Numerical simulation of sand waves in a turbulent open channel flow

Khosronejad, Ali; Sotiropoulos, Fotis

doi:10.1017/jfm.2014.335

Cited by 103 publications

(76 citation statements)

References 108 publications

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“…It should be acknowledged that in the published article we (1) mistakenly used the same symbols for the dynamic viscosity of water and the molecular diffusion coefficient of the scalar, (2) neglected to include the value used for the molecular diffusion, and (3) did not mention that σ * is the reciprocal of the turbulent Schmidt number. Although these details should have been included, these omissions do not change well‐established facts that in turbulent flows the mixing of the solute by molecular diffusion is many orders of magnitude less important than that induced by turbulent eddies (Chawdhary et al, ; Chou & Fringer, ; Gualtieri et al, ; Gualtieri & Bombardelli, ; Khosronejad & Sotiropoulos, ; Scalo et al, ). As we mentioned in Khosronejad et al (), the viscous sublayer in Eagle Creek was not resolved in our simulations, as the first node away from the solid boundaries in wall units was (on average) equal to z + = 45 (see Table 3 in Khosronejad et al, ).…”

Section: Response To Criticism Of Misrepresentation Of Scalar Transportmentioning

confidence: 99%

Reply to Comment by Sookhak Lari, K. and Davis, G. B. on “ ‘Large Eddy Simulation of Turbulence and Solute Transport in a Forested Headwater Stream’: Invalid Representation of Scalar Transport by the Act of Diffusion”

Khosronejad

Sotiropoulos

2018

JGR Earth Surface

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Based on the molecular diffusion coefficient used in the large eddy simulation (LES) (equation (3) of the article), one can easily infer that a molecular Schmidt number of 700 was adopted for the solute. It should be acknowledged that in the published article we omitted to include the value used for the molecular diffusion and did not mention that is the reciprocal of the turbulent Schmidt number. Although these details should have been included, these omissions do not change well‐established facts that in turbulent flows the mixing of the solute by the molecular diffusion is many orders of magnitude less important than that induced by the turbulence. As we mentioned in our article, the viscous sublayer in the Eagle Creek stream was not resolved in our simulations as the first node off the solid boundaries in wall units was (on average) equal to 45 (see Table 3 of the article). This implies that all of the computational nodes are located well outside of the viscous sublayer, where molecular diffusion becomes dominant. Moreover, since we carry out LES, we do not resolve the Kolmogorov scales in the flow the rate of dissipation of which is governed by molecular viscosity. Rather, the subgrid scale eddy viscosity of the LES acts as the model for the effect of the unresolved scales of motion. Even though all these are well‐known facts from fundamental theory of turbulent mixing, we include in this response additional simulations to address the concerns raised in this commentary.

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Section: Response To Criticism Of Misrepresentation Of Scalar Transportmentioning

confidence: 99%

Reply to Comment by Sookhak Lari, K. and Davis, G. B. on “ ‘Large Eddy Simulation of Turbulence and Solute Transport in a Forested Headwater Stream’: Invalid Representation of Scalar Transport by the Act of Diffusion”

Khosronejad

Sotiropoulos

2018

JGR Earth Surface

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“…The volume fraction of conservative tracer ( ψ ) is modeled as a passive scalar whose transport is governed by the following convection‐diffusion equation [ Chou and Fringer , , ; Kraft et al , ; Khosronejad and Sotiropoulos , ]:

\frac{1}{J} \frac{\partial (ρψ)}{∂t} + \frac{\partial (ρ U^{j} ψ)}{\partial ξ^{j}} = \frac{\partial}{\partial ξ^{j}} ((), (μ + σ^{*} μ_{t}) \frac{G^{jk}}{J} \frac{∂ψ}{\partial ξ^{k}})

where σ ∗ is the Schmidt number (= 0.75) [ Khosronejad et al , ] and μ t is the eddy viscosity obtained from LES model [ Kang and Sotiropoulos , ].…”

Section: The Vsl3d Modelmentioning

confidence: 99%

“…The details of the numerical method for solving the flow, solute transport, and turbulence closure governing equations in complex domains have already been documented extensively elsewhere [ Ge and Sotiropoulos , ; Borazjani et al , ; Kang et al , ; Khosronejad and Sotiropoulos , ], and only a brief summary of key elements of the method will be given here. The governing equations for resolved flow field are discretized in space on a hybrid staggered/nonstaggered grid arrangement [ Gilmanov and Sotiropoulos , ; Ge and Sotiropoulos , ] using second‐order accurate central differencing for the convective terms along with second‐order accurate, three‐point central differencing for the divergence, pressure gradient, and viscous‐like terms.…”

