Dynamic viscoelastic behavior and interlaminar performance of glass/epoxy composites with binary nano-fillers at different in-situ elevated temperature environments

For commercial civil applications of laminated composite material, characterizations to forecast the interlaminar shear behavior and viscoelastic response across a wide temperature range are essential. In this study, the interlaminar shear strength (ILSS) of glass/epoxy (GE) composites dispersed with binary nanofillers nanosilica-multilayer graphene (NS-MLG) and nanosilica-nanoclay (NS-NC) was analyzed at an in-situ testing temperature of 20, 70, and 110?. Further, the viscoelastic property of the composites was studied using a dynamic mechanical thermal analyzer (DMTA) in the temperature range of 35-165?. An increase in the ILSS value of around 9% and 10% was observed at room temperature for GE/MLG-NS and GE/NC-NS, respectively, compared to control GE composites. In contrast, the trend was seen to change at higher temperatures. There was a slight decrement in the storage modulus (E') of GE/MLG-NS and GE/NC-NS composites in the glassy region compared to control GE composites. The mean T-g of the GE composite (control) was nearly 107.3? when the E' decline onset temperature was taken into account, but after the addition of MLG-NS, it was 10.1? below. The mean T-g of GE/NC-NS was determined to be 106.3?, and in the glass transition as well as rubbery regions, it was observed to compete with the E' value of the control GE composites. Fractography was done using micrographs obtained from environmental scanning electron microscope (ESEM). Traces of polymeric material found at the fiber surface certified the improved interfacial adhesion between glass fiber and polymer in the matrix-modified composite samples.