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Papers
20 resultsShowing papers similar to Modeling the evolution of nanoplastic particle aggregation in aquatic systems
ClearEffects of temperature and particle concentration on aggregation of nanoplastics in freshwater and seawater
The aggregation behavior of nanoplastics in freshwater and seawater was studied at different temperatures and particle concentrations, finding that salinity, particle concentration, and temperature all significantly influenced aggregation rates with implications for nanoplastic fate in aquatic environments.
Prediction of nanoplastics aggregation in wastewaters
Researchers modeled how nanoplastic particles from degraded plastic waste aggregate in wastewater under different conditions. Understanding aggregation behavior is key to predicting how nanoplastics move through water treatment systems and ultimately whether they reach drinking water sources.
Mechanistic understanding of the aggregation kinetics of nanoplastics in marine environments: Comparing synthetic and natural water matrices
Researchers investigated aggregation kinetics of polystyrene nanoplastics in marine environments, finding that organic matter type and salt concentration strongly influenced particle stability, with nanoplastics in natural seawater aggregating differently than in synthetic matrices.
Nanoplastics display strong stability in aqueous environments: Insights from aggregation behaviour and theoretical calculations
Nanoplastics released into aquatic environments were found to be highly stable and resist aggregation and settling under many conditions, meaning they can persist and disperse widely rather than quickly sinking. This environmental stability makes nanoplastics particularly concerning as long-lived and mobile contaminants in water systems.
Aggregation behavior of polyethylene microplastics in the nearshore environment: The role of particle size, environmental condition and turbulent flow
Researchers investigated how particle size, salinity, dissolved organic matter, and turbulent flow affect the aggregation behavior of polyethylene microplastics in nearshore water, finding that all factors influenced aggregation rates and aggregate structure. Understanding microplastic aggregation in estuarine environments is essential for predicting their sedimentation and biological uptake.
Surface Charge Regulation of Nanoplastics in Aquatic Environments
Researchers developed a coupled mathematical model integrating electrostatic and diffusion equations to predict how environmental factors regulate the surface charge of nanoplastics in aquatic systems. The model revealed that pH, ionic strength, and dissolved organic matter all critically influence nanoplastic surface charge, governing their aggregation and transport behavior.
Molecular modeling to elucidate the dynamic interaction process and aggregation mechanism between natural organic matters and nanoplastics
Researchers used molecular modeling to understand how nanoplastics interact with natural organic matter found in water environments. They found that the chemical properties of both the plastic surface and the organic molecules determined whether they clumped together or remained dispersed. The study provides new molecular-level insights into how nanoplastics behave and spread in natural water systems, which is important for predicting their environmental fate.
Heteroaggregation of nanoplastic particles in the presence of inorganic colloids and natural organic matter
Nanoplastics were found to heteroaggregate extensively with inorganic colloids and natural organic matter in both freshwater and marine conditions, altering their size, surface charge, and settling behavior compared to pristine particles. The study demonstrates that nanoplastic behavior in natural waters is dominated by interactions with other environmental constituents rather than the intrinsic properties of the plastic alone.
Novel measurement method of determining PS nanoplastic concentration via AuNPs aggregation with NaCl
Researchers examined how salinity and dissolved organic matter affect the aggregation and sedimentation of polystyrene nanoplastics in estuarine water, finding that higher salinity and humic acid promoted particle aggregation and accelerated settling. These dynamics influence the fate and bioavailability of nanoplastics in coastal environments.
Understanding the stability of nanoplastics in aqueous environments: effect of ionic strength, temperature, dissolved organic matter, clay, and heavy metals
This study examined how environmental factors including ionic strength, temperature, dissolved organic matter, and clay affect the stability and aggregation of nanoplastics in water, finding that these conditions significantly influence particle behavior. Understanding nanoplastic stability is critical for predicting their fate, transport, and bioavailability in aquatic systems.
Heteroaggregation kinetics of nanoplastics and soot nanoparticles in aquatic environments
Researchers examined how polystyrene nanoplastics and soot particles aggregate together in aquatic environments, finding that particle ratio, salinity, pH, and dissolved organic matter all influence clumping rates — with calcium ions dramatically accelerating aggregation and potentially altering nanoplastic transport in coastal and marine waters.
The suspension stability of nanoplastics in aquatic environments revealed using meta-analysis and machine learning
Researchers combined machine learning and meta-analysis to model nanoplastic aggregation behavior in water, finding that surface charge is the dominant factor, and predicting that nanoplastics will aggregate and settle in estuarine and low-flow conditions such as those found in China's Poyang Lake.
On some physical and dynamical properties of microplastic particles in marine environment
This study examined the physical and dynamical properties of microplastic particles in marine environments, using modeling to predict how particle shape, density, and size govern transport, dispersion, and accumulation patterns.
Sedimentation behavior of aggregated microplastics: Influence of particle size and water constituents in environmental waters
Laboratory experiments investigated how aggregation of microplastics with sediments and organic matter affects their sinking rates in water, finding that aggregate composition strongly influences settling velocity. These findings improve models predicting whether microplastics sink to the seafloor or remain suspended in the water column.
Aggregation and Deposition Kinetics of Polystyrene Microplastics and Nanoplastics in Aquatic Environment
Researchers measured aggregation and deposition kinetics of 50 nm and 500 nm polystyrene particles under varying ionic strength and pH conditions, finding that both particle sizes aggregated rapidly at elevated salt concentrations and that the smaller nanoplastics were more mobile in column experiments.
Aggregation kinetics of microplastics in aquatic environment: Complex roles of electrolytes, pH, and natural organic matter
Researchers found that the aggregation behavior of polystyrene microplastics in water was strongly influenced by pH, ionic strength, and the presence of natural organic matter, with divalent cations like calcium and magnesium promoting aggregation. Understanding aggregation kinetics is critical for predicting how microplastics partition between suspended and settled states in natural water bodies.
Modelling the sedimentation of macro-, micro- and nanoplastics in the ocean from surface to sediment
Researchers modeled the sedimentation of macro-, micro-, and nanoplastics from the ocean surface to the seafloor, finding that biofouling and particle aggregation dramatically accelerate sinking rates and that most plastics eventually reach benthic environments.
Effects of size and surface charge on the sedimentation of nanoplastics in freshwater
Researchers investigated how size and surface charge of polystyrene nanoplastics affect their sedimentation behavior in freshwater, finding that both properties significantly influence aggregation dynamics and settling rates, with implications for predicting nanoplastic fate in aquatic environments.
New Insights into the Formation of Aggregates of Bidisperse Nano- and Microplastics in Water Based on the Analysis of In Situ Microscopy and Molecular Simulation
Researchers combined microscopy and molecular simulations to study how nano- and microplastic particles of different sizes clump together in water. They found that mixing particle sizes delays the onset of rapid aggregation but does not change the overall growth pattern. The findings help explain how plastic particles behave in salty water like oceans and wastewater, which is important for designing effective removal strategies.
Modeling the Fate and Transport of Plastic Debris in Freshwaters: Review and Guidance
Researchers reviewed current mathematical models for tracking how plastic debris — including microplastics and nanoplastics — moves through freshwater environments, finding that while many principles from existing particle models apply, plastic's unique combination of high persistence, low density, and extreme size range makes its behavior far more varied and complex to predict.