Multiscale structural characterization of methyltriethoxysilane-based silica aerogels.

A series of methyltriethoxysilane-based silica aerogel monoliths were prepared by ambient pressure drying with various volume ratios of water to ethanol ( R). The pore volumes and average pore sizes of silica aerogels were obtained by Barrett-Joyner-Halenda (BJH) method from nitrogen adsorption-desorption isotherms. The stress-strain curves of the cylindrical aerogel specimens were measured by performing uniaxial compressive tests. The particle size distributions and the average particle sizes of silica aerogels were also evaluated based on scanning electron microscopic observations. The experimental data revealed that the average particles size increased from 0.115 to 3.08 μm as R varied from 0.7 to 1.5, and that the silica aerogels exhibited two characteristic types of the compressive stress-strain responses. By proposing a multiscale structural model to describe microstructures of silica aerogels, a structural parameter, defined as the slenderness L/ D of the cube column length L and the average particle diameter D, was related to the specific volume and the BJH volume of the silica aerogel monoliths, as well as the specific volume of silica. Accordingly, the two types of the compressive stress-strain responses may be distinguished by the critical value ( L/ D). [ABSTRACT FROM AUTHOR]