Abstract
Carbon black (CB), carbon nanotubes (CNTs), and graphene nanoplatelets (GnPs) individually or doubly served as reinforcing fillers in polycarbonate (PC)/poly(vinylidene fluoride) (PVDF)-blend (designated CF)-based nanocomposites. Additionally, organo-montmorillonite (15A) was incorporated simultaneously with the individual carbon fillers to form hybrid filler nanocomposites. Microscopic images confirmed the selective localization of carbon fillers, mainly in the continuous PC phase, while 15A located in the PVDF domains. Differential scanning calorimetry results showed that blending PVDF with PC or forming single/double carbon filler composites resulted in lower PVDF crystallization temperature during cooling. However, PVDF crystallization was promoted by the inclusion of 15A, and the growth of β-form crystals was induced. The rigidity of the CF blend increased after the formation of nanocomposites. Among the three individually added carbon fillers, GnPs improved the CF moduli the most; the simultaneous loading of CNT/GnP resulted in the highest moduli by up to 33%/46% increases in tensile/flexural moduli, respectively, compared with those of the CF blend. Rheological viscosity results showed that adding CNTs increased the complex viscosity of the blend to a greater extent than did adding CB or GnPs, and the viscosity further increased after adding 15A. The electrical resistivity of the blend decreased with the inclusion of carbon fillers, particularly with CNT loading.
Highlights
Polymer blends and composites are fabricated to improve the specific properties of parent polymer components for broadening their applications
The miscibility, phase morphology, and type/dispersibility of added fillers are the key factors in controlling the final properties of polymer blends and composites
It is recognized that a fine dispersion of nanofiller(s) throughout the polymer matrix and a strong attractive force between nanofiller(s) and a polymer are the two keys to successfully achieving polymer nanocomposites
Summary
Polymer blends and composites are fabricated to improve the specific properties of parent polymer components for broadening their applications. The miscibility, phase morphology, and type/dispersibility of added fillers are the key factors in controlling the final properties of polymer blends and composites. Research of different nanofiller(s) polymer nanocomposites continues to be updated [3,4,5,6]. Organically modified montmorillonite (O-MMT, nanoclay) is one of the suitable choices for fabricating high-performance polymer nanocomposites. In addition to O-MMT, carbon nanomaterials with superior properties have been utilized to manufacture polymer nanocomposites with enhanced properties. Carbon nanotubes (CNTs) and graphene nanoplatelets (GnPs) have demonstrated their potential to produce polymer nanocomposites possessing high rigidity and improved thermal/electrical conductivity [8,9,10,11]. It is recognized that a fine dispersion of nanofiller(s) throughout the polymer matrix and a strong attractive force between nanofiller(s) and a polymer are the two keys to successfully achieving polymer nanocomposites
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