Pressure and polymer selections for solid-state batteries investigated with high-throughput simulations

Polymer coatings and high mechanical pressure are promising solu-tions for improving interfacial contact in all-solid-state lithium metal batteries. However, design guidelines for polymer type, thickness, and stack pressure are still missing. In this study, we present a model for mechanics at the interface of polymer-coated solid-state electro-lytes in contact with a lithium metal anode, considering lithium creep, polymer viscoelasticity, and pressure-driven electrochem-istry. We cover various common polymer coatings, eventually high-lighting the dependence of interfacial resistance on stack pressure and coating thickness. A machine learning algorithm with high -throughput calculations is used to optimize the combination of pressure and coating thicknesses. Numerical results are in good agreement with existing experimental evidence. A transition map is derived, which may serve as design guideline in predicting the values of current density, stack pressure, and polymeric thickness able to ensure a over time.