Elucidating the Role of Interfacial Hydrogen Bonds on Glass Transition Temperature Change in a Poly(Vinyl Alcohol)/SiO2 Polymer-Nanocomposite by Noncovalent Interaction Characterization and Atomistic Molecular Dynamics Simulations

Abstract

A thorough experimental investigation of polymer-glass transition temperature (T_g ) is performed on poly(vinyl alcohol) (PVA) and fumed silica nanoparticle (SiNP) composite. This is done together with atomistic molecular dynamics simulations of PVA systems in contact with bare and fully hydroxylated silica. Experimentally, PVA-SiNP composites are prepared by simple solution casting from aqueous solutions followed by its characterization using Fourier-transform infrared spectroscopy (FTIR), dynamic mechanical analysis (DMA), and dynamic scanning calorimetry (DSC). Both theoretical and experimentally deduced T_g are correlated with the presence of hydrogen bonding interactions involving OH functionality present on the surface of SiNP and along PVA polymer backbone. Further deconvolution of FTIR data show that inter-molecular hydrogen bonding present between PVA and SiNP surface is directly responsible for the increase in T_g . SiNP filler and PVA matrix ratio is also optimized for a desired T_g increase. An optimal loading of SiNP exists, in order to yield the maximum T_g increase arising from the competition between hydrogen bonding and crowding effect of SiNP.

Keywords: glass transition temperature; hydrogen bonding; poly(vinyl alcohol)/SiO 2; polymer-nanocomposite; simulations.