Fracture toughness, ionic conductivity, and low-temperature phase stability of tetragonal zirconia codoped with yttria and niobium oxide

Abstract

Tetragonal zirconia (t-ZrO2) solid solutions were prepared with additions of up to 1.5 mol% of niobium oxide (Nb2O5) into 3-mol%-yttria-stabilized t-ZrO2 (3Y-TZP), The influence of pentavalent cation doping on fracture toughness, ionic conductivity, and the tetragonal-to-monoclinic phase transformation in the temperature range of 120 degrees-210 degrees C was investigated. Fracture toughness and ionic conductivity increased and decreased, respectively, as the Nb2O5 content increased, which indicated that the annihilation of oxygen vacancies in 3Y-TZP was responsible for the instability of the t-ZrO2 lattice. The activation enthalpy related to the conductivity was similar to 83 kJ/mol, regardless of the dopant content, which was consistent with that for the low-temperature degradation of 3Y-TZP doped with Nb2O5. Degradation under an applied electric field occurred only on the specimen surface that was in contact with the anode, which suggests that depletion of the oxygen vacancies led to the degradation. The identical activation enthalpies and the involvement of the vacancy migration in both processes fortified the belief that the low-temperature degradation of yttria-stabilized t-ZrO2 is attributed to oxygen vacancy diffusion.