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20 resultsShowing papers similar to Simulating microplastic transport in unsaturated soil using HYDRUS-1D
ClearRainfall-induced microplastic fate and transport in unsaturated Dutch soils
This study simulated rainfall conditions to track how different types of microplastics move through Dutch soils, finding that sandy soils allowed significantly more microplastics to wash through than loamy soils. Heavier rainfall increased microplastic movement by up to 144% depending on the plastic type, with conventional polyethylene washing out most easily. The findings suggest that rain can carry microplastics from surface soil into groundwater, potentially contaminating drinking water sources.
A dual-pathway modeling framework for rainfall-driven transport of microplastics in soil-water systems
This study tracked how three common types of microplastic — polyethylene, polypropylene, and PET — move through sandy soil during simulated rainfall events, finding that rainfall intensity and plastic type both strongly govern where particles end up. Intense, short bursts of rain transport fewer microplastics both horizontally and vertically than the same total volume of gentler rain, while PET sticks to shallow soil layers and polypropylene travels furthest horizontally due to its buoyancy. The researchers developed mathematical models to predict microplastic movement, which could help inform strategies for intercepting contamination before it reaches groundwater or waterways.
How soil moisture and flow regime drive microplastic transport in the vadose zone: insight from modelling and column experiments
Scientists studied how tiny plastic particles move through soil toward underground water sources that we use for drinking water. They found that plastic particles travel very differently depending on how wet or dry the soil is - sometimes getting trapped, other times moving quickly through the ground. This research helps us better understand how microplastics might contaminate our groundwater supplies, which is important for protecting drinking water quality.
Exploring the vertical transport of microplastics in subsurface environments: Lab-scale experiments and field evidence
Researchers investigated how microplastics move downward through soil using laboratory column experiments and field sampling of groundwater. They found that heavier rainfall, smaller particle size, and fiber-shaped microplastics all increased vertical transport through unsaturated soil. Field samples confirmed the presence of microplastics in both soil layers and groundwater, suggesting that surface plastic pollution can migrate into underground water supplies.
Modeling of Microplastics Migration in Soil and Groundwater: Insights into Dispersion and Particle Property Effects
Researchers developed a mathematical model to predict how microplastics move through soil and into groundwater, accounting for particle size, shape, and water flow conditions. The model shows that smaller and rounder microplastics travel farther and deeper into groundwater systems, which is important for predicting contamination risks to drinking water wells.
Size/shape-dependent migration of microplastics in agricultural soil under simulative and natural rainfall
Researchers found that microplastic migration in agricultural soil under rainfall depends on particle size and shape, with smaller particles moving deeper and rainfall intensity significantly influencing vertical transport patterns in soil profiles.
Geometry-Driven Prediction of Microplastic Transport in Saturated Sediments: Fast and Memory-Efficient Pore-Scale Modeling
Scientists developed a new computer model that can predict how fast tiny plastic particles move through soil and sediment when water flows through them. This matters because microplastics can carry harmful chemicals like pesticides and heavy metals as they travel underground, potentially contaminating drinking water sources and groundwater. The model helps researchers understand where these plastic pollutants might end up and how quickly they could reach water supplies that people depend on.
Impact of Layering and Heterogeneity on the Transport Dynamics of Microplastics in Soil Columns: Implications for Groundwater Contamination
Researchers studied microplastic transport through layered and heterogeneous soil columns to assess groundwater contamination risk from agricultural microplastic inputs. Layered soils with contrasting textures showed preferential flow that accelerated microplastic transport to deeper horizons compared to homogeneous soils, suggesting heterogeneous agricultural soils may pose a higher groundwater contamination risk than previously modeled.
The Effect of Polymer Type and Particle Concentration on Microplastic Transport Mechanisms in Saturated Porous Media
Scientists studied how tiny plastic particles move through soil and groundwater by testing different types of plastics at various concentrations. They found that the amount and type of plastic affects how far these particles travel underground, and that bacteria growing on the plastic surfaces can change how they move through soil. This research helps us better understand how microplastics might contaminate our drinking water sources and food supply.
