Structural, rheological, and mechanical properties of polyvinyl alcohol composites reinforced with cellulose nanofiber treated by ultrahigh-pressure homogenizer

Cellulose nanofibers (CNF) were prepared by nanoisolation using a newly developed ultrahigh-pressure ho-mogenizer (UHPH). The CNF was treated by UHPH with 0, 10, and 20 passes. The effect of UHPH on defibril-lation of the CNF and its structure was investigated. The UHPH-treated CNF reinforced poly(vinyl alcohol) (PVA) composite was fabricated by solvent casting. The effect of CNF on morphology, high-order structure, rheological property, and mechanical performance of PVA/CNF composites was investigated. Structural analyses revealed that fiber diameters and fiber distributions of the CNF decreased, and the relative crystallinity increased with an increase in the UHPH passes. The mechanical treatment by UHPH promoted CNF fiber dissociation without interfering with the CNF crystal structure. High crystallinity and interaction of the hydrogen bonding of the defibrillated, treated CNF significantly enhanced the mechanical performance of the PVA/CNF composites. The UHPH treatment presented defibrillated CNF with high crystallinity, which was developed for the high-potential cellulose nanofiber in fiber-reinforced composite materials.

Automated summary

Cellulose nanofibers (CNF) were prepared by nanoisolation using an ultrahigh-pressure homogenizer (UHPH). The effect of UHPH on CNF defibrillation and structure was investigated. A CNF-reinforced poly(vinyl alcohol) (PVA) composite was fabricated, and the influence of CNF on morphology, structure, rheology, and mechanical performance was studied. Results showed that UHPH treatment reduced fiber diameter and improved relative crystallinity. The defibrillated CNF with high crystallinity significantly enhanced the mechanical performance of the composite.