催化作用
化学
降级(电信)
电化学
清除
活性氧
水溶液
氧气
燃料电池
膜
激进的
氧化磷酸化
氧化还原
组合化学
工作(物理)
氧合物
合理设计
化学工程
焊剂(冶金)
电催化剂
反应机理
质子交换膜燃料电池
水介质
分解
碳纤维
光化学
动力学
氧还原反应
纳米技术
作者
Yuyan Wan,Dai Dang,Ning Yan
标识
DOI:10.1021/acscatal.6c01375
摘要
Oxygen reduction reaction (ORR) catalysts based on M-N-C materials often exhibit promising activity in aqueous electrochemical tests but suffer from rapid degradation under practical fuel cell operation. This discrepancy can originate from different reaction environments, where conventional measurements fail to reproduce the high flux of reactive oxygen species (ROS) present at the triple-phase boundary in membrane electrode assemblies (MEAs). Here, we establish an operando protocol that quantitatively bridges this gap by determining the concentration of H 2 O 2 and derived ROS under realistic fuel cell conditions and then reproducing such oxidative environments in aqueous media via H 2 O 2 injection. Using CoCe-NC as model catalysts, in which Co sites act as stable ROS generators and Ce sites serve as radical scavengers, we demonstrate that atomic-scale proximity between ROS generation and scavenging sites critically governs radical mitigation efficiency and catalyst stability. By tuning inter-site distances, we show that enhanced durability arises from accelerated and localized ROS removal rather than intrinsic stabilization of the carbon matrix. This work establishes a generalizable framework for quantifying and reproducing realistic oxidative environments, enabling mechanistic investigation of ROS-driven degradation that is inaccessible by conventional methods, and providing guidance for the rational design of durable PGM-free ORR catalysts.
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