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Article Abstract
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 LiZnCu 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 LiZnCu@Cu heterojunctions induce a homogeneous Li nucleation and dense growth even at an ultrahigh capacity of 12 mAh cm. Such a spatial structure endows the overall LiZnCu@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||LiZnCu@Cu asymmetric cell preserves an ultrahigh average Coulombic efficiency of 99.2 % at 3 mA cm/6 mAh cm over 200 cycles. Moreover, the Li-LiZnCu@Cu||LiFePO cell maintains a cycling stability of 87.5 % after 300 cycles. After coupling with the LiCoO cathode (4 mAh cm), the cell exhibits a high energy density of 407.4 Wh kg 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.
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