Trends in Polyester Upcycling for Diversifying a Problematic Waste Stream

Kulkarni, Amruta; Quintens, Greg; Pitet, Louis M.

doi:10.1021/acs.macromol.2c02054

Cited by 21 publications

(14 citation statements)

References 143 publications

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“…PET is extensively used in packaging and textiles, while BPA-PC finds applications in electronic, constructional, and optical applications. For PET, several typical depolymerization methods, including alcoholysis, glycolysis, aminolysis, and hydrolysis, were well reviewed. ,, In our work, the methanolysis of PET required a higher temperature (Table ) compared with PLA. For example, PLA could be fully depolymerized at 140 °C by methanolysis.…”

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confidence: 79%

Solvent-Promoted Catalyst-Free Recycling of Waste Polyester and Polycarbonate Materials

Zhang,

Hu,

et al. 2024

ACS Macro Lett.

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Polymeric materials are indispensable in our daily lives. However, the generation of vast amounts of waste polymers poses significant environmental and ecological challenges. Instead of resorting to landfilling or incineration, strategies for polymer recycling offer a promising approach to mitigate environmental pollution. Pioneering studies have demonstrated the alcoholysis of waste polyesters and polycarbonates; however, these processes typically require the use of catalysts. Moreover, the development of strategies for catalyst removal and recycling is crucial, particularly in some industrial applications. In contrast, we present a catalyst-free method for the alcoholysis of common polyester and polycarbonate materials into small organic molecules. Certain polar organic solvents exhibit remarkable efficiency in polymer degradation under catalyst-free conditions. Employing these polar solvents, both polymer resins and commercially available products could be effectively degraded via alcoholysis. Our design contributes a straightforward route for recycling waste polymeric materials.

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confidence: 79%

Solvent-Promoted Catalyst-Free Recycling of Waste Polyester and Polycarbonate Materials

Zhang,

Hu,

et al. 2024

ACS Macro Lett.

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“…Chemical upcycling primarily involves the conversion of plastic polymers into their monomers or some short chains which can therefore be used as fuels or feedstock for polymerization reactions and the further production of VAP. , As a result, plastic waste can be converted into solid carbonaceous materials, liquids including acids and fuels, and gaseous fuels such as hydrogen and syngas. − The separation of various plastics, contamination, the potential creation of corrosive gases, and the typical low selectivities of products are some of the practical issues that currently plague chemical upcycling operations. , Although conventional chemical upcycling uses more energy, it is a promising strategy since it may produce a wide range of readily available compounds with the judicious development of catalysts and reaction conditions. Further, biological upcycling mainly focuses on microorganisms and enzymatic activity for the valorization of plastics with some review articles published. − Ru et al revealed that the enzymatic reactions are inefficient after reviewing the microbial valorization of plastic waste . The expense of utilizing or maintaining enzymes and bacteria, the constrained variety of reaction conditions, and the narrow scope to mostly condensation polymers are further issues with biological techniques for upcycling plastics …”

Section: Conventional Methods Of Plastic Waste Managementmentioning

confidence: 99%

Upcycling of Plastic Waste Using Photo-, Electro-, and Photoelectrocatalytic Approaches: A Way toward Circular Economy

Sajwan,

Sharma,

Sharma

et al. 2024

ACS Catal.

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Rapid industrialization and development have led to a tremendous increase in the use of various types of plastic commodities in daily life. For the past several years, plastic pollution has become a global issue, posing a serious threat to mankind. The primary issue with increasing plastic pollution is the lack of proper management which has created huge havoc in the environment. From the initial phase of plastic waste management, plastic waste has been discarded, recycled, downcycled, or dumped into landfills in a large proportion, causing extreme damage to the ecosystem. Conventionally, plastic waste is treated via thermal processes such as pyrolysis or incineration plants which require a large amount of capital and, therefore, harms the aim of circular economy. Chemical upcycling is gaining large attention as a high-potential catalytic strategy to convert waste plastics, such as polyethylene terephthalate, polyethylene, polystyrene, etc. to various fuels, functionalized polymers, and other value-added chemicals having a direct impact on affordability and viability. In this review, we have focused on the use of photocatalysis, electrocatalysis, and photoelectrocatalysis as effective and efficient plastic upcycling technologies. These approaches can lower the dependence on nonrenewable resources and, therefore, are more environmentally friendly in contrast to the conventional approaches. This review elaborately discusses the pros and cons of the conventional approaches and provides a detailed overview of the potential of renewable energy-driven approaches for the conversion of plastic wastes to valuable fuels and commodity chemicals, along with the challenges and future directions of this emerging approach for plastic waste treatment.

