Evaluation of turbulence closure models under spilling and plunging breakers in the surf zone

Brown, Scott; Greaves, Deborah; Magar, Vanesa; Conley, Daniel

doi:10.1016/j.coastaleng.2016.04.002

Cited by 92 publications

(123 citation statements)

References 31 publications

(78 reference statements)

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“…[2012] and Brown et al [2016], the aspect ratio of Dx and Dz should be close to 1 in order to prevent unreasonable large VOF flux in the x direction, which may lead to artificial steepening of the wave front and Journal of Geophysical Research: Oceans 10.1002/2016JC011884 premature wave breaking. Due to the sloping beach of the wave flume (see Figure 1a), the vertical grid size Dz reduces in the positive x direction.…”

Section: Model Validationmentioning

confidence: 99%

Large‐eddy simulation of wave‐breaking induced turbulent coherent structures and suspended sediment transport on a barred beach

et al. 2017

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To understand the interaction between wave‐breaking induced turbulent coherent structures and suspended sediment transport, we report a Large‐Eddy Simulation (LES) study of wave‐breaking processes over a near‐prototype scale barred beach. The numerical model is implemented using the open‐source CFD toolbox, OpenFOAM®, in which the incompressible three‐dimensional filtered Navier‐Stokes equations for the water and air phases are solved with a finite volume scheme. A volume of fluid (VOF) method is used to capture the evolution of the water‐air interface. The numerical model is validated with measured free surface elevation, turbulence‐averaged flow velocity, turbulent intensity, and for the first time, the intermittency of breaking wave turbulence. Simulation results confirm that as the obliquely descending eddies (ODEs) approach the bottom, significant bottom shear stress is generated. Remarkably, the collapse of ODEs onto the bed can also cause drastic spatial and temporal changes of dynamic pressure on the bottom. By allowing sediment to be suspended from the bar crest, intermittently high sediment suspension events and their correlation with high turbulence and/or high bottom shear stress events are investigated. The simulated intermittency of sediment suspension is similar to previous field and large wave flume observations. Coherent suspension events account for only 10% of the record but account for about 50% of the sediment load. Model results suggest that about 60%∼70% of coherent bottom stress events are associated with surface‐generated turbulence. Nearly all the coherent sand suspension events are associated with coherent turbulence events due to wave‐breaking turbulence approaching the bed.

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Section: Model Validationmentioning

confidence: 99%

Large‐eddy simulation of wave‐breaking induced turbulent coherent structures and suspended sediment transport on a barred beach

et al. 2017

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“…The latter is also required when incorporating TKE effects into reference concentration models. However, an appropriate quantitative description of surf zone TKE is not trivial for present turbulence closure models (Brown et al, 2016). Thirdly, wave breaking leads to large local deformations of the wave shape, which are especially important in terms of bedload-driven bed level changes around the breaker bar.…”

Section: Discussionmentioning

confidence: 99%

Suspended and Bedload Transport in the Surf Zone: Implications for Sand Transport Models

Zanden

O’Donoghue

et al. 2017

Int. Conf. Coastal. Eng.

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This paper presents results obtained during a large-scale wave flume experiment focused at measuring hydrodynamics and sediment transport processes in the wave breaking region. The experiment involved monochromatic plunging breaking waves over a mobile bed barred profile consisting of D 50 = 0.24 mm sand. Vertical profiles of velocity, turbulence, sand concentration and sand fluxes were measured at 12 cross-shore locations, covering the shoaling region up to the inner surf zone. Particularly high-resolution profiles were obtained near the bed within the wave bottom boundary layer, using an acoustic sediment concentration and velocity profiler (ACVP). Sheet flow concentration and particle velocities were measured at two locations near the bar crest using two conductivity-based concentration measurement tanks (CCM+). Total transport rates, obtained from the evolving bed profile measurements, were decomposed into suspended and bedload transport contributions across the bar. The present paper presents a summary of the key findings of the experiment, which are used to discuss existing approaches for modeling suspended and bed load transport in the surf zone.

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“…Although such models have already been proposed (e.g. Steetzel, 1993), it should be noted that it is not trivial to quantify near bed TKE using existing turbulence closure models (Brown et al, 2016). An alternative is a C0 model that is based on breaking wave characteristics such as the relative wave height (Mocke and Smith, 1992) or wave energy dissipation due to breaking (Kobayashi and Johnson, 2001).…”

Section: Discussionmentioning

confidence: 99%

“…intra wave time scale) and for a range of turbulence models, i.e. k (Lin and Liu, 1998;Brown et al, 2016), k (Brown et al, 2016), or, more advanced, large eddy simulation (Christensen, 2006). Further improvement of turbulence closure models seems essential if near bed TKE is used as input for sediment entrainment or bedload transport.…”

Section: Turbulence In Breaking Zonementioning

confidence: 99%

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Sand transport processes in the surf and swash zones

Zanden¹

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Evaluation of turbulence closure models under spilling and plunging breakers in the surf zone

Cited by 92 publications

References 31 publications

Large‐eddy simulation of wave‐breaking induced turbulent coherent structures and suspended sediment transport on a barred beach

Large‐eddy simulation of wave‐breaking induced turbulent coherent structures and suspended sediment transport on a barred beach

Suspended and Bedload Transport in the Surf Zone: Implications for Sand Transport Models

Sand transport processes in the surf and swash zones

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