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61,005 resultsShowing papers similar to Horizontal Dispersion of Buoyant Materials in the Ocean Surface Boundary Layer
ClearMixing and transport of materials in the Ocean Surface Boundary Layer
This doctoral thesis investigated turbulence and mixing processes in the ocean surface boundary layer and how they affect the transport of materials including microplastics, oil, and nutrients. The research develops mathematical models to better understand how plastic particles disperse near the ocean surface, which is important for predicting the fate of marine plastic pollution.
Dispersion of buoyant Lagrangian particles in the wave-driven ocean surface boundary layer
This computational study used large eddy simulations to model how buoyant particles — including plastics, oil, and biological material — disperse within the ocean surface boundary layer under different wave and turbulence conditions. The results showed that Langmuir turbulence (driven by wave-current interactions) is especially effective at submerging buoyant particles and influencing their horizontal spread, while highly buoyant particles can become trapped at the surface under certain conditions. The findings are directly relevant to modeling how microplastics distribute across the ocean surface and how long they remain accessible to marine organisms that feed near the surface.
Microplastics segregation by rise velocity at the ocean surface
This study modeled the competing forces of particle buoyancy and turbulent mixing that control the vertical distribution of microplastics in the ocean surface layer, finding that particle rise velocity is the key variable that segregates plastic types and determines how they distribute relative to surface and subsurface measurements.
The effect of wind mixing on the vertical distribution of buoyant plastic debris
Researchers modeled and measured how wind mixing affects the vertical distribution of buoyant plastic debris in the ocean, finding that turbulent mixing drives plastics below the surface and explains why surface sampling underestimates total plastic concentrations.
Empirical Lagrangian parametrization for wind-driven mixing of buoyant particles at the ocean surface
This study developed simplified mathematical models for how wind-driven turbulence mixes buoyant particles — including microplastics — in the ocean surface layer. Better parameterizations of near-surface mixing are important for predicting where floating microplastics concentrate and how they eventually sink.
Numerical analysis of boundary conditions in a Lagrangian particle model for vertical mixing, transport and surfacing of buoyant particles in the water column
This technical modeling paper examines how to accurately simulate the behavior of buoyant particles (like microplastics) rising to the ocean surface in computer models. Improving these simulations helps predict where floating microplastics will accumulate in the ocean.
Passive buoyant tracers in the ocean surface boundary layer: 2. Observations and simulations of microplastic marine debris
Using ocean computer models calibrated against real-world observations, this study showed how wave mixing and other physical processes push buoyant microplastics below the ocean surface, explaining why less plastic is detected at the surface than expected. These models are critical for estimating where microplastic pollution is truly accumulating in the ocean.
Modeling the trajectories of floating and non-floating microplastic particles in the water column
Researchers modeled the trajectories of both floating and non-floating microplastic particles in freshwater and marine water columns, accounting for turbulence-induced mixing, buoyancy differences, and flow characteristics that determine vertical and horizontal distribution. The study highlights that while low-density polymers like polyethylene and polypropylene are expected to concentrate at the surface, turbulent mixing drives significant depth distribution across aquatic environments.
Particle dispersion and clustering in surface ocean turbulence with ageostrophic dynamics
This paper is not directly about microplastics; it uses numerical ocean simulations to model how small-scale turbulence and ageostrophic dynamics affect the clustering and dispersion of floating particles at the ocean surface, with relevance to understanding how marine debris concentrates in convergence zones.
Large eddy simulations of the accumulation of buoyant material in oceanic wind-driven and convective turbulence
Researchers used large eddy simulations to show that buoyant materials like microplastics accumulate at specific ocean surface zones driven by convergent currents under both wind-driven and convective turbulence, improving understanding of how plastics concentrate at the sea surface.
Modeling of vertical microplastic transport by rising bubbles
This study modeled the vertical transport of microplastic particles by rising bubbles in the ocean, finding that bubble-mediated transport significantly enhances surface concentration of microplastics and helps explain why surface measurements often show higher particle densities than bulk water predictions suggest.
