Kinetics of Interfacial Ion Transfer in Lithium-Ion Batteries: Mechanism Understanding and Improvement Strategies.

The development of high-rate lithium-ion batteries is required for automobile applications. To this end, internal resistances must be reduced, among which Li + transfer resistance at electrode/electrolyte interfaces is known to be the largest. Hence, it is of urgent significance to understand the mechanism and kinetics of the interfacial Li + transfer. This Spotlight on Applications presents recent progress in the analysis and mechanical understanding of interfacial Li + transfer. First, we review the reported activation energies ( E a ) at various solid/liquid interfaces. On this basis, the mechanism and rate-determining step of the interfacial Li + transfer are discussed from the viewpoints of the desolvation of Li + , the nature of the solid electrolyte interphase (SEI), and the surface structural features of electrodes. After that, we introduce promising strategies to reduce the E a , highlighting some specific cases that give remarkably low E a . We also note the variations in frequency factors or pre-exponential factors ( A ) of the interfacial Li + transfer, which are primarily dominated by the number of Li + intercalation sites on electrode surfaces. The current understanding and improvement strategies of interfacial Li + transfer kinetics presented herein will be a foundation for designing high-rate lithium-ion batteries.