Abstract
Further advances in fuel cell technologies are hampered by kinetic limitations associated with the sluggish cathodic oxygen reduction reaction. We have investigated a range of different formulations of binary and ternary Pt, Pd and Au thin films as electrocatalysts for oxygen reduction. The most active binary thin films are near-surface alloys of Pt with subsurface Pd and certain PdAu and PtAu thin films with surface and/or subsurface Au. The most active ternary thin films are with pure metal Pt or Pd skins with some degree of Au in the surface and/or subsurface layer and the near-surface alloys of Au with mixed Pt-Pd skins. The activity of the binary and ternary catalysts is explained through weakening of the OH binding energy caused by solute elements. However, given the low alloy formation energies it may be difficult to tune and retain the composition under operating conditions. This is particularly challenging for alloys containing Au due to a high propensity of Au to segregate to the surface. We also show that once Au is on the surface it will diffuse to defect sites, explaining why small amounts of Au retard dissolution of Pt nanoparticles. For the PtPd thin films there is no pronounced driving force for surface segregation, diffusion to defects or surface self-assembling. On the basis of stability and activity analysis we conclude that the near surface alloy of Pd in Pt and some PdAu binary and PtPdAu ternary thin films with a controlled amount of Au are the best catalysts for oxygen reduction.
Highlights
Different alloys of Pt, Pd and Au have previously been investigated as potential catalysts for oxygen reduction
Six binary combinations of Pt, Pd and Au elements are initially investigated, i.e. Pt@PtPd, Pt@PtAu, Pd@PtPd, Pd@PdAu, Au@PtAu and Au@PdAu, where composition before the @ sign is for the core element and after for the thin films
Two out of six thin films, Au@PtAu and Au@PdAu are discarded a priori. These thin films will not be active for the oxygen reduction reaction (ORR) due to the large Au lattice constant
Summary
Different alloys of Pt, Pd and Au have previously been investigated as potential catalysts for oxygen reduction. Almost all thin films with the activities greater than that of Pt have at least 1/3 ML solute element content in the subsurface layer. For thin films that have a high Au concentration on the surface, and are predicted to be very active for the ORR (e.g. PtAu2/Au3/Pt), the 4-electron reduction to water will take place through a non-surface mediated splitting of the OOH bond.[46,47] The strain effect is fixed and given by the metal host.
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