Abstract

Using tin oxide (SnO 2 ) and niobium-doped tin oxide (Nb-SnO 2 ) as alternative electrocatalyst support materials can effectively solve the issue of carbon corrosion in polymer electrolyte fuel cell (PEFC) cathodes. Here, we systematically explore the effect of support surface area, Pt loading, and Pt nanoparticle size on the electrochemistry of these carbon-free electrocatalysts. Reducing the Pt loading leads to an increase in electrochemical surface area, but the specific activity decreases as previously observed in conventional carbon based electrocatalysts. Removing residual chlorine impurities by replacing the H 2 PtCl 6 nanoparticle precursor with Pt(acac) 2 increases the specific activity. Niobium-doping of the SnO 2 support also results in an increase in specific activity, due to the increased electronic conductivity. Consequently, the oxygen reduction reaction activity of optimized Pt-decorated Nb-SnO 2 is approaching to that of Pt-decorated carbon black, the current state-of-the-art PEFC electrocatalyst.