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61,005 resultsShowing papers similar to Plastic litter fate and contaminant transport within the urban environment, photodegradation, fragmentation, and heavy metal uptake from storm runoff
ClearLitter in Urban Areas May Contribute to Microplastics Pollution: Laboratory Study of the Photodegradation of Four Commonly Discarded Plastics
Laboratory photodegradation experiments showed that four common plastic litter types (LDPE, PP, PS, and PET) generate microplastics when exposed to UV light, confirming that urban litter is a direct land-based source of MPs transported to waterways by stormwater. Degradation rates and microplastic generation varied significantly among polymer types under the same exposure conditions.
Partitioning of heavy metals in sediments and microplastics from stormwater runoff
Researchers studied how heavy metals distribute between sediment particles and microplastics in stormwater runoff. UV-weathered microplastics absorbed significantly more heavy metals than new plastic, competing with sediments for metal uptake. This matters because microplastics in stormwater can transport concentrated heavy metals from urban areas into rivers and lakes, creating a combined pollution problem.
Photodegradation of macroplastics to microplastics : A laboratory study on common litter found in urban areas
A laboratory study used UV light to simulate how plastic litter found in urban environments degrades into microplastics over time. The results help explain the pathway from discarded plastic items to the small fragments now found across the environment, from soils to human tissues.
Investigate the influence of microplastics weathering on their heavy metals uptake in stormwater
Researchers examined how weathering of polyethylene and PET microplastics affects their ability to absorb heavy metals like lead and zinc from stormwater. They found that weathered microplastics had significantly rougher surfaces and altered chemistry, which increased their uptake of heavy metals compared to pristine particles. The study suggests that aged microplastics in urban stormwater systems may accumulate and transport higher concentrations of toxic metals into waterways.
Quantitative study of microplastic degradation in urban hydrosystems: Comparing in situ environmentally aged microplastics vs. artificially aged materials generated via accelerated photo-oxidation
Researchers compared how polyethylene microplastics degrade in real urban water environments versus under controlled laboratory UV exposure. They found that lab-aged plastics showed primarily physical and chemical changes from UV light, while microplastics collected from stormwater and sediments also showed signs of biological degradation and hydrolysis. The study demonstrates that artificial aging alone does not fully replicate the complex degradation processes microplastics undergo in actual urban water systems.
Fragmentation of polypropylene into microplastics promoted by photo-aging; release of metals, toxicity and inhibition of biodegradability
This study showed that when polypropylene plastic ages in sunlight, it fragments into microplastics much faster and releases metal contaminants that were originally added during manufacturing. The resulting particles and chemical leachates were toxic to aquatic organisms and resistant to biodegradation, meaning aged plastics in the environment are more hazardous than fresh ones.
Microplastic emission characteristics of stormwater runoff in an urban area: Intra-event variability and influencing factors
Researchers investigated microplastic emission characteristics in urban stormwater runoff from industrial and residential catchments. Microplastics were detected in concentrations of 54 to 639 particles per liter, with polypropylene and polyethylene being the dominant polymers and fragments the most common shape, and concentrations were higher after longer dry periods.
Microplastic emission characteristics of stormwater runoff in an urban area: Intra-event variability and influencing factors
Researchers found that stormwater runoff from both industrial and residential urban catchments contained substantial microplastics (54–639 particles per liter), with polypropylene and polyethylene dominating, and that microplastic concentrations peaked early in rain events following longer dry periods.
Microplastic degradations in simulated UV light, natural light and natural water body: A comparison investigation
Researchers compared how microplastics made of PVC, polyethylene, and polyamide break down under UV light, natural sunlight, and real-world water body conditions, finding that natural environments cause more complex degradation involving both biofilm growth and heavy metal interactions. Importantly, microplastics in natural water can both release and re-absorb heavy metals over time, complicating their environmental risk profile.
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.
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.
Accelerated photoaging of microplastic - polyethylene terephthalate: physical, chemical, morphological properties and pesticide adsorption
Researchers subjected polyethylene terephthalate (PET) microplastics to accelerated photoaging under simulated sunlight, characterizing changes in surface chemistry, crystallinity, and mechanical properties over time. Photoaging increased surface oxidation, reduced molecular weight, and enhanced the release of plastic additives, suggesting aged PET microplastics present greater chemical hazard than pristine particles.
