Development and characterization of hybrid composites from sustainable green materials

The main objective of this study was to evaluate the dynamic mechanical thermal analysis (DMTA), mechanical, physical and wettability properties of hybrid composites developed from sustainable green materials, jute fiber and wood particles that were manufactured by using the vacuum-assisted resin transfer molding technique. The storage modulus, loss modulus and tan delta values of the hybrid composites were also determined to evaluate the DMTA performance. The results showed that the storage modulus of jute/polyester resin is superior to those of the jute-wood/polyester hybrid and wood/polyester up to the glass transition temperature (T-g). However, for temperature ranges higher than T-g, the stiffness of hybrid composites increased relatively. The T-g values from loss modulus and tan delta peaks support this effect of hybridization. Tests on mechanical properties showed that the jute/polyester specimens had a significant increase in tensile strength compared with the jute-wood/polyester hybrid and wood/polyester specimens. The results of tests of physical properties showed that the wood/polyester specimen had the lowest values of thickness swelling, water absorption and moisture content compared with the jute/polyester and jute-wood/polyester composites. The highest contact angle was obtained from composites made of wood/polyester. It could be concluded that the composites with enhanced performance could be used as novel green composites in various sectors.

Automated summary

The study evaluated the performance of sustainable green composites developed from jute fiber and wood particles. The hybrid composites showed superior mechanical and physical properties compared to traditional composites, making them suitable for various applications in different sectors.