The pyrochlore Gd_1.55Li_0.45Zr₂O_6.55 was prepared by the solution and solid-state methods. The introduction of lithium in the Gd-sublattice led to decrease in the lattice parameter a = 10.4830(8) Å in comparison with Gd₂Zr₂O₇ (a =10.5346(2) Å). Monitoring of the lithium content in the sample during heat treatments showed a loss of lithium at temperatures above 1100 °C, so, to maintain the stoichiometry of lithium the low temperature sintering methods are required. The sample Gd_1.55Li_0.45Zr₂O_6.55 exhibited a predominant oxygen-ion transport over a wide range of temperatures.  Although doping did not lead to an increase in the oxygen-ion conductivity compared to Gd₂Zr₂O₇, it caused the suppression of the hole conductivity.

gadolinium zirconate Gd2Zr2O7, pyrochlore, Li+-doping, conductivity

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