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61,005 resultsShowing papers similar to The surface degradation and release of microplastics from plastic films studied by UV radiation and mechanical abrasion
ClearThermal oxidation, ultraviolet radiation, and mechanical abrasion - understanding mechanisms of microplastic generation and chemical transformation
Researchers evaluated how consumer-derived polymers fragment and chemically transform when exposed to UV radiation or thermal oxidation followed by soil abrasion. The study found that these combined weathering processes, which mimic real-world environmental conditions, significantly affect the rate and type of microplastic generation. The results highlight how everyday use and environmental exposure work together to break down plastics into microplastic particles.
From Macro to Micro Plastics; Influence of Photo-oxidative Degradation
This study used simulated UV aging to investigate how photo-oxidative degradation of common plastics drives fragmentation from macro to micro scale, characterizing the surface property changes and structural breakdown that generate microplastic particles in the environment.
Photo-induced degradation of single-use polyethylene terephthalate microplastics under laboratory and outdoor environmental conditions
Researchers tested how sunlight, water, and physical wear work together to break down PET microplastics, the type commonly found in plastic bottles and food packaging. Over 60 days, combined UV light and water exposure caused significant chemical degradation of the plastic surfaces. This matters because as microplastics break down in the environment, they release smaller fragments and potentially harmful chemicals that are easier for organisms to absorb.
Novel Release Mechanism of Microplastics and Nanoplastics by Environmentally Relevant Sand Abrasion
Researchers designed a device to quantify microplastic and nanoplastic release from LDPE films through surface abrasion by dry sand over seven months. They found that degradation produced particles across a wide size range and characterised dynamic changes in surface chemistry, identifying abrasion as a significant but underappreciated MP generation mechanism.
Aging simulation of thin-film plastics in different environments to examine the formation of microplastic
Researchers aged polyethylene, polypropylene, and polystyrene thin films under land, freshwater, estuarine, and oceanic conditions, finding that UV radiation was the primary driver of surface degradation and microplastic formation, with degradation rates varying substantially by environmental medium.
The importance of both physical aging and chemical weathering for the environmental fate of plastic
Researchers investigated the interplay between physical aging and chemical weathering in plastics and their combined effects on microplastic generation, finding that physical aging processes — distinct from photo-oxidation — play an underappreciated role in determining the environmental fate of plastic materials.
Simulated experimental investigation of microplastic weathering in marine environment
Researchers simulated microplastic weathering under marine conditions, finding that exposure to UV light, saltwater, and mechanical abrasion progressively degraded plastic surfaces, increased surface roughness, and enhanced the adsorption capacity of contaminants onto microplastic particles.
A method for measuring the emissions of in situ agricultural plastic film microplastics by ultraviolet and mechanical abrasion
Researchers developed a method to measure in situ microplastic emissions from agricultural plastic films under combined UV and mechanical abrasion, providing the first quantitative approach to assess how field conditions cause polyethylene and PVC films to fragment into microplastics.
The characteristic change of plastic film from common used packing bags under UV photodegradation
Researchers studied how UV light degrades plastic packaging films over time, finding that photodegradation causes surface cracking and chemical changes that progressively break plastic into smaller fragments, including microplastics. The findings help explain how discarded plastic packaging contributes to microplastic accumulation in the marine environment.
UVA-induced weathering of microplastics in seawater: surface property transformations and kinetics
Researchers studied how UVA radiation weathers microplastics in seawater, examining changes to surface properties and degradation rates. The study developed a model integrating an aging index with degradation kinetics, finding that UV exposure significantly transforms microplastic surface characteristics, which affects their behavior and potential ecological impact in marine environments.
Physicochemical and biological ageing processes of (micro)plastics in the environment: a multi-tiered study on polyethylene
Researchers applied a multi-tiered approach combining laboratory aging, field deployment, and environmental simulation to study how polyethylene plastic undergoes physicochemical and biological weathering in natural settings. The study found that UV radiation and microbial colonization act synergistically to accelerate surface oxidation and fragmentation of PE into smaller particles.
Environmental degradation and fragmentation of microplastics: dependence on polymer type, humidity, UV dose and temperature
Researchers systematically tested how UV light, temperature, and humidity cause five common plastic types to break apart into secondary microplastics and nanoplastics. They found that the type of plastic — not the aging conditions — was the main factor determining how quickly it fragmented and what byproducts it released, data that can improve models predicting how plastics break down in the environment.
