We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Evaluating factors influencing microplastic mobility in sediments through visualization and experiments
ClearEvaluating factors influencing microplastic mobility in sediments through visualization and experiments
Researchers used micro-CT imaging to visualize three-dimensional transport pathways of microplastics through gravel and sand sediments relevant to riverbank filtration, finding that smaller sediment pore sizes restrict microplastic mobility and that particle properties such as shape, size, and polymer density influence infiltration depth.
Investigations on microplastic infiltration within natural riverbed sediments
Researchers used laboratory flume experiments to investigate how sediment grain size affects the infiltration of four types of microplastics (PET spheres, PET ellipsoids, polystyrene fragments, and polyamide fibers) into riverbed sediments. Sediment particle size, microplastic shape, and density were key factors controlling how deeply microplastics penetrate into the hyporheic zone.
Longitudinal and Vertical Transport of Microplastic Within Sediment in Rivers and Transitional Water Environments
Researchers investigated the longitudinal and vertical transport of microplastics within sediments in rivers and transitional water environments, developing models to quantify how sediment presence affects microplastic mobility and their transport toward coastal areas.
Assessing the Behavior of Microplastics in Fluvial Systems: Infiltration and Retention Dynamics in Streambed Sediments
Scientists used laboratory river-bed simulations to study how microplastics move from surface water down into streambed sediments. Smaller particles (1 micrometer) penetrated deeper into the sediment than larger ones, and higher water flow pushed more particles downward. This research helps explain how microplastics accumulate in river beds, which serve as both drinking water sources and habitats for aquatic organisms.
X-ray computed tomography: A novel non-invasive approach for the detection of microplastics in sediments?
Researchers tested whether X-ray computed tomography (CT scanning) can non-invasively detect microplastics in river sediment cores, finding it works well for particles 4 mm or larger but cannot resolve smaller microplastics below 125 μm due to resolution limits. Importantly, CT scanning also revealed sediment layering and structural features that affect where microplastics accumulate — information that is lost when sediment cores are physically extracted and processed by conventional methods. This non-destructive approach could improve how scientists study microplastic distribution in sediments.
Microplastic infiltration into mobile sediments
Researchers used an annular flume to simulate how microplastic particles infiltrate into sandy river sediments as bedforms migrate. They found that particle size was the most important factor determining how deep microplastics penetrated into the sediment, while bedform speed and particle density had less influence. The study reveals that smaller microplastics can be buried deeper in river sediments, making them harder to detect and potentially creating long-term contamination reservoirs.
Exploring the influence of sediment motion on microplastic deposition in streambeds
This study systematically explored how sediment motion affects microplastic deposition in streambeds made of fine sediments, finding that sediment transport dynamics play a critical role in controlling where microplastics accumulate. The results improve understanding of microplastic fate in riverine systems.
Transport and retention patterns of fragmental microplastics in saturated and unsaturated porous media: A real-time pore-scale visualization
Real-time pore-scale visualization using a microscope-coupled flow cell was used to track how fragmented microplastics move and deposit in saturated and unsaturated porous media, revealing distinct transport and retention patterns depending on water saturation conditions. The findings improve mechanistic understanding of how microplastics migrate through soils toward groundwater.
Pore-Scale Insights into Microplastic Fiber Transport and Retention in Porous Media
Pore-scale imaging and experiments revealed how microplastic fibers move through and get retained in soil and sediment pores, showing that fiber shape and size strongly influence transport distance and accumulation zones. Understanding these dynamics is key to predicting where microplastics accumulate in terrestrial and subsurface environments.
Influence of sediment size on microplastic fragmentation
Researchers examined how sediment grain size influences the physical fragmentation of microplastics in river environments, where the mechanical controls on microplastic storage, remobilization, and transfer pathways remain poorly understood. The study found that sediment size plays a meaningful role in breaking down plastic particles, contributing to the generation of smaller microplastic fragments in fluvial systems.
Behaviour and transport of microplastics under saturated flow conditions in sediments and soils
Researchers investigated the behaviour and transport of microplastics under saturated flow conditions in sediments and soils, examining how particle properties influence movement through porous media. The study aimed to improve understanding of subsurface microplastic fate and transport relevant to both soil and groundwater contamination.
High resolution X-ray microtomography as a tool for observation and classification of individual microplastics
Researchers investigated X-ray microtomography (microCT) as a non-destructive tool for characterizing microplastics embedded in sediment, demonstrating that the technique could provide detailed internal and external morphological data to help classify individual particles based on structure and composition.
