Impact of Multiple Reprocessing on Properties of Polyhydroxybutyrate and Polypropylene

Main, Priyanka; Petersmann, Sandra; Wild, Nadine; Feuchter, Michael; Duretek, Ivica; Edeleva, Mariya; Ragaert, Peter; Cardon, Ludwig; Lucyshyn, Thomas

doi:10.3390/polym15204126

Cited by 6 publications

(1 citation statement)

References 72 publications

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“…Although many publications promise to discuss the degradation of biopolymers, most of them stick to generalities such as hydrolysis, chain shortening, radical formation, transesterification, etc., and focus only on the effect of different process parameters on some inline and offline properties of the product, such as compressibility, rheology, color, etc. [158][159][160][161]. Near-IR spectroscopy is an appropriate tool for monitoring most degradation processes associated with water, hydrolysis, or transesterification.…”

Section: Extrusionmentioning

confidence: 99%

Mechanochemical Degradation of Biopolymers

Jicsinszky,

Bucciol,

Chaji

et al. 2023

Molecules

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Mechanochemical treatment of various organic molecules is an emerging technology of green processes in biofuel, fine chemicals, or food production. Many biopolymers are involved in isolating, derivating, or modifying molecules of natural origin. Mechanochemistry provides a powerful tool to achieve these goals, but the unintentional modification of biopolymers by mechanochemical manipulation is not always obvious or even detectable. Although modeling molecular changes caused by mechanical stresses in cavitation and grinding processes is feasible in small model compounds, simulation of extrusion processes primarily relies on phenomenological approaches that allow only tool- and material-specific conclusions. The development of analytical and computational techniques allows for the inline and real-time control of parameters in various mechanochemical processes. Using artificial intelligence to analyze process parameters and product characteristics can significantly improve production optimization. We aim to review the processes and consequences of possible chemical, physicochemical, and structural changes.

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Section: Extrusionmentioning

confidence: 99%

Mechanochemical Degradation of Biopolymers

Jicsinszky,

Bucciol,

Chaji

et al. 2023

Molecules

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Effect of Epoxy Chain Extender and Multiple Processing on Poly-(R)-3-Hydroxybutyrate’s Properties

Hinterberger,

Main,

Waly

et al. 2024

J Polym Environ

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The semi-crystalline poly-(R)-3-hydroxybutyrate (PHB) is a biobased and biodegradable polymer. This makes it a promising alternative to polypropylene (PP), especially for packaging applications. PHB has excellent barrier properties to O2, CO2, and H2O, but is susceptible to degradation from heat and hydrolysis. The epoxy chain extender Joncryl® was added to PHB in a simulated recycling process to reverse the degradation due to processing. The effects of the chain extender and the degradation due to processing were investigated with thermal gravimetric analysis (TGA), differential scanning calorimetry (DSC), small strain oscillatory plate-plate rheometry, tensile tests, and notched Charpy impact tests. With the addition of the chain extender, a decrease in peak crystallization temperature and tensile modulus, and an increase in zero-shear viscosity and elongation at break were observed. For each additional processing step the zero-shear viscosity, the elongation at break, and the notched impact strength decreased, while the tensile modulus increased. The effect of the thermal load during processing on the material properties is significantly higher compared to the effect of the addition of the chain extender. Therefore, the practical application of the investigated chain extender alone in a multi-stage recycling process seems limited. This is due to the low processing temperature of PHB, which seems to limit the full potential of Joncryl® due to the slow reaction speed at this temperature.

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