锡
阳极
材料科学
阴极
成核
纳米技术
退火(玻璃)
化学工程
复合材料
冶金
电极
化学
物理化学
有机化学
工程类
作者
Xiaoyu Wu,Xing Chen,Yatao Yan,Guowang Diao,Hui Yan,Lubin Ni,Yuanzhe Piao,Ming Chen
出处
期刊:Advanced Science
[Wiley]
日期:2024-05-31
卷期号:11 (29): e2403224-e2403224
被引量:15
标识
DOI:10.1002/advs.202403224
摘要
Abstract The advancement of Zn–Se batteries has been hindered by significant challenges, such as the sluggish kinetics of Se cathodes, limited Se loading, and uncontrollable formation of Zn dendrites. In this study, a bidirectional optimization strategy is devised for both cathode and anode to bolster the performance of Zn–Se batteries. A novel bowl‐in‐ball structured carbon (BIBCs) material is synthesized to serve as a nanoreactor, in which tin‐based materials are grown and derived in situ to construct cathodes and anodes. Within the cathode, the multifunctional host material (SnSe@BIBCs) exhibits large adsorption capacity for selenium, and demonstrates supreme catalytic properties and spatially confined characteristics toward the selenium reduction reaction (SeRR). On the anode, Sn@BIBCs displays triple‐induced properties, including the zincophilic of the internal metallic Sn, the homogenized spatial electric field from the 3D spatial structure, and the curvature effect of the bowl‐shaped carbon. Collectively, these factors induce preferential nucleation of Zn, ensuring its uniform deposition. As a result, the integrated Zn–Se battery system achieves a remarkable specific capacity of up to 603 mAh g −1 and an impressive energy density of 581 W kg −1 , highlighting its tremendous potential for practical applications.
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