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.
Microplastic Properties Govern the Photodegradation of Sorbed Anthracene in Aquatic Environments
Researchers found that microplastic properties — including polymer type, surface chemistry, and aging state — govern the rate and pathway of solar photodegradation of sorbed anthracene in aquatic environments, with sorption to microplastics altering contaminant photochemical fate compared to free solution.
Studying the combined influence of microplastics’ intrinsic and extrinsic characteristics on their weathering behavior and heavy metal transport in storm runoff
Researchers found that the weathering behavior and heavy metal uptake of microplastics in stormwater depended on both intrinsic polymer properties — such as crystallinity — and extrinsic surface conditions like oxidation and sediment attachment, with secondary microplastics showing greater lead and zinc adsorption than primary microplastics.
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.
From macroplastics to microplastics: Role of water in the fragmentation of polyethylene
Laboratory photodegradation experiments compared how polyethylene plastic films fragment in water versus air under UV light, finding that the aquatic environment significantly influences the physical and chemical breakdown of plastic into microplastics. The study improves understanding of how water immersion changes the photodegradation pathways of floating and submerged plastic debris.
Aging assessment of microplastics (LDPE, PET and uPVC) under urban environment stressors
Researchers aged LDPE, PET, and uPVC microplastics using ozone, UV-C, and solar radiation to simulate urban environmental stressors, finding that each aging agent produced distinct changes in surface morphology, chemical structure, and crystallinity that could alter particle behavior in the environment.
Physicochemical transformation and toxic potential of polyethylene terephthalate (PET) fragments exposed to natural daylight
Researchers exposed PET plastic fragments to natural sunlight and studied how weathering changed their chemistry and toxicity. They found that sun-aged PET released a more complex mixture of chemicals, including plasticizers and metals like antimony, and became significantly more toxic to marine microalgae and bacteria. The findings highlight that plastic degradation in the environment does not make it harmless but can actually increase the danger posed by leached substances.
Microplastic Presence, Aging, and Potential Sources in Urban Runoff in a Large Piedmont Metropolitan Area: Polymer-Type-Specific Analysis
Scientists found over 20,000 tiny plastic particles in rainwater runoff from a large metropolitan area, with the plastics coming from both local sources like degraded items on the ground and particles falling from the atmosphere. These microplastics can end up in our water supply and food chain, potentially affecting human health. The study helps identify where these harmful plastic particles come from in big cities, which is important for finding ways to reduce our exposure to them.
Multi-contaminants in road runoff of a compact city: Characteristics, interactions, and ecological risks
Researchers characterised multi-contaminant pollution in road runoff from a compact city, examining the sources, transport mechanisms, interactions, and ecological risks of co-occurring contaminants including microplastics, heavy metals, and other pollutants. The study found that microplastics in road runoff interact with co-contaminants in ways that amplify ecological risk, with urban density and road surface type influencing contaminant profiles.
Evaluation of microplastic contamination by metals in a controlled environment: A risk to be considered
Researchers found that polyethylene terephthalate microplastics readily adsorb nickel, copper, and zinc metals in aquatic environments, demonstrating that degraded plastics can act as carriers for metal contaminants and pose compounded environmental risks.
Neglected but Crucial Role Played by Rainwater in the Photodegradation of Plastic
Researchers exposed common plastic types to sunlight for 12 months, with and without rainwater contact, to study how rainwater affects plastic degradation. They found that rainwater significantly accelerated the photodegradation of plastics, producing more microplastic fragments than sunlight alone. The study reveals that rainwater plays a previously overlooked but important role in breaking down plastic waste into microplastics in the environment.
How aging microplastics influence heavy metal environmental fate and bioavailability: A systematic review
This systematic review found that environmental aging (UV, weathering) degrades microplastics into smaller particles with higher surface reactivity, increasing their capacity to adsorb heavy metals. These aged microplastic-heavy metal complexes bioaccumulate through the food chain, posing greater ecological and human health risks than either pollutant alone.