Laboratory Experiments on the Transport of Microplastic Particles in Gravel and Sand Sediments
Researchers used column experiments to study the transport and infiltration behavior of PET, POM, PMMA, and PS microplastic particles across a range of sizes and densities in gravel and sand sediments, employing a novel ice-embedding technique to introduce particles and measuring their depth distribution after three days of flow.
Subsurface transport of microplastic particles in gravel columns: Impacts of different rain events and particle characteristics
Researchers conducted column experiments using pre-stained microplastic particles of two density types in gravel sediment to investigate how different rainfall intensities and land-use scenarios influence the vertical transport and retention of microplastics in subsurface environments. The study found that both particle density and rainfall event characteristics significantly affected microplastic mobility through subsurface sediments, informing models of microplastic fate in soil-water systems.
A depth-resolved snapshot of microplastic abundances in riffle heads in a gravelbed river
Researchers took depth-resolved samples from gravel riverbed sediments to map how microplastics distribute vertically through streambeds. They found significant quantities at depth, suggesting that riverbeds act as long-term reservoirs of microplastic pollution rather than just transient transport pathways.
Pore-Scale Visualized Transport and Retention of Fibrous and Fragmental Microplastics in Porous Media under Various Surfactant Conditions
Researchers used a pore-scale visualization system to observe how fibrous and fragmental microplastics move through porous media under different surfactant conditions. They found that fibrous microplastics had lower mobility because they tend to entangle and clog pore spaces, while fragmental particles moved more freely and responded differently to various surfactant types. The study provides detailed insight into how microplastic shape and surface chemistry influence their transport through soil and groundwater systems.
Studying the effect of moving sandy bedforms on the infiltration behavior of microplastic particles
This laboratory study investigated how microplastic particles move through sandy riverbeds when the sediment itself is in motion. Results showed that natural sand movement significantly affects where microplastics end up, which has important implications for understanding how plastics accumulate in freshwater ecosystems.
Behaviour and transport of microplastics under saturated flow conditions in sediments and soils
Researchers investigated the behavior and transport of microplastics under saturated flow conditions in sediments and soils, examining how physical and chemical properties of microplastic particles influence their mobility through porous geological media. The study addressed knowledge gaps in understanding subsurface microplastic transport relevant to groundwater contamination and the fate of microplastics deposited in terrestrial environments.
Microplastic Pathways: Investigating Vertical and Horizontal Movement from Riverine Environments to Oceans
Researchers investigated the vertical and horizontal movement of microplastics in riverine systems en route to the ocean, examining how physical MP characteristics and hydrodynamic conditions govern whether particles settle near riverbeds or float at the surface, and how both gravity-driven and flow-driven transport contribute to their ultimate fate.
Transport and retention of polyethylene microplastics in saturated porous media: Effect of physicochemical properties
Researchers studied how polyethylene microplastics move through water-saturated sand and gravel, testing the effects of particle size, water chemistry, and flow speed. They found that smaller microplastics traveled farther through the porous material, while higher salt concentrations and lower flow rates increased particle retention. The findings help explain how microplastics may spread through groundwater systems under real-world conditions.
Microplastics/nanoplastics in porous media: Key factors controlling their transport and retention behaviors
This review examines what controls how microplastics and nanoplastics move through soil and other porous materials like sand and sediment. Factors like particle size, shape, surface charge, water flow speed, and the presence of other pollutants all influence whether plastics stay in place or travel deeper into groundwater. Understanding these transport behaviors is important for assessing the risk of microplastics contaminating underground drinking water sources.
Real-Time Visualization of Infiltration and Retention of Microplastics with Different Shapes in Porous Media
Researchers used an improved refractive index matching method to visualize in real time how microplastics of different shapes infiltrate and become retained in porous media under water flow. They found that spherical microplastics penetrated deepest with the most vertical trajectories, while cylindrical and flaky particles showed more lateral movement and frequent deceleration. The study reveals how microplastic shape significantly influences their transport behavior in soil-like environments.
Hydro-geomorphological features govern the distribution, storage, and transport processes of riverbed microplastics
This study examined how river channel shape, water flow, and sediment dynamics control where microplastics accumulate, travel, and are stored in riverbeds. Identifying these hydro-geomorphological drivers is important for predicting microplastic transport to downstream ecosystems and the ocean.
Riverbed depth-specific microplastics distribution and potential use as process marker
Researchers examined the depth-specific distribution of microplastics in riverbed sediments, finding that particle concentration and type varied significantly with sediment depth. The findings suggest that riverbeds act as significant microplastic sinks, with deeper layers representing older accumulation zones.