Silsesquioxanes are widely used inorganic–organic
hybrid
materials because of their high thermal and chemical stability and
diverse organic functions. Self-healing of cracks formed in polymeric
siloxane networks of silsesquioxanes is crucial for many applications.
In this study, we report the design of self-healing silsesquioxane
[(O3/2Si–R–SiO3/2)n] thin films by the self-assembly process. Lamellar-structured
thin films were prepared by hydrolysis and polycondensation of bis-alkoxysilane
precursors [(EtO)3Si–R–Si(OEt)3, where R = C2H4, C2H2, or C6H4] in the presence of a surfactant,
followed by spin-coating on substrates. These films exhibit spontaneous
and rapid healing of micrometer-scale cracks even under mild conditions
(at room temperature and 50–60% relative humidity). Compared
with the conventional silica-based lamellar thin films prepared using
tetraethoxysilane and the surfactant, a significant enhancement of
the crack-healing ability is evident. This can be attributed to the
higher flexibility of the silsesquioxane networks and the higher swelling
ratio of the lamellar silsesquioxane with moisture. Furthermore, the
film hardness and adhesion to the substrate were greatly improved
by adding a bis-alkoxysilane precursor with a long bridging organic
group for interlamellar cross-linking. These results will lead to
the development of self-healing silsesquioxane materials for practical
applications.