In situ observations of particle size evolution during the hydrothermal crystallization of TiO2: A time-resolved synchrotron SAXS and WAXS study

Abstract

We have monitored the homogeneous crystallization of TiO2 phases from aqueous TiCl4 solutions at 100°C using both time-resolved small-angle X-ray scattering (TR-SAXS) and time-resolved wide-angle X-ray scattering (TR-WAXS). The WAXS data revealed that metastable anatase was the first phase to crystallize, but it began transforming to rutile within the first hour of reaction. Scherrer analysis of WAXS peak widths indicated that anatase particles grew to an average size near 7nm on a time scale of minutes, after which their size remained static, while rutile grew rapidly from <3nm to ∼10nm within 1h, followed by slower growth at a rate of ∼0.15nm/h.Using a novel sample cell designed to withstand temperatures up to 150°C and hydrothermal vapor pressure, we collected in situ SAXS data for the same conditions as the WAXS experiments. Fourier analyses of the SAXS images revealed the rapid emergence of a broad, Gaussian-type particle size distribution ranging in diameter from 1 to ∼20nm with a mean near 7nm, in excellent agreement with our WAXS analysis. At 0.5h, a second population of <3nm particles emerged, and these crystals grew to ∼9nm after 7.5h, which we interpret as the nucleation and growth of rutile (as was also observed in the WAXS patterns). In contrast to studies that presume a solid-state transformation from anatase to rutile during growth, our results suggest that anatase and rutile co-precipitate during the early stages of crystallization, but once anatase crystals grow to a critical size of 7nm, they dissolve and the solution species re-precipitate onto primary rutile nanocrystals.