The growth and degradation of binary and ternary octahedral Pt–Ni-based fuel cell catalyst nanoparticles studied using advanced transmission electron microscopy

Heggen, Marc; Dunin-Borkowski, Rafal; Gocyla, Martin

doi:10.1080/23746149.2017.1282834

Journal Article

FZJ-2017-06688

The growth and degradation of binary and ternary octahedral Pt–Ni-based fuel cell catalyst nanoparticles studied using advanced transmission electron microscopy

Heggen, M. (Corresponding author)FZJ* ; Gocyla, M.FZJ* ; Dunin-Borkowski, R.FZJ*

2017
Taylor & Francis Group Abingdon

Advances in Physics: X 2(2), 281 - 301 (2017) [10.1080/23746149.2017.1282834]

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Please use a persistent id in citations: http://hdl.handle.net/2128/15329 doi:10.1080/23746149.2017.1282834

Abstract: Advances in fuel cell technology depend strongly on the development of affordable, active, and stable catalysts. For example, octahedral Pt–Ni alloy nanoparticles show exceptional activity for the oxygen reduction reaction in fuel cell cathodes as a result of the presence of highly active {1 1 1} facets. Here, we review a selection of recent transmission electron microscopy studies that address the correlation between the catalytic performance of octahedral Pt–Ni-based nanoparticles and their atomic-scale structure and composition. We begin by describing strategies for the growth of binary Pt–Ni and ternary Pt–Ni–TM (TM = transition metal) nanoparticles, with a focus on understanding how their structure and compositional anisotropy is related to their catalytic activity and stability. We then describe the morphological changes and compositional degradation effects that can occur in electrochemical environments. Changes in nanoparticle shape, including the loss of highly active {1 1 1} facets due to dealloying from Ni-rich facets and Pt surface diffusion, are discussed as important reasons for catalyst degradation. Finally, strategies to prevent degradation, e.g. by surface doping, are addressed. The growth, segregation, and degradation mechanisms that we describe highlight the complexity with which octahedral alloy nanoparticles form and evolve under reaction conditions.

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