Effect of surface treatment and nanoclay on thermal and mechanical performances of jute fabric/biopol ‘green’ composites

Abstract

The effects of surface modification of jute fibers and nanoclay on jute–biopol green composites are evaluated by the thermal and interlaminar shear strength (ILSS) characterizations. Four subsequent chemical treatments including detergent washing, dewaxing, alkali treatment, and acetic acid treatment were performed to facilitate better bonding between the fiber and matrix. The scanning electron microscopy and Fourier transform infrared spectroscopy study confirmed improved fiber surfaces for better adhesion with matrix after final treatment. Enhanced thermal performance and tensile properties were obtained due to chemical treatments. Montmorillonite K10 nanoclay (2–4 wt.%) was dispersed into a biodegradable polymer, biopol, using solution intercalation technique and magnetic stirring. Nanoclay-infused biopol resulted in 7% improvement in the degree of crystallinity over the neat biopol. Jute fiber-reinforced biopol biocomposites with and without nanoclay were produced using treated and untreated jute fibers by the compression molding process. Treated jute fiber-reinforced biopol composites (TJBC) without nanoclay showed 5% and 9% increases in decomposition temperature and storage modulus, respectively, and 19% decrease in coefficient of thermal expansion compared to untreated jute fiber-reinforced biopol composites (UTJBC). The respective values were 5%, 100%, and 45% for 4% nanoclay-infused TJBC compared to UTJBC without nanoclay. ILSS evaluated by the short-beam shear tests, improved by 20% in the TJBC compared to the UTJBC. Incorporation of 4 wt.% nanoclay in TJBC further improved the ILSS by 22% compared to that of TJBC without nanoclay.