrocatalyst in the oxygen reduction reaction. Both metallic Rh and metallic Sn exhibit activities too low to be utilized for electrocatalytic reduction of oxygen. However, a clean and active Rh surface can be activated by incorporation of Sn into a Rh nanoparticle through the combined effects of lateral repulsion, bifunctional mechanism, and electronic modification. The corrosion-resistant property of Rh contributes to the construction of a stable catalyst that can be used under harsh fuel cell conditions. Based on both theoretical and experimental research, Rh-Sn nanoparticle designs with inexpensive materials can be a potential alternative catalyst in terms of the economic feasibility of commercialization and its facile and simple surfactant-free microwave-assisted synthesis.

KW - electrocatalyst

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KW - nanomaterial

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KW - rhodium-tin

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Rhodium-Tin Binary Nanoparticle - A Strategy to Develop an Alternative Electrocatalyst for Oxygen Reduction

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