Peculiar crystallization kinetics of biodegradable poly blends

Binary blends of poly(lactic acid) (PLA) and polypropylene carbonate) (PPC) were found to display a peculiar crystallization kinetics. The two biodegradable polymers were blended by melt mixing, to obtain binary blends at various compositions. Temperature-modulated calorimetry and dynamic-mechanical...

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Veröffentlicht in:	Polymer engineering and science 2015-12, p.2698
Hauptverfasser:	Di Lorenzo, Maria Laura, Ovyn, Roxanne, Malinconico, Mario, Rubino, Paolo, Grohens, Yves
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Sprache:	eng
Schlagworte:	Analysis Crystallization Polymers Properties
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creator	Di Lorenzo, Maria Laura Ovyn, Roxanne Malinconico, Mario Rubino, Paolo Grohens, Yves
description	Binary blends of poly(lactic acid) (PLA) and polypropylene carbonate) (PPC) were found to display a peculiar crystallization kinetics. The two biodegradable polymers were blended by melt mixing, to obtain binary blends at various compositions. Temperature-modulated calorimetry and dynamic-mechanical analysis indicated that the blend components are partially miscible, and display two separate glass transitions, at temperatures intermediate to those of the plain polymers. Electron microscopy analysis disclosed the morphology of PLA/PPC blends, made of PPC-rich particles finely dispersed within the PLA-rich matrix. The possible establishment of interactions between the functional groups of the two polymers upon melt mixing has been hypothesized as the reason for partial miscibility and compatibility of the two biodegradable polymers. The PLA/PPC blends display good mechanical properties, with enhanced performance at rupture compared with plain PLA. Most importantly, the addition of PPC affects also the crystallization kinetics of PLA, since the more mobile PPC chains favor diffusion of the stiffer PLA chain segments towards the growing crystals, which fastens the spherulite growth rate of PLA. Such positive influence of an amorphous polymer on crystal growth rate has been demonstrated here for the first time in blends that display phase-separation in the melt.
doi_str_mv	10.1002/pen.24058
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The two biodegradable polymers were blended by melt mixing, to obtain binary blends at various compositions. Temperature-modulated calorimetry and dynamic-mechanical analysis indicated that the blend components are partially miscible, and display two separate glass transitions, at temperatures intermediate to those of the plain polymers. Electron microscopy analysis disclosed the morphology of PLA/PPC blends, made of PPC-rich particles finely dispersed within the PLA-rich matrix. The possible establishment of interactions between the functional groups of the two polymers upon melt mixing has been hypothesized as the reason for partial miscibility and compatibility of the two biodegradable polymers. The PLA/PPC blends display good mechanical properties, with enhanced performance at rupture compared with plain PLA. Most importantly, the addition of PPC affects also the crystallization kinetics of PLA, since the more mobile PPC chains favor diffusion of the stiffer PLA chain segments towards the growing crystals, which fastens the spherulite growth rate of PLA. 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title	Peculiar crystallization kinetics of biodegradable poly blends
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