Abstract
Constructing active metal-support interfacial structures is crucial for enhancing the activity and stability of electrocatalysts during the hydrogen evolution reaction (HER) across a wide pH range. Herein, ultrasmall mixed Ir species anchored on MoO(2)-Mo(2)C hollow nanoflowers assembled from nanosheets were synthesized via high-temperature sintering (600-800 °C). The X-ray absorption fine structure and X-ray photoelectron spectroscopy revealed the metal-support interaction (MSI) in Ir/MoO(2)-Mo(2)C-800. In situ attenuated total reflection surface-enhanced infrared absorption spectroscopy and in situ Raman spectroscopy reveal that Ir/MoO(2)-Mo(2)C-800 can reconstruct the distribution equilibrium of the hydrogen-bond network of interfacial water to promote water adsorption and dissociation. The highly exposed Ir active sites and MSI enable Ir/MoO(2)-Mo(2)C-800 to exhibit extremely low overpotentials of 32 (alkaline), 14 (acidic), and 29 (neutral) mV at 10 mA cm(-2), respectively. Moreover, the mass activities of Ir/MoO(2)-Mo(2)C-800 (9.23, 60.99, and 8.34 A mg(-1) (PGM)) are 2.68-, 28.27-, and 3.93-fold higher than those of commercial Pt/C (3.45, 2.16, and 2.12 A mg(-1) (PGM)), respectively. The assembled Ir/MoO(2)-Mo(2)C-800 ‖ IrO(2) anion-exchange membrane (AEM) water electrolyzer demonstrates stable operation for over 700/220 h at a high current density of 0.2/1 A cm(-2) and Ir/MoO(2)-Mo(2)C-800 can maintain its initial morphology. This study proposes a feasible strategy to achieve highly efficient and stable pH-universal HER by developing electrocatalysts with high concentration Ir active sites and MSI engineering.