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20 resultsShowing papers similar to Effect of Polypropylene Microplastic on Soil Water Characteristic Curve
ClearEffects of microplastics on the water characteristic curve of soils with different textures
Researchers studied how polyethylene microplastics at different concentrations and sizes affect the water-holding properties of sandy and loamy soils. The study found that low concentrations had minimal impact, while high concentrations significantly altered soil water characteristics, with small microplastics improving water retention in loamy soil and larger particles reducing water content in sandy soil.
Effects of microplastics on the hydraulic properties and pore characteristics of compacted soil
Researchers investigated how polyethylene microplastics affect the hydraulic properties and pore structure of compacted soil, finding that higher microplastic concentrations disrupted pore size distribution and reduced saturated hydraulic conductivity while altering water retention capacity.
The influence of microplastics on the dry end of the soil-water retention curve
Researchers measured how adding microplastics to soil affects the soil-water retention curve beyond the wilting point — the level at which plants can no longer extract water. Different microplastic types affected water retention differently depending on their surface properties and shape. These changes in soil water dynamics could affect plant available water and agricultural productivity in microplastic-contaminated soils.
Dry‐wet alternation and microplastics particle size effects on and contributions to soil water and soil pore properties
Researchers examined how microplastics of different particle sizes affect soil water properties and pore characteristics under repeated drying-wetting cycles typical of agricultural fields. They found that both microplastic size and the drying-wetting alternation influenced soil hydraulic parameters and pore distributions. The study suggests that microplastic residues in farmland soils may alter water retention and movement in ways that could affect agricultural productivity.
Can Microplastic Pollution Change Soil-Water Dynamics? Results from Controlled Laboratory Experiments
Researchers conducted controlled laboratory experiments examining how microplastic shape and concentration affect soil water-holding capacity and evaporation in fine sand, finding through statistical and non-parametric analyses that microplastic pollution at environmentally relevant concentrations significantly altered both hydrological parameters.
Soil texture is an important factor determining how microplastics affect soil hydraulic characteristics
This study tested how polypropylene microplastics of different sizes affect how water moves through three types of soil. Adding microplastics reduced the soil's ability to absorb and hold water by up to 96%, with clay soils being the most affected. These changes to soil water flow could affect crop growth and potentially increase the movement of other pollutants through contaminated farmland.
Microplastics effects on wettability, pore sizes and saturated hydraulic conductivity of a loess topsoil
Researchers tested how polyethylene terephthalate (PET) and polystyrene microplastics at concentrations already found in farmland soils affect key physical properties of agricultural soil. They found that adding microplastics reduced the soil's ability to conduct water and hold moisture, with larger particles at higher concentrations causing the greatest changes. The study suggests that microplastic accumulation in agricultural soils could alter water movement and availability in ways that may affect crop growth.
Impact of Microplastics on Soil Health: Soil-Water Retention, Shrinkage and Holding Properties
A review of research on microplastics in soil found that plastic particles can alter water retention, shrinkage, and structural properties in ways that could reduce agricultural productivity. Because microplastics are as prevalent in soils as in oceans, their terrestrial impacts warrant much greater research attention.
Microplastics alter soil structural stability as quantified by high-energy moisture characteristics
Scientists found that adding polypropylene and polyethylene microplastic fibers to soil changed its physical structure by altering pore spaces and weakening soil aggregates. Larger fiber sizes and higher concentrations caused more disruption to soil water retention and drainage. These changes to soil structure could affect crop growth and water management on farms where microplastic contamination from irrigation or mulch films has accumulated.
Concentration‐ and Size‐Dependent Influences of Microplastics on Soil Hydraulic Properties and Water Flow
Researchers investigated how microplastic concentration and particle size affect soil hydraulic properties and water flow. They found that microplastic contamination reduced saturated conductivity by up to 50% and inhibited water infiltration, with higher concentrations and larger particle sizes leading to weaker soil water-holding capacity.
Microplastic induces soil water repellency and limits capillary flow
Laboratory experiments showed that microplastics mixed with sandy soil induced water repellency and reduced capillary water flow, with the magnitude of the effect depending on MP content and the relative sizes of MP and soil particles. The findings suggest that microplastic accumulation in soil can impair water infiltration and potentially disrupt plant-available water in agricultural soils.
Saturated hydraulic conductivity in microplastics incorporated soils: Effects of soil texture, polymer type, particle size, and concentration
Researchers measured saturated hydraulic conductivity in loam and sandy loam soils amended with PET, PVC, and PE microplastics of two size classes, finding that PET particles in sandy loam produced the highest conductivity values and that polymer hydrophobicity and particle size both influence soil water flow.
Effects of Microplastics on Soil Hydraulic Properties
Researchers investigated how pristine and UV-weathered polypropylene granules and polyester fibers affect soil hydraulic properties in a silt loam soil, finding that microplastic incorporation altered bulk density, saturated hydraulic conductivity, water holding capacity, and aggregate stability in ways that depended on particle shape and weathering state.
Microplastic-induced alterations in water flow and solute transport dynamics in soil
Researchers conducted laboratory experiments to measure how microplastics alter water flow and nutrient transport through soil. They found that polyethylene and PVC microplastics clogged soil pores, reducing water conductivity by up to 74% and creating uneven flow patterns. The study suggests that microplastic accumulation in agricultural soils could significantly impair water and nutrient delivery to crops.
Microplastics Have Widely Varying Effects on Soil
Researchers found that microplastic concentrations as low as 0.4% alter soil drainage, with potential downstream consequences for crop growth and plant productivity.
Potential impacts of microplastic pollution on soil–water–plant dynamics
Researchers tested how different shapes and sizes of high-density polyethylene (HDPE) microplastics affect a soil's ability to hold water, finding that fragment-shaped microplastics increased water retention by up to 36% — a significant change that could alter water availability for crops and affect agricultural planning in contaminated soils.
Impacts of Microplastics on the Soil Biophysical Environment
Four common microplastic types (polyacrylic fibers, polyamide beads, polyester fibers, PE fragments) were added to loamy sand soil at environmentally relevant concentrations in a garden experiment and effects on soil-water relationships, structure, and microbial function were measured over 5 weeks. Results showed that microplastics altered water repellency, aggregate stability, and microbial activity in a plastic-type-dependent manner, confirming that microplastics can disrupt fundamental soil biophysical processes.
Microplastics Can Change Soil Properties and Affect Plant Performance
Researchers tested six different types of microplastics in soil and found that they altered key soil properties including water-holding capacity, bulk density, and microbial activity. These changes in soil structure had cascading effects on plant growth, with some microplastic types reducing above-ground biomass. The study demonstrates that microplastics can fundamentally change how soil functions, with consequences for plant health and ecosystem stability.
Effects of microplastics on evaporation dynamics in porous media
Researchers found that polyethylene and PVC microplastics altered soil water evaporation rates and crack formation patterns in laboratory experiments, with effects varying by microplastic type, concentration, and soil texture, suggesting microplastics can disrupt soil water dynamics.
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.