Abstract

Abstract Garnet structured ceramic electrolyte Li 7 La 3 Zr 2 O 12 (LLZO) attracts much attention in solid‐state lithium batteries for its high ionic conductivity, wide electrochemical window, and lack of reducible element. However, the application of LLZO has been hindered by severe dendrite penetration. The theoretical investigations on the mechanisms of lithium dendrite evolution are carried out, aiming at quantifying the promotion effects of overpotential and the limitation counterpart of bulk modulus. Since dendrites preferentially propagate along connected defects, while intrinsic defects are difficult to be compeletely eliminated, manipulation of overpotential should be a more feasible way for dendrites suppression. The mixed electronic‐ionic conducting interphase, which in situ forms by introducing a Ti‐doping Li 56 La 24 Zr 15 TiO 96 (T‐LLZO) interlayer between Li and LLZO, is suggested based on the proposed mechanisms, which effectively facilitates to alleviate the overpotential thus suppress the lithium dendrites theoretically. This strategy is verified experimentally by obviously improved stability of Li/Li symmetric cell using T‐LLZO ceramic pellet electrolyte.