材料科学
偶极子
氧化还原
化学物理
离子键合
铋
极化(电化学)
硫黄
催化作用
无定形固体
电子转移
电子
电子结构
阳极
相(物质)
纳米技术
化学工程
电偶极矩
化学极性
锂(药物)
吸附
电极
离子液体
极化密度
作者
Shunyou Hu,Huanchun Zhang,Yancen Li,Runcang Sun,Xi Zhang,Mingjie Yi,Yinze Zuo,Huan Pang
摘要
ABSTRACT The practical application of lithium‐sulfur batteries is severely hindered by the sluggish sulfur redox kinetics and the notorious lithium polysulfides (LiPSs) shuttle effect. Herein, we report a strategy utilizing an Fe‐based ionic liquid to trigger amorphization, engineering symmetry‐breaking p ‐block bismuth oxides on carbon nanofibers (CNFs) with electric dipole domains and asymmetric Fe 1 ‐O‐Bi electronic bridges (Fe 1 ⊂A/C‐Bi 2 O 3 @CNFs). The amorphous phase induces significant electronic delocalization, facilitating substantial orbital overlap and creating electron transport channels for rapid redox of LiPSs. Specifically, the asymmetric Fe 1 ‐O‐Bi electron bridges lower the p ‐band center through 3 d ‐2 p ‐6 p multi‐orbital coupling, optimizing the chemical adsorption of LiPSs and preventing active site poisoning. The electronic dipole domain functions as an electron/Li + “pump” to enhance charge transfer and Li + diffusion. In addition, the electric dipole domain induces dipole‐dipole interactions, facilitating Li─S bond polarization and cleavage. As a result, the Fe 1 ⊂A/C‐Bi 2 O 3 ‐based cell achieved a cyclability of 698 mAh g −1 at 1.0 C over 1000 cycles with a degradation rate of 0.026% per cycle, and a high areal capacity of 6.8 mAh cm −2 under a sulfur loading of 7.4 mg cm −2 . The strategy of constructing an electronic dipole domain through amorphization provides a new direction for the rational design of efficient catalysts for sulfur redox reactions.
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