Hydrothermal degradation of a 3Y-TZP translucent dental ceramic: A comparison of numerical predictions with experimental data after 2 years of aging

Objectives. The purpose of the study was to assess the hydrothermal resistance of a translucent zirconia with two clinical relevant surface textures by means of accelerated tests (LTD) and to compare predicted monoclinic fractions with experimental values measured after two years aging at 37 degrees C. Methods. Polished (P) and ground (G) specimens were subjected to hydrothermal degradation by exposure to water steam at different temperatures and pressures. The t-m phase transformation was quantified by grazing incidence X-ray diffraction (GIXDR). The elastic modulus and hardness before- and after LTD were determined by nanoindentation. Results. G specimens presented a better resistance to hydrothermal degradation than P samples. Activation energies of 89 and 98 kJ/mol and b coefficients of 2.0 x 10(-5) and 1.8 x 10(-6) were calculated for P and G samples respectively. The coefficients were subsequently used to predict transformed monoclinic fractions at 37 degrees C. A good correlation was found between the predicted values and the experimental data obtained after aging at 37 degrees C during 2 years. Hydrothermal degradation led to a significant decrease of the elastic moduli and hardness in both groups. Significance. The dependency of the t-m phase transformation rate on temperature must be determined to accurately predict the hydrothermal behavior of the zirconia ceramics at oral temperatures. The current prevailing assumption, that 5 h aging at 134 degrees C corresponds to 15-20 years at 37 degrees C, will underestimate the transformed fraction of the translucent ceramic at 37 degrees C. In this case, the mechanical surface treatment influences the ceramic's transformability. While mild grinding could potentially retard the hydrothermal transformation, polishing after occlusal adjustment is recommended to prevent wear of the antagonist teeth and maintain structural strength. (C) 2015 Academy of Dental Materials. Published by Elsevier Ltd. All rights reserved.