Abstract
AbstractLow active material loading in the composite electrode of all‐solid‐state batteries (SSBs) is one of the main reasons for the low energy density in current SSBs. In this work, it is demonstrated with both modeling and experiments that in the regime of high cathode loading, the utilization of cathode material in the solid‐state composite is highly dependent on the particle size ratio of the cathode to the solid‐state conductor. The modeling, confirmed by experimental data, shows that higher cathode loading and therefore an increased energy density can be achieved by increasing the ratio of the cathode to conductor particle size. These results are consistent with ionic percolation being the limiting factor in cold‐pressed solid‐state cathode materials and provide specific guidelines on how to improve the energy density of composite cathodes for solid‐state batteries. By reducing solid electrolyte particle size and increasing the cathode active material particle size, over 50 vol% cathode active material loading with high cathode utilization is able to be experimentally achieved, demonstrating that a commercially‐relevant, energy‐dense cathode composite is achievable through simple mixing and pressing method.
Highlights
All-solid-state batteries (SSBs) have become an exciting energy competitive with conventional lithium-ion batteries
We systematically studied the relation between cathode loading, cathode utilization, and the particle size of the CAM and the SE through a basic model for the composite cathode
We have demonstrated the effect of the cathode to SE particle size ratio (λ) on the cathode utilization and loading tolerance in cold-pressed SSBs
Summary
All-solid-state batteries (SSBs) have become an exciting energy competitive with conventional lithium-ion batteries. An optimal storage technology to replace conventional lithium-ion batteries.[1,2] composite cathode morphology should have minimal void. They improve safety by removing organic carbonate-based liquid space and good cathode/SE contact, and include the minimum electrolytes and can potentially increase energy density by utilizing amount of SE needed to ensure sufficient Li diffusion between a Li-metal anode.[3] while proof of concept of SSBs has the CAM and bulk electrolyte. Our results provide simple design guidelines to improve the energy density of solid-state batteries by achieving high CAM loading in the composite cathode
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