Simultaneous Upcycling of Biodegradable Plastic and Sea Shell Wastes Through Thermocatalytic Monomer Recovery

Lee, Seonho; Lee, Jechan; Park, Young‐Kwon

doi:10.1021/acssuschemeng.2c04050

Cited by 21 publications

(9 citation statements)

References 43 publications

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“…Thermochemical conversion is recently used in the recovery of biodegradable plastics, especially biodegradable straws , and mulch film due to a simple process and wide tolerance to mixed wastes. However, the conversion process was usually conducted at a high reaction temperature (above 400 °C) and therefore consumed a large amount of energy.…”

Section: Introductionmentioning

confidence: 99%

“…8 However, in the easy-to-collect occasion, it is the recovery that should be considered as a preferable choice from the viewpoint of both resource utilization and carbon emission. Thermochemical conversion is recently used in the recovery of biodegradable plastics, especially biodegradable straws 9,10 and mulch film 11 due to a simple process and wide tolerance to mixed wastes. However, the conversion process was usually conducted at a high reaction temperature (above 400 °C) and therefore consumed a large amount of energy.…”

Section: ■ Introductionmentioning

confidence: 99%

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Approach for the Low Carbon Footprint of Biodegradable Plastic PBAT: Complete Recovery of Its Every Monomer via High-Efficiency Hydrolysis and Separation

Shen

Zhang²,

Long

et al. 2023

ACS Sustainable Chem. Eng.

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Biodegradable plastics are considered one of the solutions to solve the environmental pollution caused by plastic waste. However, on easy-to-collect occasions, recovery of biodegradable plastics is a preferable option rather than biodegradation, since it can fully utilize carbon resources and reduce carbon emissions. Herein, efficient and eco-friendly recycling of widely used biodegradable plastic, polybutylene adipate terephthalate (PBAT), was demonstrated by alkaline hydrolysis in the solution of ethanol and H 2 O. The degradation ratio of PBAT was achieved above 99% at 80 °C for 50 min. Diacid salts were self-precipitated out from the reaction solution, followed by acidification to obtain diacid monomers. The reaction solution after filtrating away the diacid salts can be recycled several times without sacrificing the degradation ratio of PBAT, while 1,4-butanediol monomer can be further recovered by the two-step mild distillation at 80 °C. The carbon emission of the whole recycling process was evaluated, and it was only half of that of the biodegradation. The work provides new insight into the recycling of biodegradable plastics.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Approach for the Low Carbon Footprint of Biodegradable Plastic PBAT: Complete Recovery of Its Every Monomer via High-Efficiency Hydrolysis and Separation

Shen

Zhang²,

Long

et al. 2023

ACS Sustainable Chem. Eng.

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show abstract

“…14 The scale of a pyrolysis process can be varied flexibly, allowing the installation of the process at sites in which feedstock is abundantly available. 15 Pyrolysis process is versatile as it can make products in different phases (e.g., solid, gas, and liquid) [16][17][18] by simply varying operational parameters (e.g., temperature, heating rate, and feed and/or vapor residence time). 19 Furthermore, the environmental footprint of pyrolysis is smaller than that of landfilling, gasification, and incineration.…”

Section: Introductionmentioning

confidence: 99%

Upcycling of plastic and tire waste toward use as modifier for asphalt binder

Lee

Park

Lee

2023

Energy & Environment

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A tremendous amount of plastic and tire waste is generated every day. Pyrolysis gives a sustainable plastic and tire waste management solution by transforming them into high-value carbonaceous materials (i.e., char). Char made from plastic or tire waste can be used as a modifier for asphalt binder (i.e., bitumen), in order to improve the properties and performance of base bitumen. In most cases, the char is produced from waste feedstock at ≤300°C, most likely due to the high volatile matter content in feedstock. These chars have been proven experimentally to enhance the deformation resistance, rutting resistance, stiffness, and elasticity of bitumen. The optimal dosage of char in the modification process is highly associated with the kind of waste feedstock and pyrolysis conditions under which the char is made. The present review highlights the promise of the char materials derived from plastic and tire waste for use in materials applied to civil and construction industries, which is aimed specifically at expanding the application of chars made from plastic and tire waste beyond their typical applications, such as in environmental remediation and catalysts.

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“…This allows the system to be installed at sites with abundant feedstock [ 27 ]. Pyrolysis is a versatile process that anaerobically transforms waste feedstock (e.g., plastic waste) into products in various phases (e.g., gas, liquid, and solid) [ 28 , 29 , 30 ]. The product phase and yield can be readily controlled by varying the operational parameters (temperature, heating rate, residence time, reactor type, etc.)…”

Section: Introductionmentioning

confidence: 99%

Plastic-Waste-Derived Char as an Additive for Epoxy Composite

et al. 2023

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Tremendous amounts of plastic waste are generated daily. The indiscriminate disposal of plastic waste can cause serious global environmental issues, such as leakages of microplastics into the ecosystem. Thus, it is necessary to find a more sustainable way to reduce the volume of plastic waste by converting it into usable materials. Pyrolysis provides a sustainable solution for the production of carbonaceous materials (e.g., char). Plastic-waste-derived char can be used as an additive in epoxy composites to improve the properties and performance of neat epoxy resins. This review compiles relevant knowledge on the potential of additives for epoxy composites originating from plastic waste. It also highlights the potential of plastic-waste-derived char materials for use in materials in various industries.

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Simultaneous Upcycling of Biodegradable Plastic and Sea Shell Wastes Through Thermocatalytic Monomer Recovery

Cited by 21 publications

References 43 publications

Approach for the Low Carbon Footprint of Biodegradable Plastic PBAT: Complete Recovery of Its Every Monomer via High-Efficiency Hydrolysis and Separation

Approach for the Low Carbon Footprint of Biodegradable Plastic PBAT: Complete Recovery of Its Every Monomer via High-Efficiency Hydrolysis and Separation

Upcycling of plastic and tire waste toward use as modifier for asphalt binder

Plastic-Waste-Derived Char as an Additive for Epoxy Composite

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