Morphological investigation of ternary and semicrystalline organic inorganic hybrid nanocomposite

Organic-inorganic (O-I) hybrid nanocomposites have already been widely investigated in the optoelectronic industry and are emerging in the biomedical field. In both cases, a thorough knowledge of the O-I hybrid morphology is key for reaching tailored properties of the devices; however, up to now little is known on this matter. Herein, we used advanced X-ray scattering and microscopy techniques to investigate in detail the morphology and nanostructure of a biocompatible, ternary, and semicrystalline O-I hybrid nanocomposite made up of poly(epsilon-caprolactone) (PCL) and poly(ethylene glycol) (PEG), cross-linked by in situ-generated silsesquioxane structures (SS). Results showed that phase separation occurred at all length scales. At the microscale, irreversible PCL /PEG phase separation generated a globular morphology, where PEG-rich spherical domains were uniformly distributed within a PCL-rich matrix. At the nanoscale, partial organic/inorganic phase segregation resulted in the formation of polysilsesquioxane nanoparticles in both matrix and domains. Finally, an unusual crystalline behaviour was observed for the ternary O-I hybrid nanocomposite, PCL-PEG/SS, where PCL crystallization was anticipated and PEG crystallization was delayed in comparison with the binary PCL /SS and PEG /SS O-I hybrids as well as to a blend of the uncross-linked PCL and PEG precursors. These results provide new insights on how the competing processes of phase separation, crystallization, and inorganic cross-linking affect the overall morphology and nanostructure of O-I hybrid nanocomposites and, therefore, might be useful for establishing relevant structure-property relationships. [GRAPHICS] . (AU)