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The Entanglement of Li Capping and Deposition: An <i>Operando</i> Optical Microscopy Study

Chen−Jui Huang, Hsien‐Chu Tao, Pei-Jung Chao, Chunying Li, Boas Tua Hotasi, Hsin‐Yueh Liu, Ming‐Hsien Lin, She‐Huang Wu, Wei‐Nien Su, Bing−Joe Hwang

2023ACS Nano28 citationsDOI

Abstract

Dendrite growth and low Coulombic efficiency impede the practical application of Li-metal batteries. As such, monitoring Li deposition and stripping in real-time is crucial to understanding the fundamental lithium growth kinetics. This work presents an operando optical microscopic technique that enables precise current density control and quantification of Li layer properties (i.e., thickness and porosity) to study Li growth in various electrolytes. We discover the robustness and porosity of the remaining capping layer after the Li stripping process as the critical features governing the subsequent dendrite propagation behavior, resulting in distinct capping and stacking phenomena that affect Li growth upon cycling. While dendrite propagation quickly occurs through the fracture of the fragile Li capping layer, uniform Li plating/stripping can be facilitated by the compact and robust capping layer even at high current densities. This technique can be extended to evaluate dendrite suppression treatments in various metal batteries, providing in-depth information on metal growth mechanisms.

Topics & Concepts

Faraday efficiencyMaterials scienceStackingStripping (fiber)Dendrite (mathematics)PorosityOptical microscopeLayer (electronics)NanotechnologyChemical engineeringElectrolyteElectrodeComposite materialScanning electron microscopeChemistryMathematicsPhysical chemistryGeometryOrganic chemistryEngineeringAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research
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