Abstract
It is no secret alkaline fuel cells (AFC) using a liquid electrolyte (usually concentrated KOH) have assets over their proton-exchange membrane counterparts, in particular in niche applications where the latter are challenged by too harsh operating/environmental conditions [1]. AFC can also, in theory, use non-Pt catalysts at their electrodes without detrimental durability issues. However, recent studies from our group showed that Pt/C and Pd/C were very sensitive to the metal nanoparticles detachment from the carbon owing to their propensity to catalyze the carbon-support corrosion upon repeated alternation of the potential below/above their metal oxide potential (which is unavoidable at the anode upon start/stop of the fuel cell) [2-5].In this presentation, it is highlighted that more robust hydrogen oxidation catalysts can be prepared by tailoring a carbon cap around the metal nanoparticles, in particular for palladium as the catalyst metal. Such “carbon-capped” Pd/C nanoparticles (ex. PdG2/C) exhibit a good compromise between their HOR activity and long-term stability (Figure 1), evaluated by identical location transmission electron microscopy upon accelerated stress tests (0.1 - 1.23 V vs. RHE stepped by 3 s – 3 s, 1000 times) (Figure 2). Their properties are very advantageous over non-capped (classical) Pd/C nanoparticles, demonstrating the interest of this strategy for the development of active and durable HOR catalysts for AFC anodes.
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