Phenomenological model of lithium-ion battery formation cycling and aging

This work proposes a semi-empirical model for the SEI growth process during the early stages of lithium-ion battery formation cycling and aging. By combining a full-cell model which tracks half-cell equilibrium potentials, a zero-dimensional model of SEI growth kinetics, and a semi-empirical description of macroscopic cell expansion, the resulting model replicated experimental trends measured on a 2.5 Ah pouch cell, including the first-cycle efficiency, cell thickness changes, and electrolyte reduction peaks during the first charge dQ/dV signal. This work also introduces an SEI growth boosting formalism which enables a unified description of SEI growth during both formation cycling and aging. The model further provides a homogenized representation of multi-component SEI reactions which enables the study of both solvent and additive consumption during formation. This work bridges the gap between electrochemical descriptions of SEI growth and applications towards industrial battery manufacturing technology where battery formation is an essential but time-consuming final step. We envision that the formation model can further be used to predict the impact of formation protocols and electrolyte systems on SEI passivation and resulting battery longevity.