Passive buoyant tracers in the ocean surface boundary layer: 1. Influence of equilibrium wind‐waves on vertical distributions
Using large eddy simulations, this paper modeled how wind-driven waves affect the vertical distribution of buoyant particles near the ocean surface, providing the physical framework for the companion paper on microplastic debris distribution. The models explain why floating microplastics are often mixed down below the surface, reducing the concentrations observed in surface sampling.
Influence of Near‐Surface Currents on the Global Dispersal of Marine Microplastic
An ocean circulation model incorporating biological and physical processes found that near-surface currents, including wind-driven surface drift and wave-induced mixing, play a major role in dispersing buoyant microplastics globally, with plastic accumulating preferentially in subtropical convergence zones. The model improves understanding of how ocean physics shapes global microplastic distribution patterns.
Vertical transport of buoyant microplastic particles in the ocean: The role of turbulence and biofouling
Researchers modeled how turbulence and biofouling interact to determine the vertical movement of buoyant microplastic particles in the ocean. They identified three distinct flow regimes that govern whether microplastics stay at the surface, oscillate, or sink to the seafloor. The study helps explain the observation that even low-density microplastics are found in deep ocean sediments, suggesting biofouling-driven density changes are a key transport mechanism.
Physical transport properties of marine microplastic pollution
Researchers reviewed the physical transport properties of marine microplastics — including buoyancy, settling velocity, and biofouling effects — and developed models predicting the dispersal of both pelagic and benthic plastic pollution from land-based sources across different ocean regions. The study highlights how hydrodynamic behavior varies by polymer type and particle size, leading to differential accumulation patterns in surface waters, the water column, and seafloor sediments.
Non-breaking Wave Effects on Buoyant Particle Distributions
This study used wave-resolving simulations to examine how surface gravity waves affect the distribution of buoyant microplastic particles in the ocean mixed layer. The findings show that wave dynamics create concentration patterns near the surface that are missed by models that do not resolve individual wave phases.
The effect of particle properties on the depth profile of buoyant plastics in the ocean
Using sampling at multiple depths from 0 to 5 meters in the North Atlantic subtropical gyre, researchers measured how turbulent mixing redistributes buoyant microplastics below the ocean surface. The results show that surface net sampling alone significantly underestimates total microplastic concentrations, particularly in windy conditions.
Influence of waves on the three-dimensional distribution of plastic in the ocean
Researchers modeled the trajectories of microplastic particles released continuously from coastal sources across realistic ocean simulations to understand how wave dynamics and ocean circulation distribute plastic pollution globally. The model showed that wave-driven mixing significantly influences vertical plastic distribution, not just horizontal surface drift. Including wave effects improves predictions of where ocean microplastics accumulate.
On Clustering of Floating Tracers in Random Velocity Fields
This mathematical modeling study explores how floating particles — including microplastics — cluster into dense patches on the ocean surface under turbulent currents, finding that realistic time-correlated ocean flows produce clusters far faster than simpler models predict. Understanding this clustering behavior is important for accurately assessing where microplastic pollution concentrates in the ocean and how organisms encounter it at ecologically meaningful densities.
Lagrangian Investigation of Wave-Driven Turbulence in the Ocean Surface Boundary Layer
This study used Lagrangian particle tracking within large-eddy simulations to analyze wave-driven turbulence in the ocean surface boundary layer. Ocean surface turbulence directly controls how microplastics are mixed, accumulated, and transported in the uppermost layer of the ocean.
Sinking microplastics in the water column: simulations in the Mediterranean Sea
Researchers simulated the vertical dispersion and distribution of negatively buoyant microplastics in the Mediterranean Sea using a realistic circulation model, evaluating how inertia, Coriolis force, turbulence, and variable seawater density affect sinking trajectories and accumulation zones.
The Fluid Mechanics of Ocean Microplastics
This review examined the fluid mechanics governing microplastic transport in marine environments, covering buoyancy, Stokes drift, turbulence, and biofouling effects across scales from surface films to deep-sea accumulation zones. The authors identified key knowledge gaps in predicting vertical transport and small-scale aggregation processes.
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.
Fluid dynamics challenges in predicting plastic pollution transport in the ocean: A perspective
This perspective reviewed fluid dynamics challenges in predicting microplastic transport in oceans, highlighting unsolved problems in modeling inertial particles in waves and turbulence, particle transformation, and the influence of submesoscale ocean processes.