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W2017236589 endingPage "8092" @default.
W2017236589 startingPage "8080" @default.
W2017236589 abstract "The crystallization of isotactic polypropylene (iPP) under the coexistence of shear flow and carbon nanotubes (CNTs) was investigated by means of in situ synchrotron X-ray scattering techniques, i.e. wide-angle X-ray diffraction (WAXD) and small-angle X-ray scattering (SAXS). Compared to sheared pure iPP, the combined effect of shear flow and CNTs endowed iPP crystals with weak degree of orientation at the early stage of crystallization but high degree of orientation in the later period. This was because the initial orientation of molecular chains induced by shear was suppressed as a result of the increased viscoelasticity of iPP melt in the presence of CNTs, but subsequently oriented molecular chains were stabilized by CNT surface absorption. The crystallization kinetics of sheared CNTs/iPP nanocomposites was synergistically promoted, where the crystallization rate was increased about 40 times in comparison to that of quiescently crystallized pure iPP. The Avrami exponent of CNTs/iPP nanocomposites and sheared iPP was around 2, indicating two-dimensional lamellar growth. The Avrami exponent of sheared CNTs/iPP nanocomposites surprisingly appeared to be 2.52, suggestive of mixed two-dimensional lamellar growth and three-dimensional sphrulitic growth geometries. Moreover, β-crystals were absent in sheared CNTs/iPP nanocomposites in contrast to the normal observation that α-row nuclei induced by shear generated β-crystals. The synergistic crystallization rate, the mixed crystal growth geometry as well as the absence of β-crystals in sheared CNTs/iPP nanocomposites were in close relation with intense interaction between shear flow and CNTs, which gave rise to extra nuclei in sheared CNTs/iPP melt. Apart from heterogeneous nucleating sites originated from CNTs and homogeneous nucleating sites (row-nuclei) initiated by shear, extra nuclei were taken into account to contribute to the further accelerated crystallization kinetics. The extra nuclei became active growth points of branching sites on the two-dimensional lamellae to generate three-dimensional spherulitic growth, thus leading to mixed crystal growth geometry of sheared CNTs/iPP nanocomposites. Besides, extra nuclei as well as α-nuclei derived from CNTs remarkably encouraged the formation of α-crystals, responsible for inexistence of β-crystals in sheared CNTs/iPP nanocomposites." @default.
W2017236589 created "2016-06-24" @default.
W2017236589 creator A5031207407 @default.
W2017236589 creator A5032343796 @default.
W2017236589 creator A5063059754 @default.
W2017236589 creator A5083286147 @default.
W2017236589 creator A5087443544 @default.
W2017236589 date "2011-09-16" @default.
W2017236589 modified "2023-09-30" @default.
W2017236589 title "In Situ Synchrotron X-ray Scattering Study on Isotactic Polypropylene Crystallization under the Coexistence of Shear Flow and Carbon Nanotubes" @default.
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W2017236589 doi "https://doi.org/10.1021/ma201688p" @default.
W2017236589 hasPublicationYear "2011" @default.