Litcius/Paper detail

Reduced Sediment Settling in Turbulent Flows Due To Basset History and Virtual Mass Effects

Shuolin Li, Andrew D. Bragg, Gabriel G. Katul

2023Geophysical Research Letters15 citationsDOIOpen Access PDF

Abstract

Abstract The behavior of suspended particles in turbulent flows is a recalcitrant problem spanning wide‐ranging fields including geomorphology, hydrology, and dispersion of particulate matter in the atmosphere. One key mechanism underlying particle suspension is the difference between particle settling velocity ( w s ) in turbulence and its still water counterpart ( w so ). This difference is explored here for a range of particle‐to‐fluid densities (1–10) and particle diameter to Kolmogorov micro‐eddy sizes (0.1–10). Conventional models of particle fluxes that equate w s to w so result in eddy diffusivities and turbulent Schmidt numbers contradictory to laboratory experiments. Incorporating virtual mass and Basset history forces resolves these inconsistencies, providing clarity as to why w s / w so is sub‐unity for the aforementioned conditions. The proposed formulation can be imminently used to model particle settling in turbulence, especially when sediment distribution outcomes over extended time scales far surpassing turbulence time scales are sought.

Topics & Concepts

SettlingTurbulenceSuspension (topology)Particle (ecology)MechanicsPhysicsRange (aeronautics)SedimentDispersion (optics)GeologyGeomorphologyMaterials scienceOceanographyThermodynamicsOpticsMathematicsPure mathematicsComposite materialHomotopyParticle Dynamics in Fluid FlowsAeolian processes and effectsHydrology and Sediment Transport Processes