Abstract
Isotactic polypropylene filled with 1 wt.% multi-walled carbon nanotubes (iPP/MWCNTs) were prepared, and their crystallization behavior induced by pressurizing to 2.0 GPa with adjustable rates from 2.5 to 1.3 × 104 MPa/s was studied. The obtained samples were characterized by combining wide angle X-ray diffraction, small angle X-ray scattering, differential scanning calorimetry, transmission electron microscopy and atomic force microscopy techniques. It was found that pressurization is a simple way to prepare iPP/MWCNTs composites in mesophase, γ-phase, or their blends. Two threshold pressurization rates marked as R1 and R2 were identified, while R1 corresponds to the onset of mesomorphic iPP formation. When the pressurization rate is lower than R1 only γ-phase generates, with its increasing mesophase begins to generate and coexist with γ-phase, and if it exceeds R2 only mesophase can generate. When iPP/MWCNTs crystallized in γ-phase, compared with the neat iPP, the existence of MWCNTs can promote the nucleation of γ-phase, leading to the formation of γ-crystal with thicker lamellae. If iPP/MWCNTs solidified in mesophase, MWCNTs can decrease the growth rate of the nodular structure, leading to the formation of mesophase with smaller nodular domains (about 9.4 nm). Mechanical tests reveal that, γ-iPP/MWCNTs composites prepared by slow pressurization display high Young’s modulus, high yield strength and high elongation at break, and meso-iPP/MWCNTs samples have excellent deformability because of the existence of nodular morphology. In this sense, the pressurization method is proved to be an efficient approach to regulate the crystalline structure and the properties of iPP/MWCNTs composites.
Highlights
The reinforcement of polymers with nano-scaled fillers have attracted great attention for the past ten years, and it has been widely accepted that this reinforcement can improve mechanical, and other properties, including changes in polymer crystallization behavior [1,2,3,4]
We studied the influence of crystalline structure and multi-walled carbon nanotubes (MWCNTs) on mechanical properties of the prepared composites
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Summary
The reinforcement of polymers with nano-scaled fillers have attracted great attention for the past ten years, and it has been widely accepted that this reinforcement can improve mechanical, and other properties, including changes in polymer crystallization behavior [1,2,3,4]. Our recent work indicated the crystal structure and morphology of iPP can be accurately controlled by adjusting pressurization conditions [21], and firstly proved high pressure-annealing can induce meso-γ transformation [22]. These results above have confirmed that pressurization is a novel method to tailor the crystalline structure of iPP. In this study, employing a home-made pressure device, we prepared iPP/multi-walled carbon nanotubes (MWCNTs) composites in mesophase, γ-phase and their blends through adjusting the pressurization rate in a broad range, and for the first time investigated the composites crystallization behavior during that pressurization. We studied the influence of crystalline structure and MWCNTs on mechanical properties of the prepared composites
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