材料科学
合理设计
催化作用
Crystal(编程语言)
碳纤维
工作(物理)
多孔性
大规模运输
纳米技术
化学物理
领域(数学)
氧气
自旋(空气动力学)
动能
化学工程
调制(音乐)
密度泛函理论
电催化剂
活化能
晶体结构
功率密度
功率(物理)
纳米结构
晶体工程
力场(虚构)
能量转换
析氧
电子传输链
电压
作者
Yangfan Pei,Liansheng Lan,Xiannong Tang,Ting Hu,Longbin Li,Dirk Lützenkirchen−Hecht,Kai Yuan,Yiwang Chen
摘要
ABSTRACT The oxygen reduction reaction (ORR) is central to next‐generation energy technologies, but its practical implementation is constrained by inherently sluggish kinetics. Herein, we propose a bioinspired strategy that synergistically integrate atomic‐scale crystal field engineering and hierarchical porosity design, effectively tackling the intrinsic activity and mass transport limitations of ORR. This strategy is realized in a Fe/Co dual‐metallic single‐atom sites anchored on hierarchical meso/microporous N‐doped carbon matrices (MPNC‐FeCo‐x). The optimized MPNC‐FeCo‐4 exhibits remarkable ORR performance with a half‐wave potential of 0.923 V and a turnover frequency of 2.01 e – site −1 s −1 in alkaline media. When deployed in zinc‐air batteries, it delivers an ultrahigh peak power density of 232.81 mW cm −2 and unprecedented cycling stability over 800 h. Mechanistic studies reveal that Co atoms modulate the crystal field to induce the spin transition of Fe species to medium spin ( t 2g 4 e g 1 configuration), while the hierarchical pore architecture enhancing charge and mass transfer. Advanced stepwise interfacial kinetic analysis quantifies how the enhanced intrinsic activity and the optimized mass transport cooperate to enhance ORR performance. This work establishes a paradigm for manipulating spin states via rational crystal field design in multi‐metallic single‐atom systems, providing fundamental insights into structure‐activity relationships for energy conversion technologies.
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