We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Long-term aging and degradation of microplastic particles: Comparing in situ oceanic and experimental weathering patterns
ClearEstimation of the age of polyethylene microplastics collected from oceans: Application to the western North Pacific Ocean
Scientists developed a method to estimate how long polyethylene microplastics have been floating in the ocean by measuring their chemical degradation level and matching it to UV exposure data. They applied this technique to samples from the western North Pacific and estimated ages ranging from months to years. Knowing the age of ocean microplastics helps researchers trace where plastic pollution originates and how far ocean currents carry it.
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.
An advanced analytical approach to assess the long-term degradation of microplastics in the marine environment
Researchers exposed several types of plastic pellets to realistic ocean conditions over time and found that marine weathering caused much faster surface degradation than previously estimated — up to 469 micrometers per year, twelve times higher than older figures — while also generating secondary micro- and nanoplastic particles smaller than one micron. The results provide critical real-world data for assessing how quickly ocean plastics break down into even tinier, harder-to-detect fragments.
Modelling the Photodegradation of Marine Microplastics by Means of Infrared Spectrometry and Chemometric Techniques
Researchers modeled the photodegradation of polyethylene and polypropylene marine microplastics using infrared spectrometry and chemometric techniques, tracking structural and chemical changes during accelerated UV aging that simulated five years of solar exposure.
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.
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.
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.
The wheel of time: The environmental dance of aged micro- and nanoplastics and their biological resonance
This review examines how micro- and nanoplastics change as they age in the environment through exposure to sunlight, water, and biological activity. Aged plastics behave differently than fresh ones: they accumulate faster in ecosystems, are more easily taken up by organisms, and can release trapped chemicals as they break down. The findings suggest that the real-world health and environmental risks of microplastics may be greater than lab studies using new, unweathered plastics indicate.
Novel insight into the aging process of microplastics: An in-situ study in coastal wetlands
Scientists tracked how microplastics age and break down in a coastal wetland in China over three months and found that both sunlight and microbial communities work together to degrade the plastic surfaces. Different plastic types broke down at very different rates, with estimated lifespans ranging from 335 to 661 days before significant degradation. This research helps predict how long microplastics persist in coastal environments that are important for fisheries and human food sources.
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.
An In Situ Experiment to Evaluate the Aging and Degradation Phenomena Induced by Marine Environment Conditions on Commercial Plastic Granules
Researchers designed two experimental setups to monitor the aging and degradation of commercial plastic granules (HDPE, PP, PLA, and PBAT) in marine conditions over three years. The first six months of results showed measurable changes in plastic properties from exposure to seawater and beach conditions. The study provides real-world data on how different plastic types degrade in marine environments, with biodegradable plastics showing faster changes than conventional polymers.
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.
Weathering pathways and protocols for environmentally relevant microplastics and nanoplastics: What are we missing?
This review highlights a major gap in microplastics research: most lab studies use brand-new, pristine plastic particles, but microplastics in the real world have been weathered by sunlight, water, and biological activity. Weathered microplastics behave differently, releasing more chemicals and interacting with organisms in ways that fresh plastics do not. Only about 10% of published studies have used aged microplastics, meaning current risk assessments may not reflect the true dangers of environmental microplastic exposure.
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.
Laboratory-Simulated Photoirradiation Reveals Strong Resistance of Primary Macroplastics to Weathering
Laboratory weathering experiments showed that common plastic items (HDPE, LDPE, PP, PS, PC) retain their bulk structural integrity even after simulated UV and mechanical exposure equivalent to decades of coastal conditions, yet shed a thin surface layer rich in microplastic fragments. This means macroplastics in the ocean act as a persistent, long-term source of microplastic particles even when they appear physically intact.
Short-term degradability of plastic in the marine environment
Researchers incubated seven common plastic polymers (PET, HDPE, PVC, LDPE, PP, PS, and EPS) in the marine environment for 40 days at two sites and two seasons, characterizing degradation through visual inspection, mass change, contact angle, FTIR, and SEM analysis. No significant mass loss occurred, but significant changes in oxidation status were recorded with an oscillating trend, and EPS showed the greatest chemical alteration, with macro-biofouling settlement appearing to shield plastics from photochemical degradation.
Ageing and fragmentation of marine microplastics
Researchers studied how marine microplastics fragment into smaller particles when exposed to UV light and mechanical forces, simulating natural environmental aging. They found that aged microplastics generated an enormous number of fragments, reaching billions of particles per gram of plastic, with most pieces smaller than two micrometers. The results suggest that current environmental sampling methods severely undercount the true number of small microplastic and nanoplastic particles present in the ocean.
Microplastic particle versus fiber generation during photo-transformation in simulated seawater
Researchers exposed common plastic films and fibers to simulated sunlight in seawater and tracked the photo-transformation process, finding that particles and fibers formed at different rates and that UV irradiation preferentially generates certain morphologies depending on the parent polymer.
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.
Insights into the degradation mechanism of PET and PP under marine conditions using FTIR
Researchers investigated the natural degradation of polypropylene and polyethylene terephthalate plastics under real marine conditions using FTIR spectroscopy, providing insights into how these common plastics break down in ocean environments.
Vertical distribution of new and weathered microplastics in the water column: Implications for developing reliable sampling methods
Researchers studied how weathering changes the physical properties of microplastics and affects where they end up in the water column. They found that exposure to sunlight and environmental conditions altered the density and surface chemistry of plastic particles, causing them to settle or float differently than new plastics. The study suggests that current water sampling methods may miss a significant portion of weathered microplastics, since these altered particles distribute more widely across different water depths.
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.
Photochemical dissolution of buoyant microplastics to dissolved organic carbon: Rates and microbial impacts
Common ocean surface microplastics (PE, PP, EPS) were irradiated under simulated sunlight, which fragmented and oxidized the polymers and produced dissolved organic carbon as a significant byproduct. The study identifies sunlight-driven photochemical dissolution as an important but poorly quantified removal mechanism for buoyant microplastics from the ocean surface.
Polymer weathering under simulated solar radiation and comparison to stormwater and estuarine microplastics
Researchers weathered polyethylene and polypropylene plastics under simulated sunlight in water for 90 days and compared their spectral changes to those found in environmental microplastics from stormwater and estuaries. They found that polypropylene degraded faster than polyethylene and that spectral databases had difficulty accurately identifying heavily weathered plastics. The study highlights challenges in identifying and age-dating microplastics found in the environment.