Dong, Bo Yeandel, Stephen R Goddard, Pooja Slater, Peter R Combined experimental and computational study of Ce-doped La3Zr2Li7O12 garnet solid-state electrolyte Li-containing garnet materials have been attracting considerable interest as potential solid-state electrolytes for Li ion batteries. In such Ln3M2LixO12 (Ln = lanthanide, alkaline earth; M = Zr, Hf, Sn, Nb, Ta, Sb, Bi, Te), the best Li ion conductivity is observed for Li contents, x, just below the maximum 7.0. The decrease in conductivity for x = 7.0 systems is related to Li ordering (cell changes from cubic to tetragonal) to prevent too short Li-Li interactions. In this work, we report a combined experimental and modeling study of Ce4+ doping in La3Zr2Li7O12. We show for the first time that Ce4+ can be doped onto the Zr4+ site in this material. This doping strategy results in a reduction in the tetragonal distortion as well as a lowering of the temperature of the tetragonal-cubic phase transition, attributed to the increase in cell size reducing Li-Li interaction strain. Coupled with these changes, the conductivity shows a significant (1.5 orders of magnitude) improvement. Furthermore, the Ce doping also reduces the interfacial resistance (388 ω cm2 for Li7La3Z1.75Ce025O12) in contact with Li metal, giving additional potential benefits to this doping strategy. The long-term cycling stability of a Li//garnet//Li symmetric cell over 190 h has been demonstrated. Electrochemical cells;Electrical conductivity;Lithium;Doping;Ions 2020-02-03
    https://repository.lboro.ac.uk/articles/journal_contribution/Combined_experimental_and_computational_study_of_Ce-doped_La3Zr2Li7O12_garnet_solid-state_electrolyte/11786775