Abstract
Al-doped Li7La3Zr2O12 (LLZO) solid electrolyte is a promising candidate for all-solid-state lithium battery (ASSB) due to its high ionic conductivity and stability against lithium metal. Dense LLZO pellets were prepared by high-temperature sintering and a Li3BO3 melting agent was used to control the microstructure (grain size and grain boundary chemistry). An ionic conductivity of 0.49 mS·cm−1 was measured at room temperature. The LLZO/Li interface was modified by introducing an aluminum layer. The impact of the microstructure of LLZO ceramics and the chemistry of the LLZO/Li interface were discussed by measuring the critical current density (CCD). Even though secondary phases at the grain boundary lead to an increase of the electronic conductivity, no significant influence of the microstructure on the CCD value (50 μA·cm−2) has been established. The low CCD value has been improved by forming an Al-Li alloy interlayer at the LLZO/Li interface, due to a better homogenization of the Li current at the interface. In parallel, the applied pressure (0.09 MPa vs. 0.4 MPa) has been studied and did impact the CCD. A value of 0.35 μA·cm−2 was measured. These results highlight the conditions needed for keeping a good electrolyte/Li interface during the cycling of a solid state battery.
Highlights
To cite this version: Thibaut Dussart, Nicolas Rividi, Michel Fialin, Gwenaëlle Toussaint, Philippe Stevens, et al
The use of a lithium electrode in a conventional Li-ion battery leads to an unstable solid electrolyte interface (SEI) and short-circuits are observed when lithium dendrites grow during plating which penetrates the polymer separator.[2]
Solid electrolytes can facilitate the use of the metallic lithium electrode and overcome the safety issues related to the flammability of conventional organic liquid electrolytes.[3]
Summary
To cite this version: Thibaut Dussart, Nicolas Rividi, Michel Fialin, Gwenaëlle Toussaint, Philippe Stevens, et al.
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