溶剂化
电催化剂
催化作用
电解质
位阻效应
氧气
材料科学
水溶液
化学物理
溶剂化壳
化学工程
金属
析氧
光化学
化学
质子
工作(物理)
配体(生物化学)
密度泛函理论
氧还原反应
反应中间体
无机化学
动力学
纳米技术
电极
分子动力学
燃料电池
生物电化学
工作职能
作者
Zhaoyang Han,Ruihui Gan,Tao Gong,Longji Yuan,Wenliang Feng,Huici Qiao,Yuzhe Liu,Jinzhu Zhu,Ruisong Li,Xulei Sui,Yongping Zheng,Guangjie Shao,Zhenbo Wang
标识
DOI:10.1002/adma.202523627
摘要
The electrocatalytic performance is governed by the immediate microenvironment surrounding the active site, particularly the hydrogen-bond network that stabilizes reaction intermediates. While cation effects in aqueous electrolytes allow tuning of this network, this powerful leveraging is absent in proton-exchange membrane fuel cells (PEMFCs), where proton is the sole cation. Here, we demonstrate a general strategy of "immobilized molecular perturbation" for single-atom catalysts, which moves the tuning function from the electrolyte to the catalyst's second coordination sphere. Using the oxygen reduction reaction (ORR) on Fe─N─C as a model, we demonstrate that proximal P─O groups act as steric and hydrogen-bonding perturbers. This engineered microenvironment selectively weakens the solvation shell of key *OH intermediates, as confirmed by spectroscopy and computations, thereby facilitating the rate-determining step of *OH desorption. This regulation endows the catalyst with exceptional performance, achieving a half-wave potential of 0.861 V in 0.5 m H2SO4 and a peak power density of 1024 mW cm-2 in a H2/O2 PEMFC. Furthermore, it exhibits outstanding stability with 72 % current retention after 253 h at 0.65 V, positioning it among the best-reported non-precious metal catalysts. This work shifts the paradigm from exclusive active-center optimization to deliberate local microenvironment engineering, enabling accelerated electrocatalysis in device-relevant environments.
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