Abstract
Proton-exchange-membrane water electrolyzers (PEMWEs) are of particular interest for green hydrogen production, where the oxygen evolution reaction (OER) at the anode largely determines the overall efficiency. Up to now, only ultrafine IrO(2) catalyst gives desirable performance, while its scarcity and high cost inhibit the widespread application. RuO(2) catalyst is the most promising alternative, while its practical application is greatly hindered by poor durability. Herein, the greatly boosted performance of conventional sub-micrometer RuO(2) by compositing with Ag is reported, and both the morphology of Ag and the compositing way significantly affect the electrolysis performance. The PEMWE fabricated with a two-layer RuO(2)/Ag nanowire (NWs) composite anode achieves 1.77 A cm(-2) at 2.00 V, due to a prominent 44.6 times increase of the electronic conductivity, which greatly improves the catalyst utilization. In addition, mass transportation at high-current-density region is enhanced due to the highly porous feature of Ag NW layer. Long-term stability under high current density of 1 A cm(-2) for 100 h is proved with the composite anode, due to the suppressed degradation of RuO(2) by silver compositing. This work may accelerate the widespread commercialization of PEMWEs by providing a new way for developing IrO(2)-free anode.