Alumina nanoparticles were successfully functionalized with a bi-functional coupling agent, (3-methacryloxypropyl)trimethoxysilane (MPS), through a facile neutral solvent method. MPS was found to be covalently bound with the nanoparticles. The linked MPS was polymerized with a vinyl-ester resin monomer through a free radical polymerization. Atomic force microscope phase images showed a uniform distribution of nanoparticles. Microtensile test results revealed the Young's modulus and strength increasing with particle loading. Microscopic examinations revealed the presence of large plastic deformations at the micron scale in the nanocomposites in agreement with the observed strengthening effect of functionalized nanoparticles. Thermo-gravimetric analysis (TGA) did not show any significant change in the thermal degradation of the nanocomposite as compared with the neat resin. The polymer matrix effectively protected the alumina nanoparticles from dissolution in basic and acidic solutions.
Zinc oxide (ZnO) nanoparticles functionalized with a bi-functional coupling agent
methacryloxypropyl-trimethoxysilane (MPS) were used to fabricate a vinyl-ester resin polymeric
nanocomposite, which shows an improved interfacial interaction between the particle and matrix.
As a result, in comparison to the unmodified particle-filled nanocomposites, the functionalized
particle-filled composites possessed higher resistance to thermal degradation, and demonstrated
improved UV shielding and enhanced photoluminescent properties. The more uniform particle
dispersion, passivation of the particle surface with MPS and increased oxygen vacancies were
justified to contribute to the increased thermal stability and the enhanced photoluminescent
properties. Significant tensile strength improvement was closely related to the observed uniform
particle distribution and the intimate interfacial interaction through the strong chemical bonding
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