Section: The Vsl3d Modelmentioning

confidence: 99%

“…In another study VSL3D was employed to underscore the limitations of isotropic RANS models for resolving the structure of secondary flows in natural bends and demonstrate the need for LES. More recently, the VSL3D has been further extended to incorporate free surface effects [ Kang and Sotiropoulos , ] and also develop a coupled hydrodynamic formulation for simulating sand wave dynamics across a range of scales [ Khosronejad et al , , ; Khosronejad and Sotiropoulos , ].…”

Section: Introductionmentioning

confidence: 99%

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Large eddy simulation of turbulence and solute transport in a forested headwater stream

et al. 2016

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The large eddy simulation (LES) module of the Virtual StreamLab (VSL3D) model is applied to simulate the flow and transport of a conservative tracer in a headwater stream in Minnesota, located in the south Twin Cities metropolitan area. The detailed geometry of the stream reach, which is ∼135 m long, ∼2.5 m wide, and ∼0.15 m deep, was surveyed and used as input to the computational model. The detailed geometry and location of large woody debris and bed roughness elements up to ∼0.1 m in size were also surveyed and incorporated in the numerical simulation using the Curvilinear Immersed Boundary approach employed in VSL3D. The resolution of the simulation, which employs up to a total of 25 million grid nodes to discretize the flow domain, is sufficiently fine to directly account for the effect of large woody debris and small cobbles (on the streambed) on the flow patterns and transport processes of conservative solutes. Two tracer injection conditions, a pulse and a plateau release, and two cross sections of measured velocity were used to validate the LES results. The computed results are shown to be in good agreement with the field measurements and tracer concentration time series. To our knowledge, the present study is the first attempt to simulate via high-resolution LES solute transport in a natural stream environment taking into account a range of roughness length scales spanning an order of magnitude: from small cobbles on the streambed (∼0.1 m in diameter) to large woody debris up to ∼3 m long.

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“…Numerical models have been used to simulate the interaction of bedforms and hydrodynamics (El Kheiashy et al, ; Khosronejad & Sotiropoulos, ; Lefebvre, Paarlberg, & Winter, ; Omidyeganeh & Piomelli, ; Stoesser et al, ). They compensate for limitations in field and flume measurements as they allow simulations of high‐resolution near‐bed flow fields, provide estimate of turbulence, and can be used with a variety of boundary conditions.…”

Section: Introductionmentioning

confidence: 99%

Three‐Dimensional Flow Above River Bedforms: Insights From Numerical Modeling of a Natural Dune Field (Río Paraná, Argentina)

Lefebvre

2019

JGR Earth Surface

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Bedforms are ubiquitous features in rivers and shallow seas, as mobile sediment is transported by flowing water. The mutual interaction of hydrodynamics and bedform has been widely studied in the laboratory over two‐dimensional bedforms having an angle‐of‐repose (30°) lee side and a relatively simple shape. However, the influence of bedform natural morphology and three‐dimensionality on the flow is still poorly constrained. The present work looks at how a natural three‐dimensional (3‐D) bedform field influences flow properties through high‐resolution numerical modeling. A 3‐D numerical model is set up with Delft3D and verified against lab experiments of idealized 3‐D bedforms. The model is used to simulate water velocities, turbulence, water levels, and bed shear stress above a natural bedform field from the Río Paraná (Argentina). The presence and size of the flow separation zone and turbulent wake depend on the presence and properties of the slip face (defined here as the portion of the lee side with angles >15°) and not on those of the crest. When present, the flow separation and wake lengths are, for the tested settings, respectively, around 5 and 13 times the slip face height. A slip face orientation of 25° or more compared to the flow increases cross‐stream flow and suppresses flow reversal over the slip face. To understand and predict flow and bedform properties, the slip face rather than the crest position should be identified and analyzed.

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Numerical simulation of sand waves in a turbulent open channel flow

Cited by 103 publications

References 108 publications

Reply to Comment by Sookhak Lari, K. and Davis, G. B. on “ ‘Large Eddy Simulation of Turbulence and Solute Transport in a Forested Headwater Stream’: Invalid Representation of Scalar Transport by the Act of Diffusion”

Reply to Comment by Sookhak Lari, K. and Davis, G. B. on “ ‘Large Eddy Simulation of Turbulence and Solute Transport in a Forested Headwater Stream’: Invalid Representation of Scalar Transport by the Act of Diffusion”

Large eddy simulation of turbulence and solute transport in a forested headwater stream

Three‐Dimensional Flow Above River Bedforms: Insights From Numerical Modeling of a Natural Dune Field (Río Paraná, Argentina)

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