<p>High-valence Ru<sup><i>n</i>+</sup> (<i>n</i> &gt; 4) sites possess high catalytic activity to negotiate the sluggish oxygen evolution reaction in proton exchange membrane water electrolysis, but undergo thermodynamic instability. The synthesis of Ru-based catalysts with stable high-valence Ru sites remains challenging. Here, we present an interstitial nitrogen doping strategy to trigger a charge symmetry breaking for the stabilization of high-valence Ru sites in ruthenium dioxide. The resultant catalyst requires a low overpotential of 195 mV at 10 mA cm<sup>-2</sup> and operates stably with negligible activity drop over 1000 hours. In-depth electrochemical characterizations combined with in-situ spectroscopic studies reveal that the presence of high-valence Ru sites accelerates the charge accumulation for the chemical bond making/breaking and water dissociation at the reaction interface, leading to enhanced kinetics. Additionally, the strong Ru-N electronic coupling and weak Ru-O covalency suppress the Ru oxidative dissolution and lattice oxygen oxidation, accounting for the long-term stability. A realistic water electrolysis cell assembled with this catalyst at the anode achieves 1000 mA cm<sup>-2</sup> at 1.79 volts and can run steadily for at least 300 hours.</p>

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Charge symmetry breaking stabilizes high-valence Ru sites for proton exchange membrane electrolysis

  • Sheng Zhu,
  • Chen Dong,
  • Yu Shen,
  • Shuai-Qi Gong,
  • Ming-Rong Qu,
  • Xiao-Long Zhang,
  • Rui-Qi Liu,
  • Wen-Sheng Yan,
  • He-Xing Li,
  • Yu-Lin Min,
  • Min-Rui Gao,
  • Shu-Hong Yu

摘要

High-valence Run+ (n > 4) sites possess high catalytic activity to negotiate the sluggish oxygen evolution reaction in proton exchange membrane water electrolysis, but undergo thermodynamic instability. The synthesis of Ru-based catalysts with stable high-valence Ru sites remains challenging. Here, we present an interstitial nitrogen doping strategy to trigger a charge symmetry breaking for the stabilization of high-valence Ru sites in ruthenium dioxide. The resultant catalyst requires a low overpotential of 195 mV at 10 mA cm-2 and operates stably with negligible activity drop over 1000 hours. In-depth electrochemical characterizations combined with in-situ spectroscopic studies reveal that the presence of high-valence Ru sites accelerates the charge accumulation for the chemical bond making/breaking and water dissociation at the reaction interface, leading to enhanced kinetics. Additionally, the strong Ru-N electronic coupling and weak Ru-O covalency suppress the Ru oxidative dissolution and lattice oxygen oxidation, accounting for the long-term stability. A realistic water electrolysis cell assembled with this catalyst at the anode achieves 1000 mA cm-2 at 1.79 volts and can run steadily for at least 300 hours.