Insights of PHB/QC Biocomposites: Thermal, Tensile and Morphological Properties

In the present work composites based on poly (hydroxybutyrate) (PHB) and quasi-crystals (Al 62.0 Cu 25.5 Fe 12.5 ) (QC), i.e., PHB/QC were processed aiming at biodegradable compounds with improved performance. According to the particle size evaluation and scanning electron microscopy images the adde...

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Veröffentlicht in:	Journal of polymers and the environment 2020-09, Vol.28 (9), p.2481-2489
Hauptverfasser:	Fernandes, M. R. P., França, T. S., Queiroz, I. X., Wanderley, W. F., Cavalcante, D. G. L., Passos, T. A., Melo, D. M. A., Wellen, R. M. R.
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Schlagworte:	Biocompatibility Biodegradability Biodegradation Biomedical materials Chemistry Chemistry and Materials Science Composite materials Crystals Elongation Environmental Chemistry Environmental Engineering/Biotechnology Hardness Hardness tests Industrial Chemistry/Chemical Engineering Materials Science Mechanical properties Modulus of elasticity Original Paper Polyhydroxybutyrate Polymer Sciences Scanning electron microscopy Thermal stability
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container_title	Journal of polymers and the environment
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creator	Fernandes, M. R. P. França, T. S. Queiroz, I. X. Wanderley, W. F. Cavalcante, D. G. L. Passos, T. A. Melo, D. M. A. Wellen, R. M. R.
description	In the present work composites based on poly (hydroxybutyrate) (PHB) and quasi-crystals (Al 62.0 Cu 25.5 Fe 12.5 ) (QC), i.e., PHB/QC were processed aiming at biodegradable compounds with improved performance. According to the particle size evaluation and scanning electron microscopy images the added QC phase presented particle diameters with approximately 5 µm which conducted to homogeneously dispersed higher composites hardness, as evidenced through Shore D Hardness testing and SEM images. QC improved PHB melting and delayed decomposition without losses on the thermal stability. The elastic modulus increased upon QC addition whereas subtle decrease was verified in the elongation at break mechanisms. Summing up, harder and thermal stable PHB/QC composites were produced which may be used for applications where biodegradable and biocompatible characters are requested.
doi_str_mv	10.1007/s10924-020-01785-w
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R. P. ; França, T. S. ; Queiroz, I. X. ; Wanderley, W. F. ; Cavalcante, D. G. L. ; Passos, T. A. ; Melo, D. M. A. ; Wellen, R. M. R.</creator><creatorcontrib>Fernandes, M. R. P. ; França, T. S. ; Queiroz, I. X. ; Wanderley, W. F. ; Cavalcante, D. G. L. ; Passos, T. A. ; Melo, D. M. A. ; Wellen, R. M. R.</creatorcontrib><description>In the present work composites based on poly (hydroxybutyrate) (PHB) and quasi-crystals (Al 62.0 Cu 25.5 Fe 12.5 ) (QC), i.e., PHB/QC were processed aiming at biodegradable compounds with improved performance. According to the particle size evaluation and scanning electron microscopy images the added QC phase presented particle diameters with approximately 5 µm which conducted to homogeneously dispersed higher composites hardness, as evidenced through Shore D Hardness testing and SEM images. QC improved PHB melting and delayed decomposition without losses on the thermal stability. The elastic modulus increased upon QC addition whereas subtle decrease was verified in the elongation at break mechanisms. 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subjects	Biocompatibility Biodegradability Biodegradation Biomedical materials Chemistry Chemistry and Materials Science Composite materials Crystals Elongation Environmental Chemistry Environmental Engineering/Biotechnology Hardness Hardness tests Industrial Chemistry/Chemical Engineering Materials Science Mechanical properties Modulus of elasticity Original Paper Polyhydroxybutyrate Polymer Sciences Scanning electron microscopy Thermal stability
title	Insights of PHB/QC Biocomposites: Thermal, Tensile and Morphological Properties
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