Biodegradable Poly(butylene adipate-co-terephthalate) Nanocomposites Reinforced with In Situ Fibrillated Nanocelluloses

Abstract: The enhancement of mechanical properties is highly required for the expanded applications of biodegradable polymers like poly(butylene adipate-co-terephthalate) (PBAT). The use of nanocellulose as reinforcing fillers is one of the effective approaches while preserving the biodegradability of polymers, but the dispersion of nanofibers in polymer matrixes is a great challenge. Here, we report an in situ fibrillation method to prepare nanocellulose-reinforced PBAT composite films with superior mechanical properti… Show more

“…The micrographs of PBAT cryo-fracture show a typical brittle surface fracture of a ductile polymer in its glassy state, and it is not influenced by cross-linking ( Figure 3 a,b). Few micrometrical fibers in bundles are detected in both biocomposites ( Figure 3 c,d, at both magnifications) but the majority of cellulosic fibers appears fibrillated, 38 − 40 as a consequence of shear forces induced during melt processing and the beneficial wet-feeding approach, which prevents fibers agglomeration. The fracture surface of the P-PBAT biocomposite is characterized by numerous voids, which are correlated to the pull-out of the fibers ( Figure 3 c), indicating poor adhesion at the interface pulp/PBAT.…”

Reusable, Recyclable, and Biodegradable Heat-Shrinkable Melt Cross-Linked Poly(butylene adipate-co-terephthalate)/Pulp Biocomposites for Polyvinyl Chloride Replacement

“…The micrographs of PBAT cryo-fracture show a typical brittle surface fracture of a ductile polymer in its glassy state, and it is not influenced by cross-linking ( Figure 3 a,b). Few micrometrical fibers in bundles are detected in both biocomposites ( Figure 3 c,d, at both magnifications) but the majority of cellulosic fibers appears fibrillated, 38 − 40 as a consequence of shear forces induced during melt processing and the beneficial wet-feeding approach, which prevents fibers agglomeration. The fracture surface of the P-PBAT biocomposite is characterized by numerous voids, which are correlated to the pull-out of the fibers ( Figure 3 c), indicating poor adhesion at the interface pulp/PBAT.…”

Reusable, Recyclable, and Biodegradable Heat-Shrinkable Melt Cross-Linked Poly(butylene adipate-co-terephthalate)/Pulp Biocomposites for Polyvinyl Chloride Replacement

Insights into the enhanced mechanism of electron beam pretreatment on application performance for poly (butylene adipate-co-terephthalate)/acetylated cellulose composite plastics