Evolution of thermally stratified turbulent open channel flow after removal of the heat source

Kirkpatrick, M.P.; Williamson, N.; Armfield, S.W.; Zecevic, Vanja

doi:10.1017/jfm.2019.543

Cited by 17 publications

(30 citation statements)

References 50 publications

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“…Thus Ri f = Ri f ( L O , L S , L ρ ), and the DNS results of Kirkpatrick et al. (2019) are entirely consistent with Equation . As argued by Ivey et al.…”

Section: Mixing Mechanismssupporting

confidence: 83%

Roles of Shear and Convection in Driving Mixing in the Ocean

Ivey

Bluteau

Gayen

et al. 2021

Geophysical Research Letters

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Using field, numerical, and laboratory studies, we consider the roles of both shear and convection in driving mixing in the interior of the density‐stratified ocean. Shear mixing dominates when the Richardson number Ri < 0.25, convective mixing dominates when Ri > 1.0, and in the intermediate regime when 0.25 < Ri < 1.0 both shear and convection can contribute to mixing. For pure shear mixing the mixing efficiency Rif approaches 0.5, while for pure convective mixing the mixing efficiency Rif approaches 0.75. The diapycnal diffusivities for the two mechanisms are given by very different expressions. Despite these complexities, a simple mixing length model using the mean flow shear S provides robust estimates of diffusivity across the range 0 < Ri < 2. To account for the roles of both shear and convection over this range of Ri, we also formulate a modified version of the empirical KPP model for parameterizing ocean mixing in numerical models.

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“…Thus Ri f = Ri f ( L O , L S , L ρ ), and the DNS results of Kirkpatrick et al. (2019) are entirely consistent with Equation . As argued by Ivey et al.…”

Section: Mixing Mechanismssupporting

confidence: 83%

Roles of Shear and Convection in Driving Mixing in the Ocean

Ivey

Bluteau

Gayen

et al. 2021

Geophysical Research Letters

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“…We have presented a study of destratification of thermally stratified turbulent open-channel flow after the imposition of surface cooling. This study builds on our previous studies of the equilibrium state due to radiative heating (Williamson et al 2015) and the response of this system to removal of the heat source (Kirkpatrick et al 2019).…”

Section: Discussionmentioning

confidence: 99%

“…In a previous study, (Kirkpatrick et al 2019, henceforth KWAZ) we investigated the transient evolution of this flow when the solar heat source is removed and the flow allowed to evolve in time with no heat flux through the upper or lower boundaries. This model represents the situation in which solar forcing stops, due for example to an increase in cloud cover, while atmospheric conditions are such that surface heat fluxes are small.…”

Section: Introductionmentioning

confidence: 99%

Destratification of thermally stratified turbulent open-channel flow by surface cooling

et al. 2020

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“…The Reynolds number Re τ = u τ H/ν = 180 and the non-dimensional buoyancy coefficient λ = 0.5. All variables are non-dimensionalised in terms of channel depth H, average friction velocity on the bottom surface and sidewalls u τ and a temperature scale based on the radiative heat flux (see [12] for details. )…”

Section: Mathematical Formulationmentioning

confidence: 99%

“…The simulation was performed using the PUFFIN code [10]. The code has been validated for turbulent stratified flows against experimental data [11] and against other published correlations and scaling relationships [12]. The grid cell sizes in viscous wall units are n + 0 = 2.9 in the channel centreline, and n + 0 = 0.4 near the walls.…”

Section: Mathematical Formulationmentioning

confidence: 99%

The Influence of Sharp Meanders on Thermally Stratified Open Channel Flow

Nguyen¹,

Kirkpatrick²

2020

Australasian Fluid Mechanics Conference (AFMC)

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In this study, direct numerical simulation (DNS) results for turbulent stratified open channel flow through an idealized meander with an internal heat source that models radiative heating from above are used to investigate the effect of bends on the degree of stratification and the mechanism by which the turbulence kinetic energy is produced and redistributed along the channel centreline. The pronounced local increase of TKE gains strength in the area entering halfway in the bend where a local extremum of TKE is found near the outer bank. The curve is sharp with the ratio of minimum radius of curvature to depth R min /B = 1.67, the maximum deviation angle of θ 0 = 110 • with the ratio of width over depth B/H = 10, the meander wavelength to depth λ/H = 11, and the friction Reynolds number Re τ = 180. We find that there is an explosion of turbulence at the location of 35% of the distance along the channel centreline which gradually weakens in the downstream part of the bend. Possible causes of this feature are discussed.

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Evolution of thermally stratified turbulent open channel flow after removal of the heat source

Cited by 17 publications

References 50 publications

Roles of Shear and Convection in Driving Mixing in the Ocean

Roles of Shear and Convection in Driving Mixing in the Ocean

Destratification of thermally stratified turbulent open-channel flow by surface cooling

The Influence of Sharp Meanders on Thermally Stratified Open Channel Flow

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