Degradation Rates of Plastics in the Environment

Chamas, Ali; Moon, Hee‐Jong; Zheng, Jiajia; Qiu, Yang; Tabassum, Tarnuma; Jang, Jun Hee; Abu-Omar, Mahdi M.; Scott, Susannah L.; Suh, Sangwon

doi:10.1021/acssuschemeng.9b06635

Cited by 1,704 publications

(1,104 citation statements)

References 169 publications

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“…Apart from the modification of the microstructural properties to achieve better mechanical properties, optical reflectance, and customizable transmission of UV radiation (optical and radiometric properties), the rate of natural degradation and compostability predicts the environmental sustainability of plastics in agricultural settings. Synthetic plastics such as HDPE, PET, and PP plastics are not biodegradable; this is demonstrated by the low specific surface degradation rate (SSDR) of 10 2 and 10 3 μm/year [50]. The limited biodegradability of these structures is attributed to the unique chemical properties and bonding.…”

Section: Degradation and Compostabilitymentioning

confidence: 99%

“…Micro-plastics are small plastic fragments with a size that varies between 0.5 and 5 mm [50], which originate from plastic additives and plastic debris [61]. In 2020, there were at least, 250,000 tons and 51 trillion pieces of micro-plastics [61].…”

Section: Spread Of Micro-plastics In the Environmentmentioning

confidence: 99%

“…The unique fragmentation behaviors also limit the formation of biofilms, and by extension the probability of decomposition. In contrast to biofilms, which are degraded naturally in the environment, micro-plastics exhibit oxygen incorporation, which translates to an increase in the mass and the attraction of micro-organisms [50], which may latter aid the degradation process. However, since the degradation process is slow the risk of ingestion by marine species remains high [62]; this would impact human health considering that seafood is a staple diet in coastal areas.…”

Section: Spread Of Micro-plastics In the Environmentmentioning

confidence: 99%

See 2 more Smart Citations

Environmental Sustainability of Plastic in Agriculture

Maraveas

2020

Agriculture

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This article investigates the environmental sustainability of plastic nets in agricultural environments based on published experimental data. This article focuses on biodegradable and synthetic plastics used in farms as mulching materials and shade materials/greenhouse covering materials (shade nets and plastic films) to protect plants from pests and extreme weather. The sustainability was determined by three factors, carbon footprint from cradle to the end of life (LCA), durability (resistance to photo-oxidation and high tensile strength), and affordability. The LCA analyses showed that the production of polyethylene (PE) requires less energy and generates low quantities of greenhouse gas equivalents. Beyond the LCA data, biodegradable polymers are sustainable based on biodegradability and compostability, ability to suppress weeds, control soil temperatures, and moisture, and augment fertigation and drip irrigation. However, existing technologies are a limiting factor because lab-based innovations have not been commercialized. In addition, industrial production of shade nets, plastic greenhouse covers, and mulching materials are limited to synthetic plastics. The bio-based plastic materials are sustainable based on biodegradability, and resistant to photo-oxidation. The resistance to UV degradation is an essential property because solar radiation cleaves C-C bonds, which in turn impact the mechanical strength of the materials. In brief, the sustainability of plastics in farms is influenced by LCA data, mechanical and optical properties, and performance relative to other materials.

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Section: Degradation and Compostabilitymentioning

confidence: 99%

Section: Spread Of Micro-plastics In the Environmentmentioning

confidence: 99%

Section: Spread Of Micro-plastics In the Environmentmentioning

confidence: 99%

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Environmental Sustainability of Plastic in Agriculture

Maraveas

2020

Agriculture

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“…The co-densification of biomass and plastic wastes can be considered as a step closer to a circular bioeconomy that can achieve a reduction of over 80% (assuming 90% wood and 10% plastics) of greenhouse gas emission compared with the use of coal (Eriksson and Finnveden, 2009). Meanwhile, combusting plastic wastes as a fuel can also achieve the rapid degradation of these non-biodegradable polymers, rather than degradation in the environment with long-lasting pollution (Chamas et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Densification of Biomass and Waste Plastic Blends as a Solid Fuel: Hazards, Advantages, and Perspectives

Song

Hall

2020

Front. Energy Res.

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This mini-review considers the densification of biomass blended with plastic wastes as an approach for waste management and sustainable fuel production from two perspectives; (1) We overviewed the pollutants generated during plastics combustion and their hazards. The control of these pollutants can be achieved as both reported in literature and by currently in-service municipal waste plants. (2) Advantages from densifying biomass/plastic blends as a solid fuel are indicated. Biomass/plastic briquettes or pellets are a potentially promising solid fuel with low costs, high volumetric heating values, high resistance to mechanical damage, and good durability performance under humid conditions. Moreover, the combustion of biomass/plastic blends with <10% plastics has no substantial negative effect on pollutants emission compared with that of biomass. Perspectives on densifying biomass/plastic blends as a solid fuel are proposed to realize the scale-up of this technique.

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“…Most nonbiodegradable plastic wastes cause significant land and marine pollution [ 1 ]. This problem has changed the direction of serious attention towards ecological sustainability and the possible impact on related animals and plants [ 2 , 3 , 4 ].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Photodegradation Stability in Poly(butylene adipate-co-terephthalate) Composites Using Organically Modified Layered Zinc Phenylphosphonate

Wang

Chen

et al. 2020

Polymers

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The enhancement of the ultraviolet (UV) photodegradation resistance of biodegradable polymers can improve their application efficacy in a natural environment. In this study, the hexadecylamine modified layered zinc phenylphosphonate (m-PPZn) was used as a UV protection additive for poly(butylene adipate-co-terephthalate) (PBAT) via solution mixing. The results from the Fourier transform infrared spectroscopy (FTIR) and wide-angle X-ray diffraction analysis of the m-PPZn indicated the occurrence of hexadecylamine intercalation. FTIR and gel permeation chromatography were used to characterize the evolution of the PBAT/m-PPZn composites after being artificially irradiated via a light source. The various functional groups produced via photodegradation were analyzed to illustrate the enhanced UV protection ability of m-PPZn in the composite materials. From the appearance, the yellowness index of the PBAT/m-PPZn composite materials was significantly lower than that of the pure PBAT matrix due to photodegradation. These results were confirmed by the molecular weight reduction in PBAT with increasing m-PPZn content, possibly due to the UV photon energy reflection by the m-PPZn. This study presents a novel approach of improving the UV photodegradation of a biodegradable polymer using an organically modified layered zinc phenylphosphonate composite.

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Degradation Rates of Plastics in the Environment

Cited by 1,704 publications

References 169 publications

Environmental Sustainability of Plastic in Agriculture

Environmental Sustainability of Plastic in Agriculture

Densification of Biomass and Waste Plastic Blends as a Solid Fuel: Hazards, Advantages, and Perspectives

Enhanced Photodegradation Stability in Poly(butylene adipate-co-terephthalate) Composites Using Organically Modified Layered Zinc Phenylphosphonate

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