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Paper detail

Pt-based nanowire networks with enhanced oxygen-reduction activity

Pt-Al and Pt-Y-Al thin film electrodes on yttria-stabilised zirconia electrolytes were prepared by dealloying of co-sputtered Pt-Al or Pt-Y-Al films. The selective dissolution of Al from the Pt-alloy compound causes the formation of a highly porous nanowire network with a mean branch thickness below 25 nm and a pore intercept length below 35 nm. The oxygen reduction capability of the resulting electrodes was analysed in a micro-solid oxide fuel cell setup at elevated temperatures (598-873 K). Here, we demonstrate that these nanoporous thin films excel "state-of-the-art" fuel cell electrodes in terms of catalytic activity and thermal stability. The nanoporous Pt electrodes exhibit exchange current densities that are up to 13 times higher than conventional Pt electrodes, measured at 648 K. It is shown that the enhanced catalytic activity of these Pt electrodes is achieved through the engineering of the materials d-bands due to the addition of yttrium as ternary constituent.

preprint2014arXivOpen access
Henning GalinskiThomas RyllYang LinBarbara ScherrerAnna EvansMax DöbeliLudwig J. Gauckler
cond-mat.mes-hallcond-mat.mtrl-sciphysics.chem-ph
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Henning GalinskiThomas RyllYang LinBarbara ScherrerAnna EvansMax DöbeliLudwig J. Gauckler

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