Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation

Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation

Although platinum nanocrystals have been considered as potential electrocatalysts for methanol oxidation reaction (MOR) in fuel cells, the large-scale practical implementation has been stagnated by their limited abundance, easy poisoning, and low durability. Here, grain boundary-enriched platinum (G...

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Main Authors: Chao Zhang, Huajie Huang, Jianan Gu, Zhiguo Du, Bin Li, Songmei Li, Shubin Yang
Format: Article
Language:English
Published: American Association for the Advancement of Science 2019-01-01
Series:Research
Online Access:http://dx.doi.org/10.34133/2019/8174314
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spelling doaj-3c654c46e97d44e6a49d22097545e5292020-11-25T02:48:25ZengAmerican Association for the Advancement of ScienceResearch2639-52742019-01-01201910.34133/2019/8174314Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol OxidationChao Zhang0Huajie Huang1Jianan Gu2Zhiguo Du3Bin Li4Songmei Li5Shubin Yang6Key Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaCollege of Mechanics and Materials,Hohai University,Nanjing 210098,ChinaKey Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaKey Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaKey Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaKey Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaKey Laboratory of Aerospace Advanced Materials and Performance of Ministry of Education,School of Materials Science and Engineering,Beihang University,100191 Beijing,ChinaAlthough platinum nanocrystals have been considered as potential electrocatalysts for methanol oxidation reaction (MOR) in fuel cells, the large-scale practical implementation has been stagnated by their limited abundance, easy poisoning, and low durability. Here, grain boundary-enriched platinum (GB-Pt) scaffolds are produced in large scale via facilely reducing fast cryomediated dynamic equilibrium hydrolysates of platinum salts. Such plentiful platinum grain boundaries are originated from the fast fusion of short platinum nanowires during reduction of the individually and homogeneously dispersed platinum intermediates. These grain boundaries can provide abundant active sites to efficiently catalyze MOR and meanwhile enable to oxidize the adsorbed poisonous CO during the electrocatalytic process. As a consequence, the as-synthesized GB-Pt scaffolds exhibit an impressively high mass activity of 1027.1 mA mgPt−1 for MOR, much higher than that of commercial Pt/C (345.2 mA mgPt−1), as well as good stability up to 5000 cycles. We are confident that this synthetic protocol can be further extended to synthesize various grain boundary-enriched metal scaffolds with broad applications in catalysis.http://dx.doi.org/10.34133/2019/8174314
collection DOAJ
language English
format Article
sources DOAJ
author Chao Zhang
Huajie Huang
Jianan Gu
Zhiguo Du
Bin Li
Songmei Li
Shubin Yang
spellingShingle Chao Zhang
Huajie Huang
Jianan Gu
Zhiguo Du
Bin Li
Songmei Li
Shubin Yang
Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
Research
author_facet Chao Zhang
Huajie Huang
Jianan Gu
Zhiguo Du
Bin Li
Songmei Li
Shubin Yang
author_sort Chao Zhang
title Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
title_short Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
title_full Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
title_fullStr Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
title_full_unstemmed Fast Cryomediated Dynamic Equilibrium Hydrolysates towards Grain Boundary-Enriched Platinum Scaffolds for Efficient Methanol Oxidation
title_sort fast cryomediated dynamic equilibrium hydrolysates towards grain boundary-enriched platinum scaffolds for efficient methanol oxidation
publisher American Association for the Advancement of Science
series Research
issn 2639-5274
publishDate 2019-01-01
description Although platinum nanocrystals have been considered as potential electrocatalysts for methanol oxidation reaction (MOR) in fuel cells, the large-scale practical implementation has been stagnated by their limited abundance, easy poisoning, and low durability. Here, grain boundary-enriched platinum (GB-Pt) scaffolds are produced in large scale via facilely reducing fast cryomediated dynamic equilibrium hydrolysates of platinum salts. Such plentiful platinum grain boundaries are originated from the fast fusion of short platinum nanowires during reduction of the individually and homogeneously dispersed platinum intermediates. These grain boundaries can provide abundant active sites to efficiently catalyze MOR and meanwhile enable to oxidize the adsorbed poisonous CO during the electrocatalytic process. As a consequence, the as-synthesized GB-Pt scaffolds exhibit an impressively high mass activity of 1027.1 mA mgPt−1 for MOR, much higher than that of commercial Pt/C (345.2 mA mgPt−1), as well as good stability up to 5000 cycles. We are confident that this synthetic protocol can be further extended to synthesize various grain boundary-enriched metal scaffolds with broad applications in catalysis.
url http://dx.doi.org/10.34133/2019/8174314
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