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“…Poly(ethylene terephthalate) (PET) is the most important aromatic polyester available today, widely used in film and beverage packaging and textiles. , However, the fossil-based nature of terephthalic acid (TPA) or its dimethyl ester (dimethyl terephthalate) used in PET production has raised serious questions concerning its sustainability. − Consequently, there has been an enormous interest recently in the industry and academia to develop alternative biobased aromatic dicarboxylic acids and dicarboxylates as a potential substitute for TPA in aromatic polyesters. − One significant achievement in this direction is the development of 2,5-furandicarboxylic acid (FDCA) derived from a sugar-based building block. The polycondensation of FDCA with ethylene glycol yields a 100% biobased polyester known as poly(ethylene 2,5-furandicarboxylate), or PEF, which possesses comparable or even slightly better properties than PET. , Inspired by this successful example, several alternative biobased aromatic diacid or dicarboxylates have been reported for polyester synthesis, particularly using the phenolic and furanic building blocks obtained from lignocellulosic biomass. − …”

Section: Introductionmentioning

confidence: 99%

Semi-Crystalline and Amorphous Polyesters Derived from Biobased Tri-Aromatic Dicarboxylates and Containing Cleavable Acylhydrazone Units for Short-Loop Chemical Recycling

Valsange,

de Menezes,

Warlin

et al. 2024

Macromolecules

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Recycling polymers by site-specific scission into short-chain oligomers/polymers, followed by recoupling these to form the original polymer presents an energetically more favorable shorter-loop chemical recycling in comparison to recycling into monomers. Here, we present the synthesis and polymerization of tri-aromatic diesters to prepare polyesters with acylhydrazone units as weak structural links. Two diester monomers were prepared by combining methyl 5-chloromethyl-2-furoate, obtainable from 5-chloromethylfurfural, with potentially biobased hydroquinone and resorcinol, respectively. The two diesters have a central phenyl ring flanked by two furan rings, and were polymerized with 1,6-hexanediol and 1,4-butanediol, respectively, together with controlled amounts of monofunctional ethyl levulinate to form telechelic ketone-terminated polyesters. Subsequent reactions of these telechelic polyesters with adipic dihydrazide yielded the corresponding chain-extended polyesters with increased molecular weights ([η] = 0.29–0.52 dL g–1) with acylhydrazone units in the backbone. Thermogravimetric analysis showed a high thermal stability of the polyesters with thermal decomposition only above 275 °C. The polyesters containing the linear hydroquinone units were found to be semi-crystalline materials with melting points at 158 and 192 °C, respectively, while those containing the kinked resorcinol units were fully amorphous with glass transition temperatures at 35 and 44 °C, respectively. Initial investigations of the chemical recyclability of the polyesters demonstrated that acylhydrazone units could be selectively cleaved to recover the original telechelic ketone-terminated polyesters, which could again be chain-extended to obtain a recycled polymer with molecular weights and properties very similar to those of the original material.

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Trends in Polyester Upcycling for Diversifying a Problematic Waste Stream

Cited by 21 publications

References 143 publications

Solvent-Promoted Catalyst-Free Recycling of Waste Polyester and Polycarbonate Materials

Solvent-Promoted Catalyst-Free Recycling of Waste Polyester and Polycarbonate Materials

Upcycling of Plastic Waste Using Photo-, Electro-, and Photoelectrocatalytic Approaches: A Way toward Circular Economy

Semi-Crystalline and Amorphous Polyesters Derived from Biobased Tri-Aromatic Dicarboxylates and Containing Cleavable Acylhydrazone Units for Short-Loop Chemical Recycling

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