English

Lithium-ion battery performance model including solvent segregation effects

Chemical Physics 2023-11-10 v1

Abstract

A model of a lithium-ion battery containing a cosolvent electrolyte is developed and implemented within the open-source PyBaMM platform. Lithium-ion electrolytes are essential to battery operation and normally contain at least two solvents to satisfy performance requirements. The widely used Doyle-Fuller-Newman battery model assumes that the electrolyte comprises a salt dissolved in a single effective solvent, however. This single-solvent approximation has been disproved experimentally and may hinder accurate battery modelling. Here, we present a two-solvent model that resolves the transport of ethylene carbonate (EC) and lithium salt in a background linear carbonate. EC concentration polarization opposes that of Li+ during cycling, affecting local electrolyte properties and cell-level overpotentials. Concentration gradients of Li+ can be affected by cross-diffusion, whereby EC gradients enhance or impede salt flux. A rationally parametrized model that includes EC transport predicts 6% more power loss at 4.5C discharge and ~0.32% more capacity loss after a thousand 1C cycles than its single-solvent equivalent. This work provides a tool to model more transport behaviour in the electrolyte that may affect degradation and enables the transfer of microscopic knowledge about solvation structure-dependent performance to the macroscale.

Keywords

Cite

@article{arxiv.2311.05467,
  title  = {Lithium-ion battery performance model including solvent segregation effects},
  author = {Ruihe Li and Simon O'Kane and Andrew Wang and Taeho Jung and Niall Kirkaldy and Monica Marinescu and Charles W. Monroe and Gregory J. Offer},
  journal= {arXiv preprint arXiv:2311.05467},
  year   = {2023}
}
R2 v1 2026-06-28T13:16:24.261Z