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.
Experimental and mathematical investigation of cotransport of clay and microplastics in saturated porous media
This study investigated how microplastics travel through underground soil and sand, finding that clay particles in the soil can actually help microplastics move farther by changing how they interact with soil surfaces. The research developed a mathematical model to predict this movement. Understanding how microplastics travel through soil is important because it affects whether they reach and contaminate groundwater used for drinking.
Modelling the effect of microplastics on soil capillary and film water content and flow
Researchers used physical modelling to investigate how microplastics of different polymer types — including PBAT, LDPE, and others — affect soil capillary and film water content and flow, finding that MP presence alters pore-scale water dynamics in ways that influence subsurface water storage and plant water uptake.
Vertical migration of microplastics in porous media: Multiple controlling factors under wet-dry cycling
Researchers studied how microplastics move vertically through sandy soil during cycles of wetting and drying, testing four common plastic types at various particle sizes. They found that smaller, more hydrophobic particles migrated deeper, and that frequent wet-dry cycles and the presence of dissolved organic matter accelerated downward movement. The findings suggest that microplastics in agricultural soils could potentially reach groundwater, posing risks to underground water quality.
Rainfall-Induced Transport of Microplastics in Soils Depends on Soil Pore Structure
Scientists studied how tiny plastic particles move through real soil when it rains, finding that the soil's natural pore structure (like tiny tunnels and holes) determines how deep and fast the plastics travel. This research helps us better understand how microplastics spread through farmland soil, which is important because these plastics could eventually end up in our food and water supply. Understanding this movement is a key step toward predicting long-term health risks from microplastic contamination.
Rainfall-induced lateral and vertical microplastic transport of varying sizes in agricultural fields
Rainfall simulation experiments tracked polyethylene microplastics of three size ranges (53–500 µm) on agricultural soil plots, finding that smaller particles were transported farther laterally in surface runoff and penetrated deeper into soil profiles, highlighting size-dependent microplastic mobility under rainfall conditions.
Microplastic polymer type impacts water infiltration and its own transport in soil
Researchers conducted laboratory soil column experiments to examine how microplastic polymer type affects both water infiltration rates and the transport of the plastic particles themselves through soil, testing the two most commonly used agricultural microplastic types under controlled hydrological conditions. The study found that polymer type significantly influenced both water flow dynamics and microplastic mobility in soil, with important implications for predicting plastic fate in agricultural and natural terrestrial ecosystems.
Overlooked yet critical pathways for microplastics input to soil and groundwater system: Transport mechanisms and simulation predictions in landfill environments
Researchers systematically investigated how microplastics travel through landfill soils into groundwater, examining the effects of particle density, size, polymer type, temperature, and salinity on transport. The study used column experiments and computational modeling to reveal that landfill conditions create overlooked but critical pathways for microplastic contamination of soil and groundwater systems.
Vertical transport of microplastic in agricultural soil in controlled irrigation plot experiments
Researchers conducted field plot experiments in agricultural soil and found that microplastics migrate vertically with irrigation water, with smaller particles (53–63 µm) penetrating up to 6 cm deep and larger particles remaining near the surface, indicating that water infiltration is a key driver of subsurface plastic transport.
Modeling and Parametric Simulation of Microplastic Transport in Groundwater Environments
Researchers developed a parametric simulation model specifically for microplastic transport in groundwater environments, addressing the inadequacy of existing dissolved-contaminant models for studying particulate plastic pollution in subsurface systems.
Processes controlling the transportation of microplastics in agricultural soils
Researchers investigated the physical processes controlling microplastic transport through agricultural soils, examining how soil structure, water flow, bioturbation, and particle properties interact to move microplastics from surface application sites deeper into the soil profile or laterally toward aquatic systems. The study addressed the dual role of agricultural soils as both sinks and potential sources of microplastic pollution to surrounding environments.