法拉第效率
表面改性
阳极
成核
锂(药物)
原子层沉积
材料科学
剥离(纤维)
纳米技术
溶解
沉积(地质)
阴极
集电器
图层(电子)
电极
电解质
化学
化学工程
复合材料
工程类
医学
物理化学
生物
内分泌学
古生物学
有机化学
沉积物
作者
Kuan‐Hung Chen,Adrian J. Sanchez,Eric Kazyak,Andrew L. Davis,Neil P. Dasgupta
标识
DOI:10.1002/aenm.201802534
摘要
Abstract Improving the performance of Li metal anodes is a critical bottleneck to enable next‐generation battery systems beyond Li‐ion. However, stability issues originating from undesirable electrode/electrolyte interactions and Li dendrite formation have impaired long‐term cycling of Li metal anodes. Herein, a bottom‐up fabrication process is demonstrated for a current collector for Li metal electrodeposition and dissolution composed of highly uniform vertically aligned Cu pillars. By rationally controlling geometric parameters of the 3D current collector architecture, including pillar diameter, spacing, and length, the morphology of Li plating/stripping upon cycling can be controlled and optimal cycling performance can be achieved. In addition, it is demonstrated that deposition of an ultrathin layer of ZnO by atomic layer deposition on the current collector surface can facilitate the initial Li nucleation, which dictates the morphology and reversibility of subsequent cycling. This core–shell pillar architecture allows for the effects of geometry and surface chemistry to be decoupled and individually controlled to optimize the electrode performance in a synergistic manner. Using this platform, Li metal anodes are demonstrated with Coulombic efficiency up to 99.5%, providing a pathway toward high‐efficiency and long‐cycle life Li metal batteries with reduced excess Li loading.
科研通智能强力驱动
Strongly Powered by AbleSci AI