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61,005 resultsShowing papers similar to [Research Progress on Plastic Aging Processes and Their Environmental Hazards].
ClearRecent 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.
Innovative overview of the occurrence, aging characteristics, and ecological toxicity of microplastics in environmental media
This review summarizes existing research on where microplastics are found in the environment, how they age and break down, and their toxic effects on living organisms. The paper highlights that as microplastics weather in the environment through sunlight and chemical exposure, they become smaller and can carry other pollutants, potentially increasing their health risks. It also covers emerging strategies for detecting and removing microplastics.
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.
Degradation of microplastics in the natural environment: A comprehensive review on process, mechanism, influencing factor and leaching behavior
This review examines how microplastics break down in the environment through physical, chemical, and biological processes, and what happens as they degrade. As microplastics age and fragment, they release chemical additives and dissolved organic matter that can be toxic, meaning degrading plastics may actually become more harmful to ecosystems and human health over time.
A review on enriched microplastics in environment: From the perspective of their aging impact and associate risk
This review explores what happens to microplastics as they age in the environment over long periods. Researchers found that natural weathering changes the physical and chemical properties of microplastics in ways that may increase their ability to harbor harmful microorganisms and interact with other pollutants, suggesting that aging may actually make microplastic pollution more hazardous over time rather than less.
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.
Mechanistic insights into non-negligible toxicity evolution of microplastics under different aging processes
This review examines how different environmental aging processes, such as UV exposure, mechanical wear, and chemical weathering, change the physical and chemical properties of microplastics and alter their toxicity. Researchers found that aged microplastics and the chemicals they leach tend to be more harmful to organisms than fresh particles, causing growth inhibition and genetic damage. The findings suggest that the environmental risks of microplastics may increase significantly as they degrade over time.
Nanoplastics in aquatic environments: The hidden impact of aging on fate and toxicity
This review highlights that most toxicity studies on nanoplastics use brand-new pristine particles, but real-world nanoplastics are aged by sunlight and chemical exposure, which fundamentally changes their surface properties and toxicity. Aged nanoplastics may be more harmful than pristine ones because they interact differently with biological systems, meaning current safety assessments likely underestimate the true risks.
Aging of plastics in aquatic environments: Pathways, environmental behavior, ecological impacts, analyses and quantifications
This review examines how plastics age and degrade in aquatic environments through photo-oxidation, mechanical abrasion, and biodegradation. Researchers discuss the physicochemical changes that occur in aging plastics and the release of potentially harmful oxidation products during degradation. The study suggests that understanding these complex aging dynamics is essential for assessing the environmental and ecological risks posed by microplastics.
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.
Effects of aging on environmental behavior of plastic additives: Migration, leaching, and ecotoxicity
This review examines how the aging and weathering of microplastics in the environment causes chemical additives like plasticizers, flame retardants, and antioxidants to leach out. As microplastics age through UV exposure, heat, and biological activity, they release these additives more readily, increasing the toxic risk to organisms. The findings are important because they show that older, weathered microplastics found in the real world may be more chemically hazardous than fresh plastics used in most lab studies.
Oxidation and fragmentation of plastics in a changing environment; from UV-radiation to biological degradation
This review examines how plastics break down in the environment through UV radiation, weathering, and biological processes, producing smaller and smaller fragments including microplastics and nanoplastics. The breakdown process also releases chemical additives and creates particles with altered surface properties that may be more toxic than the original plastic. Understanding these degradation pathways is critical because the secondary particles produced may pose greater risks to ecosystems and human health than the larger plastic debris.
Mechanism and characterization of microplastic aging process: A review
This review explains how microplastics age and break down in the environment through sunlight, heat, and chemical reactions, and why this aging process matters. As microplastics weather, their surfaces change in ways that make them better at absorbing toxic pollutants and more harmful to living organisms. Understanding these aging processes is important because the microplastics people encounter in food and water have typically been weathered, meaning they may be more dangerous than the fresh plastics used in most lab studies.
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.
Effect of Polymer Aging on Uptake/Release Kinetics of Metal Ions and Organic Molecules by Micro- and Nanoplastics: Implications for the Bioavailability of the Associated Compounds
Researchers developed a theoretical framework to describe how aging and degradation of plastic particles in the environment changes their ability to absorb and release metals and organic contaminants. They found that as plastics weather and break down, their capacity to pick up and later release pollutants increases significantly. The study suggests that the age and condition of microplastics are important factors in determining how much contamination they carry and deliver to living organisms.
Leaching behavior and toxic effect of plastic additives as influenced by aging process of microplastics
This review examined how environmental aging processes affect the leaching behavior and toxicity of plastic additives from microplastics. Researchers found that UV exposure, weathering, and biological degradation alter the physicochemical properties of microplastics, increasing the release of harmful chemical additives and potentially amplifying their toxic effects on organisms in the environment.
Environmental Implications of Physicochemical Differences Between Environmental Nanoplastics and Their Commercial Forms
Researchers conceptually analyzed physicochemical differences between environmentally aged nanoplastics and their commercial engineered forms, examining how natural aging alters surface properties, environmental stability, and behavior in aquatic media for five types of environmentally relevant nanoplastic models.
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.
Microplastics: From Intrinsic Properties to Environmental Fate
This review examines how the built-in properties of plastics — their chemical structure, additives, and molecular weight — determine how quickly they break down in the environment and what happens when they do. As microplastics degrade, they fragment into even smaller particles that may be more harmful because they can more easily enter living organisms. Understanding these degradation pathways is essential for predicting the long-term environmental and health risks of plastic pollution.
Aging of plastics and microplastics in the environment: a review on influencing factors, quantification methods, challenges, and future perspectives
This review examined how plastics and microplastics age and degrade in the environment through physical, chemical, and biological processes. Researchers found that while various analytical techniques exist to measure degradation, there is no widely accepted standard method for comparing how different environmental conditions affect microplastic breakdown rates. The study highlights the need for better tools to predict how long microplastics will persist in different environments, which is essential for understanding their long-term ecological impact.
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.
Complex release dynamics of microplastic additives: An interplay of additive degradation and microplastic aging
This study investigated how microplastics release their chemical additives -- including phthalates, bisphenol A, and flame retardants -- into water, especially under UV sunlight. The process is more complicated than simple leaching: sunlight both breaks down the additives and ages the plastic itself, which changes how fast chemicals are released. These findings matter because the toxic additives that leach from microplastics may pose a greater health risk than the plastic particles themselves.
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.
Aging Process of Microplastics in the Aquatic Environments: Aging Pathway, Characteristic Change, Compound Effect, and Environmentally Persistent Free Radicals Formation
This review summarizes how microplastics age and transform in aquatic environments through oxidation, weathering, and fragmentation. Researchers documented changes in particle size, crystallinity, and surface chemistry during the aging process, and found that aged microplastics may interact synergistically with other environmental pollutants. The study also describes how photoaging generates environmentally persistent free radicals that could pose additional toxicity concerns.