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Electronic metal-support interaction enhanced oxygen reduction activity and stability of boron carbide supported platinum.


ABSTRACT: Catalysing the reduction of oxygen in acidic media is a standing challenge. Although activity of platinum, the most active metal, can be substantially improved by alloying, alloy stability remains a concern. Here we report that platinum nanoparticles supported on graphite-rich boron carbide show a 50-100% increase in activity in acidic media and improved cycle stability compared to commercial carbon supported platinum nanoparticles. Transmission electron microscopy and x-ray absorption fine structure analysis confirm similar platinum nanoparticle shapes, sizes, lattice parameters, and cluster packing on both supports, while x-ray photoelectron and absorption spectroscopy demonstrate a change in electronic structure. This shows that purely electronic metal-support interactions can significantly improve oxygen reduction activity without inducing shape, alloying or strain effects and without compromising stability. Optimizing the electronic interaction between the catalyst and support is, therefore, a promising approach for advanced electrocatalysts where optimizing the catalytic nanoparticles themselves is constrained by other concerns.

SUBMITTER: Jackson C 

PROVIDER: S-EPMC5489685 | biostudies-literature | 2017 Jun

REPOSITORIES: biostudies-literature

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Electronic metal-support interaction enhanced oxygen reduction activity and stability of boron carbide supported platinum.

Jackson Colleen C   Smith Graham T GT   Inwood David W DW   Leach Andrew S AS   Whalley Penny S PS   Callisti Mauro M   Polcar Tomas T   Russell Andrea E AE   Levecque Pieter P   Kramer Denis D  

Nature communications 20170622


Catalysing the reduction of oxygen in acidic media is a standing challenge. Although activity of platinum, the most active metal, can be substantially improved by alloying, alloy stability remains a concern. Here we report that platinum nanoparticles supported on graphite-rich boron carbide show a 50-100% increase in activity in acidic media and improved cycle stability compared to commercial carbon supported platinum nanoparticles. Transmission electron microscopy and x-ray absorption fine stru  ...[more]

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