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61,005 resultsShowing papers similar to Preliminary insights into the photosensensitivity of bio-based plastics: Release of microplastic-derived organic matter in water under UV irradiation
ClearInsights into the photoaging behavior of biodegradable and nondegradable microplastics: Spectroscopic and molecular characteristics of dissolved organic matter release
Researchers compared how biodegradable and conventional microplastics break down under ultraviolet light and what dissolved substances they release. They found that biodegradable PLA microplastics released more protein-like organic matter during UV exposure than conventional polystyrene, and this matter was more readily used by microorganisms. The study suggests that biodegradable plastics, while designed to be better for the environment, may introduce different ecological risks as they break down.
Characterization of microplastic-derived dissolved organic matter in freshwater: Effects of light irradiation and polymer types
Researchers examined how different types of microplastics release dissolved organic matter into freshwater under light and dark conditions. They found that polypropylene released the most organic compounds after UV exposure, while protein-like substances were the main material released by most plastics in the dark. The study indicates that microplastics may have ongoing, long-term effects on water chemistry and microbial activity in natural water bodies.
Photo-induced leaching behaviors and biodegradability of dissolved organic matter from microplastics and terrestrial-sourced particles
Researchers studied how light exposure causes microplastics and terrestrial particles to leach dissolved organic matter, and how this leachate behaves in the environment. The study found differences in the biodegradability of leachate from plastic versus natural sources, suggesting that microplastic-derived organic matter may persist differently in aquatic ecosystems.
Insight into chain scission and release profiles from photodegradation of polycarbonate microplastics
Researchers studied how sunlight breaks down polycarbonate microplastics in water and what chemicals are released in the process. The study found that UV exposure caused the plastics to fragment into smaller pieces while releasing bisphenol A (BPA) and other potentially harmful organic compounds. Importantly, BPA accounted for only a small fraction of the total chemicals released, suggesting that many unknown degradation products are also entering aquatic environments.
Effects of organic additives on spectroscopic and molecular-level features of photo-induced dissolved organic matter from microplastics
Researchers studied how UV sunlight causes microplastics to release dissolved organic matter, and how chemical additives in commercial plastics affect this process. They found that commercial plastics with additives released significantly more organic compounds under UV light than pure polymer particles. The study suggests that as everyday plastic products break down in the environment, their built-in additives may amplify the release of potentially harmful dissolved chemicals into surrounding water.
Photochemistry of microplastics-derived dissolved organic matter: Reactive species generation and organic pollutant degradation
Researchers investigated how dissolved organic matter released from degrading polystyrene and PVC microplastics behaves when exposed to sunlight in water. They found that sunlight breaks down the aromatic compounds in this plastic-derived material and generates reactive chemical species, though at lower rates than natural organic matter. Despite this, these reactive species significantly accelerated the breakdown of co-existing pollutants, suggesting that degrading microplastics may act as unexpected natural catalysts in aquatic environments.
Dissolved organic matter derived from biodegradable microplastic promotes photo-aging of coexisting microplastics and alters microbial metabolism
Dissolved organic matter leaching from two biodegradable microplastics (PBAT/PCL blends) was characterized, finding that it can promote photo-oxidation reactions in water by acting as a photosensitizer. The study raises concerns that biodegradable plastics, while designed to break down, generate chemically reactive leachate with potential environmental impacts.
Insights into the photosensitivity and photobleaching of dissolved organic matter from microplastics: Structure-activity relationship and transformation mechanism
This study investigated the photosensitivity and photobleaching behavior of dissolved organic matter released from microplastics (MPDOM), examining how physicochemical properties of different plastics influence photoactivation and transformation. The structure-activity analysis revealed that MPDOM composition strongly determines its photoreactivity, affecting how microplastic-derived organic compounds interact with sunlight and generate reactive oxygen species in aquatic environments.
The fate of microplastics in the environment: Systematic studies to determine release rates of secondary micro- and nanoplastics and water-soluble organics induced by photolysis and hydrolysis
Researchers conducted systematic studies on the photolytic and hydrolytic degradation of microplastics using three photolysis protocols and multiple polymer types to determine release rates of secondary micro- and nanoplastics and water-soluble organics, providing mechanistic data needed for environmental fate and risk assessment.
The fate of microplastics in the environment: Systematic studies to determine release rates of secondary micro- and nanoplastics and water-soluble organics induced by photolysis and hydrolysis
Researchers conducted systematic studies on the photolytic and hydrolytic degradation of microplastics using three photolysis protocols and multiple polymer types to determine release rates of secondary micro- and nanoplastics and water-soluble organics, providing mechanistic data needed for environmental fate and risk assessment.
Release of microplastics from a bio-based composite after ultraviolet irradiation
Researchers examined the release of microplastic particles from a bio-based polylactic acid (PLA) composite material following ultraviolet irradiation in laboratory conditions, quantifying microplastic formation through observation, identification, and enumeration of released particles. The study aimed to assess whether bio-based polymers marketed as more sustainable alternatives to petroleum-based plastics like polypropylene still generate microplastic pollution during UV-driven environmental degradation.
