Probing the Sol-Gel Transition in SiO2 Hydrogels—A New Application of Near-Infrared Fluorescence

Picosecond time-resolved fluorescence spectroscopy has enabled us to use a near-infrared fluorescent dye to probe the sol-gel transition in SiO2 hydrogels, polymerized from sulfuric acid and sodium silicate solution, for the first time. We compare the microviscosity surrounding the probe during the sol-to-gel transition as predicted by two alternative models which both describe the decay of fluorescence anisotropy well. The results for one rotational time and a residual anisotropy imply that macrogelation of the sol leads to relatively small changes in the mobility of the fluorophore caused by small changes in microviscosity, but after much longer times, e.g., ≈ 1500 min, the mobility of the fluorophore decreases, reflecting a rapid increase in microviscosity of over several orders in magnitude. In sharp contrast, analysis of the anisotropy in terms of two rotational times predicts little change in microviscosity over the whole polymerization process.