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61,005 resultsShowing papers similar to NovelRelease Mechanism of Microplastics and Nanoplasticsby Environmentally Relevant Sand Abrasion
ClearNovel Release Mechanism of Microplastics and Nanoplastics by Environmentally Relevant Sand Abrasion
Researchers designed a device to quantify microplastic and nanoplastic release from LDPE films through surface abrasion by dry sand over seven months. They found that degradation produced particles across a wide size range and characterised dynamic changes in surface chemistry, identifying abrasion as a significant but underappreciated MP generation mechanism.
Nanoscale Abrasive Wear of Polyethylene: A Novel Approach To Probe Nanoplastic Release at the Single Asperity Level
Scientists created a new method using atomic force microscopy to measure exactly how nanoplastics are released when sand grains scrape against polyethylene surfaces. They found that UV-weathered plastic released nanoplastics at ten times the rate of new plastic, through a different mechanism (cutting instead of plowing). This research provides the first quantitative measurements of nanoplastic release rates, helping predict how much nanoplastic pollution enters the environment from degrading plastic waste.
The effects of sediment properties on the aeolian abrasion and surface characteristics of microplastics
Laboratory experiments quantified how sediment properties influence the rate at which wind abrades and fragments exposed microplastics, generating smaller particles. The results improve understanding of aeolian (wind-driven) microplastic fragmentation as a source of airborne micro- and nanoplastics in arid environments.
On the Formation and Characterization of Nanoplastics During Surface Wear Processes
Researchers characterized nanoplastic particle generation during surface wear processes, finding that mechanical abrasion of bulk plastic materials produces a broad size distribution of particles including sub-100 nm fragments, with surface wear rate depending on polymer hardness and contact conditions.
Macroplastic surface characteristics change during wind abrasion
Laboratory wind tunnel experiments showed that wind-driven abrasion of macroplastics on sandy surfaces produces distinct surface features and generates secondary microplastic particles, demonstrating that wind erosion is a meaningful pathway for plastic fragmentation in arid and coastal environments.
Erosion of rigid plastics in turbid (sandy) water: quantitative assessment for marine environments and formation of microplastics
Researchers quantified the erosion rate of rigid plastic materials by water-borne sand under conditions representing turbid rivers and coastal oceans. Polypropylene showed the highest erosion response at a surface degradation rate of 5,160 um per year, demonstrating that mechanical erosion by suspended sediments is a significant source of microplastic generation in aquatic environments.
The surface degradation and release of microplastics from plastic films studied by UV radiation and mechanical abrasion
Researchers examined how UV radiation and mechanical abrasion, both individually and combined, cause plastic films to degrade and release microplastics. They found that the combination of UV exposure and physical wear was significantly more damaging than either factor alone, accelerating surface deterioration and particle release. The study provides evidence that everyday environmental conditions can generate substantial quantities of microplastics from common plastic materials.
A minimalist approach to quantify emission factor of microplastic by mechanical abrasion
Researchers developed a simple method using light transmittance to measure how quickly plastic films shed microplastic particles when rubbed against a surface. This low-cost approach could help assess the environmental impact of different plastic film products and guide the development of plastics that shed fewer particles.
Secondary Microplastics Generation in the Sea Swash Zone With Coarse Bottom Sediments: Laboratory Experiments
Laboratory experiments in a simulated beach swash zone showed that mechanical abrasion of polypropylene, polyethylene, and polystyrene debris generates secondary microplastic particles in the 0.5-5 mm size range. The study provides direct experimental evidence that wave action on beaches is an active mechanism producing new microplastics from macroplastic debris.
Surface Mechanical Properties and Topological Characteristics of Thermoplastic Copolyesters after Precisely Controlled Abrasion
This study characterized surface mechanical properties and texture changes in thermoplastic copolyesters after controlled abrasion testing. Understanding how polymer surfaces wear is relevant to microplastic generation, since mechanical abrasion of plastic products is a key pathway through which microplastics are released into 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.
The effects of sediment properties on the aeolian abrasion and surface characteristics of microplastics
This study used laboratory wind tunnel experiments to examine how microplastics are physically abraded when transported by wind alongside sand and soil particles, testing angular, sub-rounded, and rounded sediment grains over extended periods. The abrasion altered the surface chemistry and texture of the plastic particles in ways that could affect how they interact with pollutants and organisms in the environment. The work reveals that wind transport does not merely move microplastics — it transforms them, potentially changing their environmental hazard profile.
