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20 resultsShowing papers similar to The impact of microplastic weathering on interactions with the soil environment: a review
ClearAfter the sun: a nanoscale comparison of the surface chemical composition of UV and soil weathered plastics
Researchers used nanoscale surface analysis to compare how UV light and soil burial weather the chemical composition of plastics differently, finding that each exposure type produces distinct surface changes. These differences affect how plastics interact with surrounding environments, including how they may adsorb or release contaminants as microplastics in nature.
Weathering of microplastics and interaction with other coexisting constituents in terrestrial and aquatic environments
This review summarizes how microplastics weather and interact with other environmental constituents in both terrestrial and aquatic systems. Researchers found that weathering processes such as UV exposure and microbial activity alter the surface properties of microplastics, increasing their ability to adsorb heavy metals, organic pollutants, and pathogens. The study highlights that weathered microplastics may pose greater environmental risks than pristine particles due to their enhanced capacity to carry contaminants.
Effect of weathering on environmental behavior of microplastics: Properties, sorption and potential risks
This review examines how environmental weathering changes the physical and chemical properties of microplastics, affecting their ability to absorb pollutants and their toxicity to organisms. Researchers found that weathered microplastics develop altered surface chemistry, increased surface area, and changed color, all of which influence how they interact with contaminants and are ingested by aquatic life. The study also evaluates the toxic potential of chemical byproducts released during the weathering process itself.
Thermal oxidation, ultraviolet radiation, and mechanical abrasion - understanding mechanisms of microplastic generation and chemical transformation
Researchers evaluated how consumer-derived polymers fragment and chemically transform when exposed to UV radiation or thermal oxidation followed by soil abrasion. The study found that these combined weathering processes, which mimic real-world environmental conditions, significantly affect the rate and type of microplastic generation. The results highlight how everyday use and environmental exposure work together to break down plastics into microplastic particles.
Photodegradation modifies microplastic effects on soil properties and plant performance
Researchers examined how UV-driven photodegradation alters the effects of microplastics on soil properties and plant growth. The study found that degraded plastic fibers increased soil water retention and respiration more than their non-degraded counterparts, while degraded foams reduced soil aggregation, demonstrating that the environmental weathering state of microplastics is an important factor in determining their ecological impact.
Micro- and Nanoplastic Processes: Degradation, Fragmentation, Aggregation and the Need for Environmentally Relevant Reference Materials
This research review explains how tiny plastic particles break down and change when exposed to sunlight, water, and bacteria in the environment. These weathered plastic pieces behave very differently from fresh plastics—they can clump together and move through soil and water in new ways, potentially affecting where they end up in our food and water systems. Understanding how plastics age and change is crucial for predicting their long-term impacts on human health and the environment.
In-soil degradation of polymer materials waste – A survey of different approaches in relation with environmental impact
This review surveys the in-soil degradation of polymer materials — including natural fibers, synthetic plastics, and composites — examining how environmental factors such as UV radiation, microorganisms, moisture, and temperature drive degradation and influence the environmental impact of plastic waste in terrestrial ecosystems.
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.
Effects of microplastics on soil physical, chemical and biological properties
This review examines how microplastics affect soil health, covering their impact on the physical structure, chemical composition, and biological communities of soil ecosystems. Microplastics can alter soil water retention, change nutrient cycling, and harm soil organisms from earthworms to microbes. Since agricultural soils are a major reservoir of microplastics, these changes could affect crop growth and food quality, creating an indirect pathway for microplastic-related harm to human health.
Influence of microplastics on small-scale soil surface roughness and implications for wind transport of microplastic particles
Researchers investigated how microplastics mixed into soil affect surface roughness at small scales, finding that microplastics altered surface texture in ways that could increase soil susceptibility to wind erosion and promote atmospheric transport of microplastic particles.
The Ultraviolet Irradiation Aging Characteristics of Microplastics in Soil under the Action of Biochar
Researchers characterized how microplastics change physically and chemically under ultraviolet irradiation aging, documenting surface cracking, yellowing, and shifts in chemical functional groups. These aging signatures are important for understanding the environmental fate and increased toxicity of weathered microplastics.
Photo-oxidation of Micro- and Nanoplastics: Physical, Chemical, and Biological Effects in Environments
This review examines how sunlight breaks down micro- and nanoplastics in the environment, changing their surface properties and making them interact differently with pollutants and living organisms. Sun-aged plastic particles can become more toxic to aquatic life and affect soil microbe communities, but many questions remain about these processes under real-world conditions.
Aging Process of Microplastics in the Environment
This review examines how natural environmental processes — UV radiation, physical abrasion, chemical reactions, and biodegradation — alter the surface, shape, and chemistry of microplastics over time, and how these changes affect their ability to absorb and transport other pollutants. Understanding microplastic aging is critical because weathered particles behave differently than fresh plastic, often becoming more hazardous as pollutant carriers in ecosystems.
The distribution of pristine and aged low density polyethylene and polyethylene terephthalate microplastics in soil aggregate fractions
Researchers investigated how pristine and artificially weathered low-density polyethylene and polyethylene terephthalate microplastics redistribute across soil aggregate fractions during aggregation, adding particles at low concentration to silt loam and loam soils amended with organic matter over a two-month incubation period. They found that weathering significantly altered microplastic surface properties, which in turn affected how particles interacted with and distributed within soil aggregate fractions during soil formation.
What comes after the Sun? On the integration of soil biogeochemical pre-weathering into microplastic experiments
This perspective article argues that most laboratory microplastic experiments use pristine particles that do not reflect the weathered surface chemistry of environmental microplastics, which undergo UV oxidation, biofilm colonization, enzymatic attack, and physical fragmentation in soil. The author calls for experimental designs that incorporate realistic weathered microplastic surface properties to better predict ecological and transport behavior.
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.
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.
Soils in distress: The impacts and ecological risks of (micro)plastic pollution in the terrestrial environment
This review examines how microplastics affect soil ecosystems, including their transport into soils, changes they undergo in the environment, and their interactions with soil organisms. The effects depend heavily on the type, shape, size, and amount of plastic particles present. Understanding these impacts is important because soil contamination with microplastics can affect food production and ultimately human exposure through the food chain.
The distribution of pristine and aged low density polyethylene and polyethylene terephthalate microplastics in soil aggregate fractions
Researchers investigated how pristine and aged low-density polyethylene (LDPE) and polyethylene terephthalate (PET) microplastics distribute across soil aggregate size fractions, examining whether weathering alters interactions between plastic particles and the soil matrix. The study found that aging significantly modified microplastic surface properties and changed their redistribution patterns within aggregate fractions compared to pristine particles.
UV-degraded polyethylene exhibits variable charge and enhanced cation adsorption
Researchers found that UV degradation of polyethylene alters surface charge and significantly enhances cation adsorption capacity, suggesting that weathered microplastics entering soil create more reactive surfaces than virgin plastic particles.