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20 resultsShowing papers similar to Aging of microplastics in a subtropical river system in Florida, USA
ClearAging of Microplastics across a Constructed Wetland
Researchers studied the weathering and microbial colonization of five microplastic polymer types over 18 months within four habitat zones of a constructed wastewater wetland, finding that microorganisms colonized plastics rapidly and that weathering rates varied by polymer type and habitat.
Aging of Microplasticsacross a Constructed Wetland
Researchers tracked the aging of five microplastic polymer types — LDPE, HDPE, polypropylene, polystyrene, and PET — across four habitats within a wastewater constructed wetland over 18 months, finding that physical, chemical, and biological processes jointly drive weathering and microorganism colonisation of plastics in these treatment systems.
Weathering Processand Characteristics of Microplasticsin Coastal Wetlands: A 24-Month In Situ Study
Researchers conducted a 24-month study of microplastic weathering in coastal wetlands, characterizing how wetland-specific conditions including UV exposure, salinity, and biological activity alter plastic surface chemistry, fragmentation, and biofilm colonization over time.
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.
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.
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.
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.
Microplastic aging processes: Environmental relevance and analytical implications
Researchers reviewed how microplastics change physically and chemically over time in the environment — a process called 'aging' — and found that standard lab methods for detecting microplastics were mostly developed using fresh, unaged plastics, making it harder to accurately measure real-world contamination. Improved analytical methods that account for aged microplastics are needed for reliable environmental assessment.
Microplastics in river water: occurrence, weathering, and adsorption behaviour
Researchers examined microplastics in river water, characterizing their occurrence, degree of weathering, and capacity to adsorb co-contaminants. The study highlights microplastics as vectors that can transport and re-release other pollutants in freshwater systems.
Effects of microplastic aging on its detectability and physico-chemical properties in loess and sandy soil
This study compared fresh microplastics to aged particles collected from soil and found that weathering significantly changes their physical and chemical properties, including making them more mobile. Aged microplastics may behave very differently in the environment than the pristine particles typically used in laboratory studies.
Comprehensive Understanding on the Aging Process and Mechanism of Microplastics in the Sediment–Water Interface: Untangling the Role of Photoaging and Biodegradation
Researchers examined how microplastics break down at the boundary between water and sediment in coastal wetlands, comparing the roles of sunlight-driven aging and biological degradation. They found that photoaging was the dominant process, accounting for over 55% of surface changes, and that biodegradable plastics aged faster than conventional ones. The study provides important insights into how microplastics transform in real-world coastal environments.
Controls on microplastic breakdown due to abrasion in gravel bed rivers
Researchers investigated the physical controls on microplastic fragmentation due to mechanical abrasion in gravel-bed rivers, examining how particle size, morphology, polymer type, and weathering state influence breakdown rates and the resulting changes in surface properties that alter risk profiles during fluvial transport.
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.
Microplastic aging and plastisphere succession in mangrove sediments: Mechanisms, microbial interactions, and degradation potential
Microplastic aging processes and the succession of microbial communities (plastisphere) in mangrove sediments were tracked over time, revealing how the plastic surface microbiome changes as particles weather. Understanding plastisphere dynamics in coastal ecosystems is important for assessing how microplastics interact with and potentially disrupt mangrove ecology.
Preparing and characterizing environmentally aged microplastics
When microplastics enter the environment, they are not static — UV radiation, water, temperature, and biological activity all cause them to age, changing their surface structure, chemical composition, and behavior. This paper presents a standardized laboratory protocol for systematically recreating and measuring microplastic aging across different environments (soil, water, air, and inside organisms), along with a composite aging index to quantify how degraded a particle has become. Having a consistent, reproducible method for studying aging is a critical step toward understanding how microplastics change as they move through ecosystems and how that affects their health and environmental risks.
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.
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.
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.
Dynamics of plastic debris and its density change between river compartments in the Tuul River system, Mongolia
Researchers investigated the migration dynamics and aging of plastic debris between floodplain, surface water, and sediment compartments of the Tuul River in Mongolia. The study characterized plastic occurrence by abundance, size, shape, polymer type, and photodegradation across river compartments to understand how plastic properties change during transport.
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.