Controlled doping of electrocatalysts through engineering impurities

Abstract: Fuel cells recombine water from H2 and O2 thereby powering e.g. cars or houses with no direct carbon emission. In anion-exchange membrane fuel cells (AEMFCs), to reach high power densities, operating at high pH is an alternative to using large volumes of noble metals catalysts at the cathode, where the oxygen-reduction reaction occurs. However, the sluggish kinetics of the hydrogen-oxidation reaction (HOR) hinders upscaling despite promising catalysts. Here, we observe an unexpected ingress of B into Pd nano-catalysts synthesised by wet-chemistry, gain control over this B-doping, and report on its influence on the HOR activity in alkaline conditions. We rationalize our findings using ab-initio calculations of both H- and OH-adsorption on B-doped Pd. Using this "impurity engineering" approach, we thus design Pt-free catalysts as required in electrochemical energy conversion devices, e.g. next generations of AEMFCs, that satisfy the economic and environmental constraints, i.e. reasonable operating costs and long-term stability, to enable the hydrogen economy.