Morphology and water resistance of mixed silane films of bis[3-(triethoxysilyl) propyl]tetrasulfide and bis-[trimethoxysilylpropyl]amine

Abstract

Functional organosilanes are powerful interface-active agents that find applications as adhesion promoters as well as optical, dielectric and protective coatings. Bis-silanes are of particular interest because they are highly crosslinked leading to very robust films. In almost all applications, the water resistance of the films is a critical performance measure. Here we use neutron reflectivity to address the effect of bridging group on the hydrothermal response of bis-silane films prepared using bis[3-(triethoxysilyl) propyl]tetrasulfide and bis-[trimethoxysilylpropyl]amine. Neat and mixed films are examined as-prepared, after exposure to water vapor and then in the re-dried state. The bridging group is the key factor that controls the morphology and water resistance of silane films. Although bis-sulfur silane is not as condensed as bis-amino silane, bis-sulfur swells less in water because of the hydrophobic nature of bridging group. The reflectivity of bis-sulfur silane film is reversible after room-temperature water conditioning but not at 80 °C, indicating chemical alternation of the film at 80 °C. The water resistance of mixed silane is roughly that of both components weighted by their volume fraction. But based on the enhanced shrinkage that occurs following water-vapor conditioning of the mixed film, condensation is accelerated in the mixed silane. Regarding the precursor solution, bis-amino silane may act as a catalyst in the hydrolysis of bis-sulfur silane leading to more silanols in the solution and further condensation in the film. Variation in the structure normal to the substrate is also examined by swelling the film with d-nitrobenzene, a non-reacting swelling agent.