Li 2 ZnCu 3 Modified Cu Current Collector to Regulate Li Deposition

Rationally designing a current collector that can maintain low lithium (Li) porosity and smooth morphology while enduring high‐loading Li deposition is crucial for realizing the high energy density of Li metal batteries, but it is still challengeable. Herein, a Li 2 ZnCu 3 alloy‐modified Cu foil is...

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Published in:Angewandte Chemie 2024-11
Main Authors: Cao, Jiaqi, Chen, Weixin, Gao, Aosong, Muhtar, Dilxat, Du, Guangyuan, Qian, Guoyu, Lu, Xueyi, Xie, Fangyan, Sun, Yang, Lu, Xia
Format: Article
Language:English
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Summary:Rationally designing a current collector that can maintain low lithium (Li) porosity and smooth morphology while enduring high‐loading Li deposition is crucial for realizing the high energy density of Li metal batteries, but it is still challengeable. Herein, a Li 2 ZnCu 3 alloy‐modified Cu foil is reported as a stable current collector to fulfill the stable high‐loading Li deposition. Benefiting from the in situ alloying, the generated numerous Li 2 ZnCu 3 @Cu heterojunctions induce a homogeneous Li nucleation and dense growth even at an ultrahigh capacity of 12 mAh cm −2 . Such a spatial structure endows the overall Li 2 ZnCu 3 @Cu electrode with the manipulated steric hindrance and outmost surface electric potential to suppress the side reactions during Li stripping and plating. The resultant Li||Li 2 ZnCu 3 @Cu asymmetric cell preserves an ultrahigh average Coulombic efficiency of 99.2 % at 3 mA cm −2 /6 mAh cm −2 over 200 cycles. Moreover, the Li‐Li 2 ZnCu 3 @Cu||LiFePO 4 cell maintains a cycling stability of 87.5 % after 300 cycles. After coupling with the LiCoO 2 cathode (4 mAh cm −2 ), the cell exhibits a high energy density of 407.4 Wh kg −1 with remarkable cycling reversibility at an N/P ratio of 3. All these findings present a doable way to realize the high‐capacity, dendrite‐free, and dense Li deposition for high‐performance Li metal batteries.
ISSN:0044-8249
1521-3757
DOI:10.1002/ange.202413065