Abstract
Both cellulose nanofiber (CNF) and carbon nanotube (CNT) are nanoscale fibers that have shown reinforcing effects in polymer composites. It’s worth noting that CNF and CNT could form a three-dimensional nano-network via mixing and vacuum filtration, which exhibit excellent mechanical strength and electrical conductivity. In this study, the developed CNF/CNT film was applied as a nano-network template and immersed into polydimethylsiloxane (PDMS) solutions. By controlling the immersed polydimethylsiloxane pre-polymer concentration, the PDMS/CNF/CNT nanocomposite with various PDMS contents were fabricated after a curing process. Morphological images showed that the CNF/CNT nano-network was well-preserved inside the PDMS, which resulted in significantly improved mechanical strength. While increasing the PDMS content (~71.3 wt %) gave rise to decreased tensile strength, the PDMS-30/CNF/CNT showed a fracture strain of 7.5%, which was around seven fold higher than the rigid CNF/CNT and still kept a desirable strength—Young’s modulus and conductivity of 18.3 MPa, 805 MPa, and 0.8 S/cm, respectively. Therefore, with the enhanced mechanical properties and the electrical conductivity, the prepared PDMS/CNF/CNT composite films may offer promising and broad prospects in the field of flexible devices.
Highlights
The rapid development of flexible electronic devices places a high demand for high-performance conductive base-materials
Morphological images showed that the cellulose nanofiber (CNF)/carbon nanotube (CNT) nano-network was well-preserved inside the PDMS, which resulted in significantly improved mechanical strength
To improve the flexibility of the conductive film, the PDMS elastomer was introduced into the film, where the CNF/CNT served as a conductive network template
Summary
The rapid development of flexible electronic devices places a high demand for high-performance conductive base-materials. PDMS has attracted considerable attention as a soft component polymer to be utilized as base-materials for flexible devices [4,5,6,7,8]. In such flexible base-materials, micro or nano-sized structures, composed of multi-reinforcing functions, e.g., high electrically conductive, or mechanical strength, are essential to further expand its applications [9,10,11,12]. By mixing CNF with a polymer solution, followed with polymerization, a CNF-based nanocomposite
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