Synthesis, structures and properties of hydrophobic Alkyltrimethoxysilane-Polyvinyltrimethoxysilane hybrid aerogels with different alkyl chain lengths

[Display omitted] •Polyvinyltrimethoxysilane (PVTMS) could effectively suppress the cyclization reaction of alkyltrimethoxysilane (ATMS).•ATMS with different alkyl chain lengths and loadings were gelled with the help of PVTMS.•The effects of ATMS alkyl chain length and content on the properties of aerogels were investigated. Alkyltrimethoxysilane (ATMS) is among most widely used silane coupling agents. These commercially available, reasonably priced chemicals are often utilized to improve the compatibility of inorganic surfaces with organic coatings. With three hydrolysable moieties, ATMS is an outstanding candidate for solving the hydrophilicity, moisture sensitivity and high cost of silica aerogels. However, ATMS has a non-hydrolysable alkyl chain that undergoes cyclization reactions. The alkyl chain prevents ATMS from being incorporated in aerogel structures. Polyvinyltrimethoxysilane (PVTMS) is a silica precursor that offers two types of crosslinking to the final aerogel product. This strong doubly-crosslinked network can potentially suppress the cyclization reactions of ATMS and include it in aerogel structure. PVTMS was used with ATMS having different alkyl lengths (3–16 carbons) and loadings (25 or 50 wt%) as the silica precursors. Acid and base catalysts were used to perform hydrolysis and condensation reactions on the mixture and ATMS:PVTMS aerogels were obtained via supercritical drying. The incorporation of ATMS in the aerogels was approved by different characterization methods. Results showed that ATMS:PVTMS aerogels possess hydrophobicity (θ ∼ 130°), moisture resistance, varying surface area (44–916 m2·g−1), meso/microporous structure and thermal insulation properties (λ ∼ 0.03 W·m-1K−1). These samples also showed excellent performance in oil and organic solvent adsorption.