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Thermal degradation of poly(lactic acid)–zeolite composites produced by melt-blending

Various zeolites (4A, Y, 13X) and related fillers (molecular sieves and coal fly ash) were used to prepare PLA composites and to assess their degrading effect on the polyester matrix under different processing conditions, at various zeolite/filler loadings. In this objective, untreated fillers, as w...

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Published in:Polymer bulletin (Berlin, Germany) Germany), 2020-04, Vol.77 (4), p.2111-2137
Main Authors: Pires, Marçal, Murariu, Marius, Cardoso, Ariela M., Bonnaud, Leila, Dubois, Philippe
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description Various zeolites (4A, Y, 13X) and related fillers (molecular sieves and coal fly ash) were used to prepare PLA composites and to assess their degrading effect on the polyester matrix under different processing conditions, at various zeolite/filler loadings. In this objective, untreated fillers, as well as washed and thermally activated zeolites, were used. PLA–zeolite composites were produced by melt-blending step followed by the evaluation of rheological information and molecular and thermal characteristics. The degradation of PLA during the preparation and processing of PLA–zeolite composites, or due to the presence of fillers, was evidenced by specific analyses (SEC, DSC, TGA, TG-FTIR). PLA degradation was mainly dependent on the nature of zeolite, filler loading, and thermal and processing history. The results of the study suggest that a stronger degradation effect is obtained by the addition of zeolite 4A into PLA (at loading of 5–10%) with respect to other zeolites (e.g., 13X and Y). It was also revealed the key roles of the temperature and residence time (as parameters in melt-mixing process), free alkalinity level, and water uptake in determining the ultimate characteristics of composites. The washing and thermal activation pretreatments of fillers have diminished in some cases the degradation of PLA matrix. Finally, the study also highlights the zeolite grades capable of being used to produce new PLA composites with competitive properties and those that could be of interest to improve PLA recycling by pyrolysis.
doi_str_mv 10.1007/s00289-019-02846-4
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source Springer Nature
subjects Acids
Alkalinity
Aluminum
Biopolymers
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Complex Fluids and Microfluidics
Composite materials
Decomposition
Fillers
Fly ash
Mechanical properties
Melt blending
Molecular sieves
Organic Chemistry
Original Paper
Physical Chemistry
Polylactic acid
Polymer Sciences
Polymers
Pore size
Pyrolysis
Rheological properties
Soft and Granular Matter
Solvents
Temperature
Thermal degradation
Zeolites
title Thermal degradation of poly(lactic acid)–zeolite composites produced by melt-blending
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