材料科学
离解(化学)
异质结
电子转移
吸附
催化作用
阴极
氧气
拉曼光谱
化学工程
动力学
光化学
氧还原反应
电子
动能
电化学
氧还原
纳米技术
原位
电极
储能
化学物理
氧化还原
电池(电)
可再生能源
一氧化碳
红外线的
光电子学
碳纤维
能量转移
电压
作者
Shuya Zhang,Qiming Chen,Liangyu Zheng,Mingjun Cen,Xinyu Luo,P. W. Zhao,Qicheng Zhang,Yang Li,Wenchao Peng,Xiaobin Fan
标识
DOI:10.1002/adma.202514607
摘要
Abstract The sluggish kinetics of the oxygen reduction reaction (ORR) impede the widespread adoption of renewable energy technologies. Here, a heterostructured Fe 2 N/CrN x @NC catalyst is presented, where CrN x clusters promote H 2 O dissociation and, in concert with Fe 2 N nanoparticles, optimize oxygen intermediates adsorption within an N‐doped carbon matrix. The CrN x ‐induced synergy is further confirmed by in situ Raman and infrared spectroscopy, kinetic isotope effect measurements, and theoretical analyses, which collectively reveal that the elaborate Fe 2 N–CrN x interface is pivotal in accelerating proton‐coupled electron transfer for ORR. As a result, Fe 2 N/CrN x @NC achieves a half‐wave potential of 0.935 V in 0.1 m KOH, exceeding Pt/C. When deployed as the air cathode in aluminum‐air batteries, Fe 2 N/CrN x @NC enables a high discharge voltage at 100 mA cm −2 and an outstanding specific capacity of 2286 mA h g Al −1 . This heterostructure engineering strategy, cooperatively manipulating water dissociation and intermediate adsorption, provides a generalized design paradigm for efficient aluminum‐air battery cathodes.
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