Increased bio-toxicity of leachates from polyvinyl chloride microplastics during the photo-aging process in the presence of dissolved organic matter
Researchers investigated how photo-aging of polyvinyl chloride microplastics is affected by the presence of dissolved organic matter in surface waters. They found that humic acid, a common component of dissolved organic matter, enhanced the degradation of PVC microplastics under light exposure and significantly increased the toxicity of the resulting chemical leachates. The study highlights the importance of considering dissolved organic matter when assessing the ecological risks of microplastic pollution in natural waters.
Photochemical reactivity of water-soluble dissolved organic matter from microplastics and microfibers
When microplastics and microfibers sit in water, they leach dissolved organic matter (DOM) that can react with sunlight to produce reactive chemicals. This study found that the type and amount of DOM released depends heavily on polymer chemistry, with aromatic plastics like PET and polystyrene releasing more light-absorbing DOM, and microfibers releasing more DOM overall than microplastic particles. Understanding how plastic-derived DOM breaks down in sunlight is important because these chemical by-products can interact with other aquatic pollutants and affect aquatic ecosystems in ways not yet fully understood.
Response of microplastic color to photoaging and its influence on the release characteristics of derived dissolved organic matters
Researchers investigated how the color of microplastics affects their degradation under sunlight and the release of dissolved organic matter. The study found that red and yellow microplastics degraded faster due to stronger ultraviolet absorption, releasing more dissolved organic matter, and that long-term exposure to degradation byproducts from certain colored microplastics inhibited plant seed germination and antioxidant enzyme activity.
Phototransformation and photoreactivity of MPs-DOM in aqueous environment: Key role of MPs structure decoded by optical and molecular signatures
Researchers investigated how dissolved organic matter released from microplastics behaves during light-driven transformation in water. They found that organic matter from benzene-containing polymers showed distinctly different photoreactivity compared to matter from polyolefin-based plastics. The study reveals that the chemical structure of the parent microplastic plays a key role in determining how its dissolved byproducts react and generate reactive species in aquatic environments.
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.
Micro- and nanoplastics released from biodegradable and conventional plastics during degradation: Formation, aging factors, and toxicity
Researchers compared how biodegradable and conventional plastics break down into micro- and nanoplastics during degradation, testing the effects of UV light and mechanical forces. They found that biodegradable plastics like PLA and PBS can produce significant quantities of secondary microplastics, challenging the assumption that they are entirely safe alternatives. The study highlights the need for risk assessments of biodegradable plastics, particularly the tiny fragments generated as they break down.
Deciphering fluorescent and molecular fingerprint of dissolved organic matter leached from microplastics in water
Scientists studied how different types of microplastics release dissolved organic matter into water, finding that UV sunlight dramatically increased the release from PET plastics by 25 times over seven days. The chemical fingerprint of the released compounds differed between PET and polyethylene plastics, with UV exposure making PET compounds harder to break down. This research matters because these leached chemicals can change water quality and may carry additional health risks beyond the plastic particles themselves.
Photodegradation of Microplastics: Mechanism, Influencing Factors and Research Progress
This review examines the mechanisms, influencing factors, and research progress of microplastic photodegradation, covering both direct photodegradation — where UV photons break carbon-carbon bonds in polymers like PE and PP — and indirect photodegradation mediated by photosensitisers such as humic acid. The review highlights that dissolved organic matter can substantially accelerate PS degradation in aquatic environments and discusses key variables including light wavelength, particle size, and matrix composition.
Molecular fingerprints of dissolved organic matter leached from microplastics over prolonged photochemical aging: Implications for aquatic carbon cycling
Researchers used ultra-high-resolution mass spectrometry to identify the dissolved organic molecules that leach from polypropylene, polyethylene, and polystyrene microplastics after prolonged exposure to sunlight. They found that polystyrene released the most diverse array of molecules, many of which could persist in water systems. The study suggests that as microplastics degrade in sunlight, they release non-natural organic compounds that may affect the aquatic carbon cycle from rivers to oceans.
Unraveling the role of natural and pyrogenic dissolved organic matter in photodegradation of biodegradable microplastics in freshwater
Researchers investigated how dissolved organic matter from natural sources versus biochar affects the breakdown of biodegradable polylactic acid (PLA) microplastics in sunlight. Naturally sourced organic matter accelerated PLA degradation nearly twice as much as biochar-derived matter by generating more reactive oxygen species, suggesting that the type of organic matter in a waterway significantly influences whether biodegradable plastics actually break down.
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.
The fate, impacts and potential risks of photoaging process of the microplastics in the aqueous environment
This review examines how ultraviolet light from sunlight causes microplastics in water to age and change their physical and chemical properties, including surface texture, chemical structure, and water-repelling ability. Researchers found that photoaged microplastics become better at carrying other pollutants and may pose greater environmental risks than fresh plastics. The study highlights that aged microplastics can also increase biological toxicity and human exposure risks compared to their original form.
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.