Roll‐to‐roll fabrication of lithiophilic Sn‐modified Cu mesh via chemical tin plating approach for long‐cycling lithium metal batteries
Kexin Liu, Ran Tan, Zhong Zheng, Rui‐Rui Zhao, Burak Ülgüt, Xinping Ai, Jiangfeng Qian
Abstract
Abstract Lithium metal, with its exceptionally high theoretical capacity, emerges as the optimal anode choice for high‐energy‐density rechargeable batteries. Nevertheless, the practical application of lithium metal batteries (LMBs) is constrained by issues such as lithium dendrite growth and low Coulombic efficiency (CE). Herein, a roll‐to‐roll approach is adopted to prepare meter‐scale, lithiophilic Sn‐modified Cu mesh (Sn@Cu mesh) as the current collector for long‐cycle lithium metal batteries. The two‐dimensional (2D) nucleation mechanism on Sn@Cu mesh electrodes promotes a uniform Li flux, facilitating the deposition of Li metal in a large granular morphology. Simultaneously, experimental and computational analyses revealed that the distribution of the electric field in the Cu mesh skeleton induces Li inward growth, thereby generating a uniform, dense composite Li anode. Moreover, the Sn@Cu mesh‐Li symmetrical cell demonstrates stable cycling for over 2000 h with an ultra‐low 10 mV voltage polarization. In Li||Cu half‐cells, the Sn@Cu mesh electrode demonstrates stable cycling for 100 cycles at a high areal capacity of 5 mAh·cm −2 , achieving a CE of 99.2%. This study introduces a simple and large‐scale approach for the production of lithiophilic three‐dimensional (3D) current collectors, providing more possibilities for the scalable application of Li metal batteries.