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20 resultsShowing papers similar to Is transport of microplastics different from that of mineral dust? Results from idealized wind tunnel studies
ClearIs 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.
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.
Atmospheric transport dynamics of microplastic fibres
Researchers examined the atmospheric transport dynamics of microplastic fibres within boundary layer flows, comparing their motion to mineral grain transport and finding key differences in behaviour that have important implications for modelling the long-range atmospheric dispersal of microplastics to remote and rural locations.
Effects of Shape and Size on Microplastic Atmospheric Settling Velocity
Researchers measured atmospheric settling and horizontal drift velocities of various microplastic shapes and sizes in controlled settling chambers, providing empirical data needed to improve atmospheric transport models that explain how microplastics reach remote environments.
Data example and code used in the publication "Is transport of microplastics different from that of mineral dust? Results from idealized wind tunnel studies"
This dataset and code repository accompany a wind tunnel study on how microplastic transport by wind compares to mineral dust transport. The study examines whether standard dust transport models can be applied to predict microplastic movement through the atmosphere.
Atmospheric Resuspension of Microplastics from Bare Soil Regions
Researchers developed a method to estimate how microplastics get lifted from bare soil into the atmosphere along with mineral dust, then modeled their global transport and deposition. They found that this soil-based resuspension is a meaningful source of atmospheric microplastics, with fiber-shaped particles traveling significantly farther than spherical ones. The study suggests that dust storms and wind erosion from agricultural and arid lands may be an underappreciated pathway for spreading microplastic contamination worldwide.
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.
Vertical concentrations gradients and transport of airborne microplastics in wind tunnel experiments
Wind tunnel experiments tracked how tiny airborne microplastic particles (about half a micrometer in diameter) distribute vertically in moving air, finding conditions under which they can remain suspended and travel long distances. These results help explain how microplastics reach remote environments like mountain peaks and Arctic ice, and contribute to models of human inhalation exposure in urban and rural settings.
Entrainment and horizontal atmospheric transport of microplastics from soil
Researchers investigated the mechanisms by which microplastics become entrained from soil into the atmosphere, finding that wind-driven processes can transport plastic particles horizontally near the ground surface, establishing agricultural soils as a significant source of airborne microplastics.
Normalized Settling Velocity Governs Short-Range Transport of Atmospheric Microplastics
Wind tunnel experiments showed that how fast a microplastic particle settles under gravity—its normalized settling velocity—is the single best predictor of how far it travels through the air before landing. This finding helps fill a major gap in atmospheric microplastic research by enabling better models of where airborne plastic particles deposit, which affects estimates of human inhalation exposure and ecosystem contamination.
Long-distance atmospheric transport of microplastic fibers depends on their shapes
Researchers developed a theory-based settling velocity model for microplastic fibers in the atmosphere that accounts for fiber shape and cross-sectional dimensions, finding that correctly characterising flat fibers rather than treating them as cylinders increases estimated mean atmospheric residence time by over 450%, suggesting the ocean is a major source of airborne plastic and that long-range transport is far more efficient than previously thought.
Comment on egusphere-2023-1025
This comment discusses a study on atmospheric transport of microplastics, noting that the mechanisms that move microplastics through the air differ importantly from those for mineral dust. Better understanding these transport pathways is essential for accurately predicting where airborne microplastics deposit globally.
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.
Geometric Form and Density Govern Microplastic Particle Kinetics During Aeolian Transport
Scientists studied how tiny plastic particles move through the air and found that they travel faster and farther than natural particles like sand. This means microplastics can spread much more easily through wind to remote areas where people live, including places far from pollution sources. Understanding how these plastics move through the air is important because it helps explain why microplastics are showing up everywhere on Earth, potentially affecting human health through the air we breathe.
Long-distance atmospheric transport of microplastic fibers depends on their shapes
This study investigated how the shape of microplastic fibers affects how far they travel through the atmosphere. Long, thin fibers stay airborne longer and can be transported greater distances than compact fragments, explaining why synthetic textile fibers are so widely found in remote 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.
Particle properties and environmental factors control atmospheric transport and deposition of micro- and nanoplastics
Researchers built a mathematical model to predict how micro- and nanoplastics travel through the atmosphere, finding that particles around 1 micrometer in diameter and fiber-shaped plastics can remain airborne for weeks and travel long distances. Factors like wind speed, rainfall, and the particles' own shape and density determine whether plastics stay in the air for seconds or spread globally.
Data example and code used in the publication "Is transport of microplastics different from that of mineral dust? Results from idealized wind tunnel studies"
This duplicate dataset entry accompanies a wind tunnel study examining how airborne microplastic transport compares to mineral dust. Atmospheric transport of microplastics is an important but understudied pathway for distributing plastic contamination to remote environments.
Atmospheric transport of microplastic particles as a function of their size and shape
Researchers investigated the atmospheric transport and settling of microplastic particles as a function of size and shape, implementing a shape-correction parameterization for fiber-shaped particles in an atmospheric transport model to better represent their reduced gravitational settling velocity compared to spheres. The study showed that non-spherical fibers experience greater atmospheric drag, increasing their residence time and transport distance, and that including shape effects improved agreement between model output and ground-based measurements.
Physical characteristics of microplastic particles and potential for global atmospheric transport: A meta-analysis
This meta-analysis pools data from multiple studies to examine the physical characteristics of airborne microplastics and how they travel through the atmosphere. The findings confirm that microplastics can be transported globally by wind, meaning people everywhere are breathing in these particles regardless of how far they live from pollution sources.