Chemical Recycling of Cellulose Acetate Eyewear Industry Waste by Hydrothermal Treatment

Bracciale, Maria Paola; de Caprariis, Benedetta; Musivand, Sogand; Damizia, Martina; De Filippis, Paolo

doi:10.1021/acs.iecr.3c04162

Cited by 4 publications

(1 citation statement)

References 35 publications

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“…As for other biopolymers, HT may be a valuable route to rapidly degrade bioplastics and facilitate their anaerobic digestion or synthesize added-value products. Nonetheless, to the best of our knowledge, the literature features only one study on the HT of bioplastics (in addition to a couple of recent studies focused on cellulose diacetate from the eyewear industry , ), and before applying the treatment to real waste bioplastics (or even to a mixture comprising other types of organic waste), the fundamentals of the degradation behavior and the qualities of the obtained products must be ascertained. In this framework, the aim of this work is to investigate the effect of a HT on three biodegradable commercial tableware products, based on polylactic acid (PLA), Mater-Bi (MB) and cellulose (CELL).…”

Section: Introductionmentioning

confidence: 99%

Fostering Bioplastics Circularity through Hydrothermal Treatments: Degradation Behavior and Products

Marchelli,

Mattonai,

Ferrentino

et al. 2024

ACS Sustainable Chem. Eng.

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Bioplastics are produced in growing amounts due to their environmental benefits, but their disposal routes remain ambiguous. A hydrothermal treatment (HT) may be a sustainable process to improve the fate of waste bioplastics, but nearly no information is available on how they respond to it. In this work, HT of biodegradable bioplastics was performed, and the resulting solid and liquid products were characterized by elemental analysis, analytical pyrolysis-based techniques, ion chromatography, and gas chromatography coupled with mass spectrometry. We selected tableware based on polylactic acid (PLA), cellulose, and Mater-Bi (MB) and performed HT at 160−200 °C. MB was identified as a mixture of PLA and polybutylene succinate (PBS). Higher treatment temperatures enhanced the solubilization, which was very marked for PLA and MB and minor for cellulose. Characterization of the solid residues revealed that PLA and MB were quantitatively degraded at 180 °C and above, while cellulose could never be fully degraded. The analysis of the aqueous phases from the HT of PLA and MB revealed the presence of an array of oligomers of PLA and PBS at low temperatures and of the corresponding monomers (lactic acid and succinic acid) at high temperatures: their recovery could represent a way to give new life to waste bioplastics.

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Section: Introductionmentioning

confidence: 99%

Fostering Bioplastics Circularity through Hydrothermal Treatments: Degradation Behavior and Products

Marchelli,

Mattonai,

Ferrentino

et al. 2024

ACS Sustainable Chem. Eng.

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Cellulose Acetates in Hydrothermal Carbonization: A Green Pathway to Valorize Residual Bioplastics

Ischia,

Marchelli,

Bazzanella

et al. 2024

ChemSusChem

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Bioplastics possess the potential to foster a sustainable circular plastic economy, but their end‐of‐life is still challenging. To sustainably overcome this problem, this work proposes the hydrothermal carbonization (HTC) of residual bioplastics as an alternative green path. The focus is on cellulose acetate – a bioplastic used for eyewear, cigarette filters and other applications – showing the proof of concept and the chemistry behind the conversion, including a reaction kinetics model. HTC of pure and commercial cellulose acetates was assessed under various operating conditions (180‐250 °C and 0‐6 h), with analyses on the solid and liquid products. Results show the peculiar behavior of these substrates under HTC. At 190‐210 °C, the materials almost completely dissolve into the liquid phase forming 5‑hydroxymethylfurfural and organic acids. Above 220 °C, intermediates repolymerize into carbon‐rich microspheres (secondary char), achieving solid yields up to 23 %, while itaconic and citric acid form. A comparison with pure substrates and additives demonstrates that the amounts of acetyl groups and derivatives of the plasticizers are crucial in catalyzing HTC reactions, creating a unique environment capable of leading to a total rearrangement of cellulose acetates. HTC can thus represent a cornerstone in establishing a biorefinery for residual cellulose acetate.

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Application of Thermodynamic Methods to the Study of Plant Biomass and Its Components—A Review

Michael

2024

Applied Biosciences

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This article describes the basics of chemical thermodynamics and its application to the study of plant biomass and its main components, cellulose, hemicelluloses, lignin, etc. The energy potential of various biomass types, as well as biomass-based solid, liquid, and gaseous biofuels, is determined. A method of additive contributions of combustion enthalpies of main components is proposed to calculate the combustion enthalpy of biomass samples. It is also established that the potential of thermal energy of the initial biomass is higher than the energy potential of secondary biofuels released from this biomass. The thermodynamic functions of plant biopolymers are calculated. Moreover, the thermodynamic stability of various crystalline allomorphs of cellulose and amorphous cellulose is studied. The melting enthalpies of crystallites with different types of crystalline structures are estimated. A thermochemical method for determining the degree of crystallinity of cellulose is proposed. The most important biomass components are cellulose and other polysaccharides. The thermodynamics of the enzymatic hydrolysis of polysaccharides and their conversion into glucose are described. In addition, the thermodynamic analysis of the conversion process of glucose into bioethanol is performed. Considerable attention is also paid to the thermochemistry of cellulose alkalization, etherification, and esterification.

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Chemical Recycling of Cellulose Acetate Eyewear Industry Waste by Hydrothermal Treatment

Cited by 4 publications

References 35 publications

Fostering Bioplastics Circularity through Hydrothermal Treatments: Degradation Behavior and Products

Fostering Bioplastics Circularity through Hydrothermal Treatments: Degradation Behavior and Products

Cellulose Acetates in Hydrothermal Carbonization: A Green Pathway to Valorize Residual Bioplastics

Application of Thermodynamic Methods to the Study of Plant Biomass and Its Components—A Review

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