过电位
材料科学
双功能
电催化剂
极化(电化学)
析氧
钴
原子轨道
自旋极化
二硒醚
石墨烯
自旋(空气动力学)
硒
铁磁性
氧气
纳米技术
化学物理
光电子学
多稳态
金属
电子结构
自旋态
过渡金属
催化作用
凝聚态物理
硫族元素
铜
作者
Sichen Huo,Xinyu Wang,Yanjie Chen,Jiannan Du,Hang Yue,Jitao Li,Li Li,Ying Dai,Gengtao Fu,Jinlong Zou
摘要
ABSTRACT Spin polarization of metal active centers provides a powerful means to mitigate the spin flipping of key intermediates during electrocatalysis. However, effectively triggering spin polarization and establishing its relationship with performance in oxygen reduction/evolution reactions (ORR/OER) remain challenging. This study proposes a defect engineering means that creates selenium vacancies (Se V ) in cobalt diselenide (CoSe 2 ) integrated onto an iron single‐atom platform (Fe SA @CoSe 2 ‐Se V ) to enhance Co's spin polarization. Fe SA @CoSe 2 ‐Se V achieves a high ORR half‐wave potential (0.921 V) and a low OER overpotential (370 mV@10 mA cm −2 ), significantly outperforming Fe SA @CoSe 2 . When applied to zinc‐air battery (ZAB), it achieves a high power‐density (186 mW cm −2 ), with a cycling life of up to 582 h. Fe SA @CoSe 2 ‐Se V ‐based flexible ZAB maintains stable charge/discharge performance even under 0°–180° bending conditions. Introduction of Se V reduces the degeneracy of the Co 3 d orbitals, effectively triggering spin polarization. This electronic structure reconstruction causes the π* orbital of Co‐*O/*OH to lose an electron, enhancing the hybridization between Co 3 d and *O/*OH 2 p orbitals and thereby mitigating the intermediates' spin flipping. Ferromagnetic Fe SA stabilizes the Se V and Co active sites, ensuring the structural/catalytic stability. This work confirms the effectiveness of Se V ‐induced spin polarization regulation, providing a novel spintronics‐based approach for designing bifunctional electrocatalysts.
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