Effects of ZrOCl₂ Concentration and Reaction Temperature on the Formation Process of Hydrous-Zirconia Fine Particles

Abstract

The crystal phase, the primary particle size, and the formation rate of hydrous-zirconia fine particles produced by hydrolysis conditions of various ZrOCl₂ concentrations (0.05-0.4mol·dm^-3) and reaction temperatures (358-373K) were measured to clarify the effects of the ZrOCl₂ concentration and the reaction temperature on the formation process. Chemical analysis and X-ray diffraction measurements revealed that hydrous-zirconia particles synthesized from all of the hydrolysis conditions were similar to those observed in monoclinic crystalline ZrO₂, except that the crystal structure changed with increasing chlorine content at the preparation conditions of 0.4mol·dm^-3 and ≤363K. The primary particle size of monoclinic hydrous-zirconia particles decreased with increasing ZrOCl₂ concentration and was independent of the reaction temperature. The rate constants (k) of hydrous-zirconia particles were determined experimentally by applying Avrami-Erofeev's equation. The determined k-value decreased, as the ZrOCl₂ concentration increased and the reaction temperature decreased. From Arrhenius plots of k, the activation energies for hydrous-zirconia particles in the monoclinic phase and containing high chlorine contents were determined to be 3.8×10²-4.0×10² and 2.5×10²kJ·mol^-1, respectively. The nucleation and the particle growth mechanisms of hydrous-zirconia particles were determined on the basis of the present experimental results.