A solvent-switched in situ confinement approach for immobilizing highly-active ultrafine palladium nanoparticles: boosting catalytic hydrogen evolution

Zhu, Qi-Long; Song, Fu-Zhan; Wang, Qiu-Ju; Tsumori, Nobuko; Himeda, Yuichiro; Autrey, Tom; Xu, Qiang

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Royal Society of Chemistry, Journal of Materials Chemistry A: materials for energy and sustainability, 14(6), p. 5544-5549

DOI: 10.1039/c8ta01093e

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A solvent-switched in situ confinement approach for immobilizing highly-active ultrafine palladium nanoparticles: boosting catalytic hydrogen evolution

Journal article published in 2018 by Qi-Long Zhu

, Fu-Zhan Song, Qiu-Ju Wang, Nobuko Tsumori, Yuichiro Himeda, Tom Autrey, Qiang Xu

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Abstract

A solvent-switched in situ confinement approach has been developed to synthesize highly active nanocatalysts with ultrafine and clean metal nanoparticles encapsulated within carbon nanopores, over which record-high hydrogen evolution has been achieved under heterogeneous conditions.

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A solvent-switched in situ confinement approach for immobilizing highly-active ultrafine palladium nanoparticles: boosting catalytic hydrogen evolution

Abstract