All solid state lithium-ion batteries are a promising battery design, which has several advantages over liquid electrolyte based lithium-ion batteries. However, significant effort is expected to be required to solve several issues like mechanical degradation and insufficient rate capability of all solid state lithium-ion batteries. In this context, modeling of the relevant phenomena can help to fully understand and reduce/eliminate these problems. The present research aims at the development and numerical evaluation of an appropriate electrochemomechanical continuum modeling approach, which is applicable on the macro-scale as well as on the micro-scale. The model will be stated in terms of a rate-type variational principle, thereby enabling for a rather compact, thermodynamically consistent formulation. Moreover, the variational principle allows for the application of robust and efficient numerical solution schemes, which will likewise be developed. The resulting space-time discrete formulation will be applied to the modeling of problems representative of situations occurring in the context of all solid state lithium-ion batteries. This is intended to provide the basis for future systematic studies and optimization of the properties of all solid state lithium-ion batteries.

DFG Programme Research Fellowships

International Connection South Africa

Host Professor Daya Reddy