Transient Polarization and Dendrite Initiation Dynamics in Ceramic Electrolytes
Rajeev Gopal, Longan Wu, Youngju Lee, Jinzhao Guo, Peng Bai
Abstract
Solid-state electrolytes combined with lithium-metal anodes have the potential to improve the energy density of lithium-ion batteries. However, soft Li metal can still penetrate these stiff electrolytes above a critical current density (CCD). Prevailing methods to determine CCD suffer inconsistencies due to void formations after repeated stripping and plating, leaving significant variations in reported data. Here, we combine one-way linear sweep voltammetry (LSV) with electrochemical impedance spectroscopy (EIS) to uncover the existence of significant polarization in ceramic electrolytes, which can fully relax even without stacking pressure. At high scan rates, LSV experiments showed metal penetration with a diverging transient current, similar to CCD values. However, at a lowered scan rate, the transient current reaches a maximum, suggesting a dynamic electrochemical limiting mechanism. The results and analysis of many consistent samples suggest that polarization of mobile charge carriers preceding the maximum current is critical for accurately understanding dendrite penetration in ceramic electrolytes.