Abstract
The reinforcement of polymer nanocomposites can be achieved through alignment or percolation of cellulose nanocrystals (CNCs). Here, we compare the efficacy of these reinforcement mechanisms in thermoplastic polyurethane (PU) elastomer nanocomposites containing thermally stable cotton CNCs. CNC alignment was achieved by melt spinning nanocomposite fibers, while a percolating CNC network was generated by solvent casting nanocomposite films with CNC contents up to 20 wt %. While in films both the CNCs and the PU matrix were entirely isotropic at all concentrations as confirmed by wide-angle X-ray scattering and birefringence analysis, the CNCs in the fibers exhibited a preferential orientation, which improved with increasing CNC concentration. Increasing the CNC concentration in the fibers reduces, however, the alignment of the PU chains, resulting in an entirely isotropic PU matrix at high CNC contents. The mechanical properties of films and fibers were evaluated using stress-strain measurements. Nanocomposite fibers with low CNC content exhibited superior stiffness, extensibility, and strength compared to the films, while the films displayed superior mechanical properties at high CNC concentrations. These findings are rationalized using common semiempirical models describing the reinforcing effects of CNC alignment in fibers (Halpin-Tsai) and CNC percolation in films (percolation model). The formation of a percolating CNC network leads to a stronger reinforcement than CNC alignment, as the reinforcing effect of the latter is limited by the comparably low aspect ratio of CNCs extracted from cotton. As a consequence, above the percolation threshold for cotton CNCs, isotropic nanocomposite PU films show a higher stiffness than aligned nanocomposite PU fibers.
Highlights
In the development of nanocomposites with improved materials properties, the use of biopolymers presents an environmentally friendly opportunity to replace or decrease the use of conventional petrochemical-based polymers
We show that nanocomposite fibers are stiffer, more extensible, and stronger than films only at low cellulose nanocrystals (CNCs) concentrations, while the mechanical properties of nanocomposite films are superior at high CNC concentrations
Nanocomposites with CNC concentrations of up to 20 wt % was demonstrated for the first time
Summary
In the development of nanocomposites with improved materials properties, the use of biopolymers presents an environmentally friendly opportunity to replace or decrease the use of conventional petrochemical-based polymers. The most abundant biopolymer on earth, cellulose, has attracted much attention in this context. Cellulose is a semicrystalline polymer that can be processed into various products, including paper and viscose.[1] It can be isolated in various nanoforms having distinct aspect ratios and crystallinities, such as cellulose nanofibers (CNFs),[2,3] microcrystalline cellulose (MCC),[4] and cellulose nanocrystals (CNCs).[5] CNCs have attracted attention in the field of reinforced polymers due to their extraordinary mechanical properties. CNCs possess a high stiffness ranging from 56 to 220 GPa along the longitudinal axis of their rodlike shape and 10 to 50 GPa in the transverse direction.[6−8]
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