Dynamics of an oscillatory boundary layer over a sediment bed in Euler-Lagrange simulations

Abstract

We investigate the dynamics of an oscillatory boundary layer developing over a bed of collisional and freely evolving sediment grains. We perform Euler-Lagrange simulations at Reynolds numbers Reδ= 200, 400, and 800, density ratio p/f = 2.65, Galileo number Ga = 51.9, maximum Shields numbers from 5.60 × 10-2 to 2.43 × 10-1, based on smooth wall configuration, and Keulegan-Carpenter number from 134.5 to 538.0. We show that the dynamics of the oscillatory boundary layer and sediment bed are strongly coupled due to two mechanisms: (I) bed permeability, which leads to flow penetration deep inside the sediment layer, a slip velocity at the bed-fluid interface, and the expansion of the boundary layer, and (II) particle motion, which leads to rolling-grain ripples at Reδ = 400 and Reδ = 800. While at Reδ = 200 the sediment bed remains static during the entire cycle, the permeability of the bed-fluid interface causes a thickening of the boundary layer. With increasing Reδ, the particles become mobile, which leads to rolling-grain ripples at Reδ = 400 and suspended sediment at Reδ = 800. Due to their feedback force on the fluid, the mobile sediment particles cause greater velocity fluctuations in the fluid. Flow penetration causes a progressive alteration of the fluid velocity gradient near the bed interface, which reduces the Shields number based upon bed shear stress.

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