化学
催化作用
析氧
过电位
氧气
无机化学
电化学
扩散
电解水
脱质子化
电解
氧气输送
质子输运
氧气储存
反应机理
分解水
催化氧化
电催化剂
化学工程
多相催化
极限氧浓度
本体电解
质子交换膜燃料电池
作者
Bichen Yuan,Zhe Shang,Susu Zhao,Aiqing Cao,Shitao Min,Jian Peng,Hui Li,Fengmei Wang,Xiaoming Sun
摘要
The instability of ruthenium-based catalysts during the acidic oxygen evolution reaction (OER) remains an obstacle to their practical implementation. In this work, we explore the dynamic self-optimization process (e.g., depletion, migration, and self-healing) of oxygen species in a Mn and Ta codoped RuO2 catalyst (i.e., MTRO), which acts as a model catalyst for stabilizing the active site during the acidic OER. By integrating tetramethylammonium cation (TMA+) chemical probes specific to deprotonated surface oxygen species with differential electrochemical mass spectrometry analysis, we tracked oxygen behavior, revealing that the reaction mechanism shifts from an initial lattice oxygen mechanism (LOM) to a subsequent adsorbate evolution mechanism (AEM). Analysis of the oxygen diffusion coefficient (e.g., DO) during the LOM pathway indicates that oxygen transportation drives reconstruction of the catalysts, while only moderate transportation could result in a structurally stable catalyst with a constant Ru–O coordination number and an optimal balance between high activity and durability: After codoping Mn and Ta into the RuO2, the DO reaches 1.40 × 10–15 cm2 s–1, which is 1/9 that of undoped RuO2, ∼25 times that of Mn-doped RuO2 (MRO). The optimized MTRO catalyst exhibits a low overpotential of 215 mV at 10 mA cm–2 and operates stably for over 1200 h in 0.5 M H2SO4, as well as 600 h of continuous operation in a proton exchange membrane electrolyzer at 0.5 A cm–2. This work elucidates that the “real” working OER catalysts based on RuO2 can be of a defective low-coordination structure (in contrast to perfect crystals) with moderate oxygen diffusion efficiency, formed through in situ self-optimization that simultaneously modulates the catalytic reaction pathway.
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