Combined Effects of UV Exposure Duration and Mechanical Abrasion on Microplastic Fragmentation by Polymer Type
Researchers studied how UV exposure duration and mechanical abrasion combine to fragment different plastic types under simulated beach conditions. They found that polypropylene was far more susceptible to fragmentation than polyethylene after UV weathering, while expanded polystyrene broke apart readily even without UV exposure. The experiments showed that a large fraction of fragmented particles were too small to recover, suggesting that significant amounts of nanoplastic are being generated on beaches.
Progress on the photo aging mechanism of microplastics and related impact factors in water environment
This review examined the photo-aging mechanisms of microplastics in aquatic environments, finding that solar UV radiation drives oxidation reactions that alter surface chemistry, fragment particles further, and enhance their capacity to adsorb and release co-occurring pollutants.
Recent advances on microplastic aging: Identification, mechanism, influence factors, and additives release
This review found that environmental aging transforms microplastic surface properties through abrasion, chemical oxidation, UV irradiation, and biodegradation, altering their environmental behavior and ecological risk. Aging also triggers the release of toxic plastic additives, but significant gaps remain between laboratory aging simulations and real-world conditions.
Study on the impact of photoaging on the generation of very small microplastics (MPs) and nanoplastics (NPs) and the wettability of plastic surface
Experiments using UV light to artificially age six common plastic types showed that sunlight (photoaging) accelerates the breakdown of plastics into very small microplastics and nanoplastics and makes plastic surfaces rougher and more chemically reactive. Understanding how different polymer structures respond to light aging is important for predicting which plastics will fragment fastest in the environment and generate the most hazardous small particles.
Environmental Degradation and Fragmentation of Microplastics: Dependence on Polymer Type, Humidity, UV Dose and Temperature
A systematic study of UV dose, humidity, and temperature effects on six polymer types found that photo-oxidation is the primary driver of microplastic fragmentation and release of secondary nano-sized particles, with the relationship between weathering conditions and fragmentation rates varying by polymer type.
Analysis of ultraviolet and thermal degradations of four common microplastics and evidence of nanoparticle release
Researchers studied how UV light and elevated temperature break down four common plastics and found that weathering releases nanoscale plastic particles. Polystyrene and polypropylene were particularly susceptible to UV degradation, generating significant numbers of nanoparticles. The findings confirm that environmental conditions actively fragment microplastics into even smaller, potentially more harmful nanoplastics.
Linking UV aging of polymers and microplastics formation: An assessment employing various characterization techniques
Researchers examined the link between UV aging of plastic polymers and the generation of microplastics in marine environments, using environmental assessment tools to model the process. The study clarifies how photodegradation rates and polymer type influence the rate and quantity of microplastic formation.
The importance of both physical aging and chemical weathering for the environmental fate of plastic
Researchers investigated the interplay between physical aging and chemical weathering in plastics and their combined role in microplastic generation, addressing a gap in understanding since most prior work has focused solely on chemical aging processes like photo-oxidation. The study examined how physical aging — an unavoidable process in glassy polymers — influences the outcomes of environmentally weathered plastics.
Degradation rates and ageing effects of UV on tyre and road wear particles
Researchers studied how UV light degrades tire and road wear particles, which are considered the largest source of microplastics in the environment. They found that UV exposure caused significant surface cracking and chemical changes in the rubber particles, accelerating their breakdown into smaller fragments. The study provides important data on how quickly these particles degrade outdoors, which helps predict their long-term environmental fate and accumulation.
UV sources and plastic composition influence microplastic surface degradation: Implications for plastic weathering studies
This study tested how different UV light sources change the surface of common microplastics like polyethylene, polypropylene, and polystyrene. The results show that sunlight and lab UV lights weather plastics differently, changing their surface roughness and chemical makeup -- which matters because these surface changes affect how microplastics transport pollutants and interact with living organisms in the environment.
Which factors mainly drive the photoaging of microplastics in freshwater?
This study systematically investigated the roles of UV irradiation, oxygen, temperature, and physical abrasion in the photoaging of polystyrene microplastics in freshwater. UV irradiation and mechanical abrasion were identified as the dominant aging factors, and their combined effect caused more extensive surface oxidation and fragmentation than either alone.
Investigating the Physicochemical Property Changes of Plastic Packaging Exposed to UV Irradiation and Different Aqueous Environments
Researchers investigated UV-driven degradation of polypropylene and PET packaging materials under different aqueous conditions, finding that UV exposure caused significant physicochemical changes including increased crystallinity and surface cracking that contribute to microplastic formation.