Synergistic Effects of Graphite and Carbon Nanotube Hybrid Fillers on Key Properties of Epoxidized Natural Rubber Nanocomposites

Abstract

Abstract This study investigates the preparation and characterization of epoxidized natural rubber (ENR) nanocomposites using graphite (GP), carbon nanotubes (CNTs), and CNTs/GP hybrid fillers. The results demonstrate that both gum and filled ENR compounds exhibit a reversion curve due to the breaking of weak -O-O- linkages. Furthermore, increasing GP loadings in ENR-GP and ENR-CNTs/GP hybrid composites lead to elevated cure curves and torque differences, indicating higher crosslink density and stiffness of the vulcanizates. These changes are attributed to the increasing chemical interaction between polar functional groups in ENR molecules and nanofiller surfaces, as confirmed by FTIR analysis. The analysis demonstrates a decrease in OH and epoxide groups, along with an increase in ether linkages. Moreover, ENR-CNTs/GP hybrid composites exhibit even higher curing curves, torque differences, Payne effect, total bound rubber content, electrical conductivity, and dielectric constant due to finer filler dispersion and distribution. This results in the formation of interconnected infinite networks that rapidly reach the percolation threshold concentration. Additionally, the formation of CNTs-GP-CNT connections enhances mechanical strength, heat conduction, and the tunneling effect of electrons. These findings confirm the synergistic effects of graphite and carbon nanotube hybrid fillers on key properties in ENR-CNTs/GP hybrid nanocomposites, indicating their potential applications in various fields.