Influence of dislocations on ionic conductivity and dendrite formation in solid electrolytes

In order to study the recently proposed strategy to tailor the electrical property of ceramics by the introduction of dislocations, numerical calculations are performed on the influence of parallel straight dislocations on ionic conductivity and dendrite formation in single-crystal solid electrolytes. If the diameter of a dislocation pipe is more than root 2 times larger than the distance between neighboring dislocations, the ionic current density is nearly uniform on the electrode and the dendrite formation would be avoided. Furthermore, under the condition, the mean ionic conductivity is higher than that without dislocations by several orders of magnitude. It may be practically possible to increase the ionic conductivity by several orders of magnitude without dendrite formation by introducing appropriate dislocations because the required dislocation density in the order of 10(17) m(-2) has already been reported experimentally although the reports were not for metal oxides.

Automated summary

Numerical calculations are performed to study the influence of parallel straight dislocations on ionic conductivity and dendrite formation in ceramics. The results show that if the diameter of a dislocation pipe is more than root 2 times larger than the distance between neighboring dislocations, the ionic current density is nearly uniform on the electrode and dendrite formation can be avoided. Moreover, under this condition, the mean ionic conductivity is significantly improved compared to without dislocations.