Rational design and controllable synthesis of catalysts with unique structure and composition are effective ways to promote electrocatalytic ethanol oxidation, thus contributing the direct ethanol fuel cells to gain ground. Herein, 2.5 nm-thin PtIrCu ternary alloy ultrathin nanowires (UNWs) with high-density planar defects are synthesized via oriented attachment with the assistance of H 2 . By adjusting the contents of Ir and Cu atoms, we find that the structure of the products changed from nanowires (NWs) to nanoparticles with the increase of Ir content. Density functional theory calculations show that when Cu atoms are replaced by Ir atoms, the vacancy formation energy of Pt atoms is increased, making the Pt atoms difficult to be activated by H 2 , which is not conducive to the formation of a one-dimensional structure. The optimal Pt 43 Ir 32 Cu 25 UNWs achieve excellent ethanol electrooxidation reaction activity (1.05 A•mg −1 Pt and 1.67 mA•cm −2 ), for it can significantly reduce the onset potential and improve the ability of CO anti-poisoning. The significant improvement in catalytic performance is attributed to the synergistic effect of the alloy and the NW structure with high-density planar defects.
Pt-based alloy nanowires become an ideal platform for commercial application of direct methanol fuel cells (DMFCs). Regrettably, most of the nanowires are prepared in oil phase system. These plentiful hydrophobic...
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