Nucleation and detachment of polystyrene nanoparticles from plowing-induced surface wrinkling
Researchers used an atomic force microscope tip to scratch polystyrene surfaces and observed the formation of nanoplastic particles up to 250 nm in diameter, revealing a mechanical wear process that could explain how everyday friction on plastic objects generates nanoplastics in the environment.
A method for measuring the emissions of in situ agricultural plastic film microplastics by ultraviolet and mechanical abrasion
Researchers developed a method to measure in situ microplastic emissions from agricultural plastic films under combined UV and mechanical abrasion, providing the first quantitative approach to assess how field conditions cause polyethylene and PVC films to fragment into microplastics.
Impact of erodent shape on microplastic breakdown during wind erosion
Researchers designed abrasion simulation experiments using three different erodent shapes (rounded, sub-angular, and angular sediments) and three sizes of polyethylene spheres to investigate how erodent geometry influences the mechanical breakdown of microplastics during wind erosion, finding that erodent shape significantly affects fragmentation rate and the generation of secondary nanoplastics.
Breakdown and Modification of Microplastic Beads by Aeolian Abrasion
Researchers studied how wind-driven saltation, a natural sand transport process, physically breaks down and modifies microplastic beads. They found that simulated wind abrasion reduced microplastic diameter by 30-50% over several hundred hours, with over 95% of the fragments produced being smaller than 10 micrometers. The study demonstrates that aeolian processes can generate large quantities of secondary microplastic fragments small enough to be inhaled, representing a previously underappreciated pathway of microplastic breakdown in the environment.
On mechanical fragmentation of single-use plastics in the sea swash zone with different types of bottom sediments: Insights from laboratory experiments
Laboratory experiments simulated wave action and beach conditions to study how four common plastic types mechanically fragment from centimeter-scale pieces into microplastics, with fragmentation rates depending on plastic type and sediment composition. Understanding these fragmentation dynamics helps explain how beach plastic litter generates the microplastic particles found in coastal environments.
Impact of erodent shape on microplastic breakdown during wind erosion
Researchers simulated wind erosion abrasion using three sediment erodent shapes (rounded, sub-angular, angular) against three sizes of polyethylene spheres to quantify how erodent geometry drives the physical breakdown of microplastics into smaller particles, including nanoplastics, in aeolian transport environments.
Transport behavior of micro polyethylene particles in saturated quartz sand: Impacts of input concentration and physicochemical factors
Laboratory sand column experiments showed that polyethylene microplastic transport is inhibited by high ionic strength (as it reduces the repulsion between particles and sand grains) but enhanced by fulvic acid (which increases surface charge repulsion). The study provides mechanistic data for predicting how microplastics move through soils under different environmental chemical conditions.
Formation of microplastic fibers and fibrils during abrasion of a representative set of 12 polyester textiles
Abrasion testing of representative polyester fabrics generated microplastic fibers and fibrils, with fiber characteristics reflecting the mechanical and chemical properties of the parent textile. The findings suggest that real-life wear and abrasion during use, not just laundering, is a significant pathway for microfiber release from synthetic textiles.
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.
Nanoscale wear evolution on a polystyrene/poly (n-butyl methacrylate) blend
Researchers used a tiny needle to repeatedly scratch plastic surfaces and filmed how nanoplastics — microscopic plastic fragments — break off during wear, finding that ripple patterns form first before small plastic particles are released. The study reveals how everyday friction on plastic materials generates nanoplastics at the nanoscale level, with implications for understanding pollution from plastic products.
Combined Effects of UV Exposure Duration and Mechanical Abrasion on Microplastic Fragmentation by Polymer Type
Researchers studied how UV exposure duration and mechanical abrasion combine to fragment different plastic types under simulated beach conditions. They found that polypropylene was far more susceptible to fragmentation than polyethylene after UV weathering, while expanded polystyrene broke apart readily even without UV exposure. The experiments showed that a large fraction of fragmented particles were too small to recover, suggesting that significant amounts of nanoplastic are being generated on beaches.
Controls on microplastic breakdown due to abrasion in gravel bed rivers
Researchers investigated the physical controls on microplastic fragmentation due to mechanical abrasion in gravel-bed rivers, examining how particle size, morphology, polymer type, and weathering state influence breakdown rates and the resulting changes in surface properties that alter risk profiles during fluvial transport.