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20 resultsShowing papers similar to The effects of sediment properties on the aeolian abrasion and surface characteristics of microplastics
ClearThe 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.
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.
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.
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.
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.
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.
Is plastic dust different from mineral dust? Results from idealized wind tunnel experiments.
Researchers conducted wind tunnel experiments to compare how plastic particles of different sizes detach from flat surfaces in wind compared to mineral dust particles. Plastic particles required higher wind speeds to become airborne than mineral dust of similar size, likely due to shape differences. These findings inform atmospheric transport models for predicting how far and how much microplastic can be carried by wind across the landscape.
Size, shape, and elemental composition as predictors of microplastic surface erosion
Scientists examined 146 microplastic particles and found that surface erosion depends on particle size and shape — larger particles and irregularly shaped fragments showed more surface degradation than small, round microbeads. More eroded surfaces can release more chemicals and create more nanoplastic fragments. These findings help researchers better assess which types of microplastics may pose the greatest environmental and health risks.
Is transport of microplastics different from mineral particles? Idealized wind tunnel studies on polyethylene microspheres
Wind tunnel experiments revealed that plastic (polyethylene) microspheres behave differently from mineral dust particles when transported by wind, particularly on hydrophobic surfaces, where plastic particles detach and become airborne more readily. Particle-to-particle collisions were found to both assist and impede detachment. These findings help explain why microplastics are found in remote atmospheric environments and improve models for predicting how far plastic particles can travel through the air from pollution sources.
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.
Is transport of microplastics different from that of mineral dust? Results from idealized wind tunnel studies
Researchers conducted wind tunnel experiments to examine the detachment and transport behavior of microplastics ranging from 38 to 125 um in diameter from idealized substrates, comparing their aerodynamic behavior to the well-established literature on mineral dust transport. The study identified key differences in microplastic detachment mechanisms relevant to understanding long-range atmospheric dispersal of plastic particles.
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.
Influence of polymer age and soil aggregation on microplastic transport in soil erosion events
Researchers compared the transport rates of pristine and aged polystyrene microplastics during simulated rainfall events and quantified their incorporation into soil aggregates across multiple wet-dry cycles, providing the first empirical data on how surface roughness and hydrophobicity changes from weathering affect MP mobility in soil erosion.
Morphology-dependent degradation and fragmentation of PVC microplastic particles influence their transport in saturated quartz sand columns
This study examined how the shape and surface characteristics of PVC microplastic particles change over time during degradation and how these changes affect their transport in sand columns. More degraded particles with rougher surfaces were retained more strongly in the sand. The findings show that microplastic weathering state affects environmental mobility, which matters for predicting how long-buried plastic particles move through soil to groundwater.
Tracing the horizontal transport of microplastics on rough surfaces
Wind tunnel experiments showed that microplastics of different shapes are transported horizontally across rough surfaces at wind speeds above threshold values, with flatter and lighter particles moving farther per wind impulse, providing empirical data for modeling atmospheric microplastic dispersal across terrestrial landscapes.
Wind erosion as a driver for transport of light density microplastics
Researchers investigated wind erosion as a transport mechanism for microplastics across different land uses in Iran and found that wind-eroded sediments contained significant quantities of light-density microplastic particles. Agricultural and barren lands showed higher microplastic concentrations in wind-eroded material. The study identifies wind as an important but overlooked pathway for spreading microplastic contamination across landscapes.
Amount and characteristics of microplastic and organic matter in wind-blown sediment at different heights within the aeolian sand saltation layer
Researchers investigated microplastics in wind-blown sediment at different heights within the aeolian saltation layer over farmlands using plastic mulch, finding that wind erosion redistributes microplastics and enriches them at specific heights above the soil surface.
Laboratory simulation of microplastics weathering and its adsorption behaviors in an aqueous environment: A systematic review
UV photo-oxidation and physical abrasion are the most practical laboratory methods for simulating microplastic weathering; aging increases surface area and oxygen-containing functional groups, altering pollutant adsorption behavior and potentially increasing environmental risks.
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.
The impact of microplastic weathering on interactions with the soil environment: a review
This review examines how weathering — exposure to UV light, moisture, and physical forces — changes the surface properties of microplastics and affects their interactions with soil. Weathered microplastics behave differently in the environment, potentially altering soil structure and the movement of water and nutrients.