钙钛矿(结构)
材料科学
催化作用
氧化物
无定形固体
氧气
氧还原
燃料电池
化学工程
降级(电信)
氧还原反应
纳米技术
复合氧化物
无机化学
格子(音乐)
工作(物理)
纳米晶
科技与社会
电极
固溶体
卤素
氧化还原
作者
Shengli Pang,Xudong He,Shuai Ma,Hao Lou,Kaijie Xu,Jintong Guan,Yi Zhuang,Xuyao Luo,Lingling Xu,Qiangsheng Xiao,Peijie Zhang,Yifei Gao,Xiaolu Song,Tenglong Zhu,Zhongti Sun,Chonglin Chen
标识
DOI:10.1002/adfm.202527046
摘要
Abstract Solid oxide fuel cells are promising technologies for renewable energy conversion, yet their practical deployment requires oxygen electrodes that simultaneously support rapid oxygen‐ion transport and sustained high‐activity oxygen reduction reaction (ORR) catalysis. However, constructing such a microchemical environment remains a persistent challenge for perovskite oxides. Here, it is demonstrated that Cl − incorporation into PrBaCo 2 O 5+δ partially replaces lattice oxygen, inducing localized metal–oxygen electronic states, enhanced lattice distortion, and Pr 3+ intermixing into BaO layers, collectively generating 3D fast pathways for oxygen‐ion diffusion. More significantly, it is revealed for the first time that Cl − preferentially segregates at the surface, forming an amorphous layer that creates an adaptive ORR interface and effectively overcomes the long‐standing issue of surface passivation. As a result, Cl − ‐engineered PrBaCo 2 O 5+δ achieves a 3–5‐fold increase in ORR activity relative to the parent oxide and exhibits outstanding durability at 750 °C, transforming ≈15.1% degradation over 100 h into a ≈2.7% performance gain. This work establishes a halogen‐mediated mechanism for tailoring perovskite microchemistry, challenges the prevailing view that halogens merely stabilize oxide lattices, demonstrates one of the most pronounced catalytic enhancements reported to date, and offers a broadly applicable strategy for designing advanced oxygen electrodes.
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