Abstract
Proton exchange membrane (PEM) water electrolysis is a promising and sustainable technology for hydrogen production. Currently, the anode catalysts used in PEM water electrolysis are predominantly iridium-based electrocatalysts, which are extremely precious and scarce. In this study, we report a mixed (Ru-W)O (x) catalyst as a promising alternative to iridium-based catalysts. The (Ru-W)O (x) catalyst was synthesized using a simple Pechini-Adams method, and its microstructure and electrochemical performance were optimized by controlling the Ru/W doping ratio and the synthesis temperature. Among the synthesized catalysts, the Ru(6)W(4)O (x) catalyst prepared at 400 °C demonstrated the best oxygen evolution reaction (OER) activity and stability, achieving an overpotential of only 140.32 mV at 10 mA cm(-2). Furthermore, after a 150 hours stability test, no significant loss in catalytic activity was observed. When applied to the anode of a PEM water electrolyzer, the Ru(6)W(4)O (x) -400 °C catalyst exhibited an impressively low cell voltage of 1.784 V at 2 A cm(-2). The energy consumption is as low as 4.34 kWh m(-3) H(2). These results provide new insights for developing efficient and stable non-iridium-based OER catalysts for PEM water electrolysis.