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61,005 resultsShowing papers similar to Simulated experimental investigation of microplastic weathering in marine environment
ClearLaboratory simulation of microplastics weathering and its adsorption behaviors in an aqueous environment: A systematic review
UV photo-oxidation and physical abrasion are the most practical laboratory methods for simulating microplastic weathering; aging increases surface area and oxygen-containing functional groups, altering pollutant adsorption behavior and potentially increasing environmental risks.
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.
Abiotic Long-Term Simulation of Microplastic Weathering Pathways under Different Aqueous Conditions
Laboratory weathering experiments simulated long-term microplastic degradation under UV, thermal, and mechanical stress to characterize how environmental exposure alters plastic surface chemistry, fragmentation, and additive release. The results provide insight into the formation pathways of secondary microplastics under realistic environmental conditions.
Effects of Weathering on Microplastic Dispersibility and Pollutant Uptake Capacity
This study examined how environmental weathering changes the surface properties of microplastics and their ability to absorb co-pollutants, finding that weathered MPs bind more contaminants than pristine particles due to surface oxidation and cracking. The results emphasize that the environmental fate and toxicity of microplastics change dynamically as they age in the environment.
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.
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.
Aging mechanism of microplastics with UV irradiation and its effects on the adsorption of heavy metals
Researchers aged polystyrene microplastics using UV irradiation under three conditions (air, pure water, seawater) and found that aging changed surface chemistry and increased the microplastics' capacity to adsorb heavy metals, with seawater aging producing the most pronounced surface oxidation.
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.
Abiotic weathering of plastic: Experimental contributions towards understanding the formation of microplastics and other plastic related particulate pollutants
Scientists studied how the five most common types of plastic break down under realistic environmental conditions involving UV light, temperature changes, and humidity. They found that weathering follows complex, uneven pathways and that the microplastics produced can have very different physical properties depending on the additives in the original plastic. This matters because it means microplastics in the environment are more varied and unpredictable than lab studies using uniform particles suggest, complicating efforts to assess their health risks.
Comprehensive assessment of photo-oxidative degradation and biofilm colonization on microplastic pellets in simulated marine environment
Researchers exposed polyethylene, polypropylene, and nylon-6 microplastics to artificial UV aging and chemical oxidation in seawater to study photo-oxidative degradation and subsequent biofilm colonization. Aging altered surface chemistry and enabled biofilm formation, with degradation rates and biofilm composition varying by polymer type.
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.
A comprehensive review of microplastic aging: Laboratory simulations, physicochemical properties, adsorption mechanisms, and environmental impacts
This review examines how microplastics change as they age in the environment through exposure to sunlight, water, and chemicals, becoming rougher and more chemically reactive over time. Aged microplastics absorb more pollutants than fresh ones and release harmful additives and free radicals, meaning the microplastics people encounter in the real world may be more dangerous than the pristine particles typically used in lab studies.
Linking UV aging of polymers and microplastics formation: An assessment employing various characterization techniques
This study used environmental assessment tools to model how UV aging of plastic polymers drives microplastic formation in marine environments. The analysis identified polymer-specific degradation rates and environmental conditions that accelerate the conversion of plastic debris into 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.
To what extent are microplastics from the open ocean weathered?
Researchers collected plastic debris from the North Atlantic subtropical gyre and analyzed its physical and chemical weathering, finding that most particles showed signs of significant UV-induced oxidation. Understanding the degree of weathering is important because it affects how plastics interact with organisms and how easily they fragment further into nanoplastics.
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.
Environmental behaviors of microplastics in aquatic systems: A systematic review on degradation, adsorption, toxicity and biofilm under aging conditions
Aging processes like UV irradiation and physical abrasion alter microplastic surface properties, increasing their capacity to adsorb environmental pollutants while also enhancing leaching of toxic additives like phthalates, collectively amplifying the environmental toxicity of weathered microplastics.
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.
Emerging investigator series: microplastic-based leachate formation under UV irradiation: the extent, characteristics, and mechanisms
Six common microplastic types were exposed to UV irradiation to characterize surface changes and leachate chemical profiles, finding that UV treatment generated oxidized surface groups and released diverse organic compounds. Leachate composition varied by polymer type, highlighting the role of weathering in generating secondary chemical pollution from microplastics.
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.
Change in adsorption behavior of aquatic humic substances on microplastic through biotic and abiotic aging processes
Researchers found that both UV irradiation and microbial aging of polyethylene microplastics significantly altered their surface chemistry, changing how aquatic humic substances adsorb onto the plastic surface and highlighting the importance of weathering state in assessing microplastic-contaminant interactions.
Elaborating more realistic model microplastics by simulating polypropylene's environmental ageing
This study developed more realistic model microplastics by simulating the environmental aging of polypropylene, producing laboratory particles with surface chemistry, roughness, and density closer to field-collected environmental microplastics.
Data Sheet 1_UVA-induced weathering of microplastics in seawater: surface property transformations and kinetics.docx
Researchers examined UVA-induced weathering of microplastics in seawater, characterizing surface property transformations and developing kinetic models to describe how UV exposure alters the physical and chemical properties of microplastic particles during environmental aging.
Impact of weathering on the chemical identification of microplastics from usual packaging polymers in the marine environment
The impact of environmental weathering on the chemical identification of common microplastics was investigated, examining how UV radiation, mechanical abrasion, and microbial activity alter the spectroscopic signatures used for polymer identification. Weathered plastics were harder to correctly identify than pristine ones, highlighting the need for reference libraries that include aged material.