A Guideline to Mitigate Interfacial Degradation Processes in Solid‐State Batteries Caused by Cross Diffusion

Diffusion of transition metals across the cathode–electrolyte interface is identified as a key challenge for the practical realization of solid‐state batteries. This is related to the formation of highly resistive interphases impeding the charge transport across the materials. Herein, the hypothesis...

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Bibliographic Details
Published in:Advanced functional materials 2023-10, Vol.33 (42)
Main Authors: Din, Mir Mehraj Ud, Ladenstein, Lukas, Ring, Joseph, Knez, Daniel, Smetaczek, Stefan, Kubicek, Markus, Sadeqi‐Moqadam, Mohsen, Ganschow, Steffen, Salagre, Elena, Michel, Enrique G., Lode, Stefanie, Kothleitner, Gerald, Dugulan, Iulian, Smith, Jeffrey G., Limbeck, Andreas, Fleig, Jürgen, Siegel, Donald J., Redhammer, Günther J., Rettenwander, Daniel
Format: Article
Language:English
Subjects:
Aluminum oxide
Charge materials
Charge transport
Cobalt
Degradation
Diffusion coefficient
Electrochemical analysis
Fugacity
Materials science
Optimization
Phase transitions
Protective coatings
Temperature dependence
Transition metals
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Summary:Diffusion of transition metals across the cathode–electrolyte interface is identified as a key challenge for the practical realization of solid‐state batteries. This is related to the formation of highly resistive interphases impeding the charge transport across the materials. Herein, the hypothesis that formation of interphases is associated with the incorporation of Co into the Li 7 La 3 Zr 2 O 12 lattice representing the starting point of a cascade of degradation processes is investigated. It is shown that Co incorporates into the garnet structure preferably four‐fold coordinated as Co 2+ or Co 3+ depending on oxygen fugacity. The solubility limit of Co is determined to be around 0.16 per formula unit, whereby concentrations beyond this limit causes a cubic‐to‐tetragonal phase transition. Moreover, the temperature‐dependent Co diffusion coefficient is determined, for example, D 700 °C = 9.46 × 10 −14 cm 2 s −1 and an activation energy E a = 1.65 eV, suggesting that detrimental cross diffusion will take place at any relevant process condition. Additionally, the optimal protective Al 2 O 3 coating thickness for relevant temperatures is studied, which allows to create a process diagram to mitigate any degradation with a minimum compromise on electrochemical performance. This study provides a tool to optimize processing conditions toward developing high energy density solid‐state batteries.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202303680