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Journal of Turbulence Volume 5, 2004 - Issue
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Miscellany

Large-eddy simulation of dispersion: comparison between elevated and ground‐level sources

Zhengtong Xie 1
,
Paul Hayden
,
Peter R. Voke
&
Alan G. Robins
Article: N31 | Received 21 Nov 2003, Accepted 26 Aug 2004, Published online: 24 Jan 2011

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C. Le Ribault, S. Simoëns & I. Vinkovic. (2012) HYBRID LARGE EDDY SIMULATION/LAGRANGIAN STOCHASTIC MODEL FOR TURBULENT PASSIVE AND REACTIVE SCALAR DISPERSION IN A PLANE JET. Chemical Engineering Communications 199:4, pages 435-460.
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IVANA VINKOVIC, CESAR AGUIRRE & SERGE SIMOËNS. (2006) Large-eddy simulation and Lagrangian stochastic modeling of passive scalar dispersion in a turbulent boundary layer. Journal of Turbulence 7.
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Articles from other publishers (18)

A.L.V. Melo, J.M. Santos, N.C. ReisJr.Jr., I.P. Castro, E. V Goulart & Z.T. Xie. (2023) Influence of wind direction and source location on peak-to-mean concentration ratios in urban environments. Journal of Wind Engineering and Industrial Aerodynamics 232, pages 105264.
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Chao Lin, Ryozo Ooka & Hideki Kikumoto. (2022) Reynolds-averaged Eulerian simulation of elevated source pollutant dispersion in turbulent boundary layer using concentration diffusivity limiter. Journal of Wind Engineering and Industrial Aerodynamics 220, pages 104876.
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Marlon Brancher, Alexander Hieden, Kathrin Baumann-Stanzer, Günther Schauberger & Martin Piringer. (2020) Performance evaluation of approaches to predict sub-hourly peak odour concentrations. Atmospheric Environment: X 7, pages 100076.
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J. M. Santos, N. C. ReisJr.Jr., I. P. Castro, E. V. Goulart & Z. T. Xie. (2019) Using Large-Eddy Simulation and Wind-Tunnel Data to Investigate Peak-to-Mean Concentration Ratios in an Urban Environment. Boundary-Layer Meteorology 172:3, pages 333-350.
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Nils Mole & Rick Munro. (2019) The Spatial Variation of the Maximum Possible Contaminant Concentration From a Steady Line Source. Boundary-Layer Meteorology 172:1, pages 67-80.
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Jan Burman, Lage Jonsson & Anna Rutgersson. (2018) On possibilities to estimate local concentration variations with CFD-LES in real urban environments. Environmental Fluid Mechanics 19:3, pages 719-750.
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E.V. Goulart, N.C. ReisJr.Jr., V.F. Lavor, Ian.P. Castro, J.M. Santos & Z.T. Xie. (2019) Local and non-local effects of building arrangements on pollutant fluxes within the urban canopy. Building and Environment 147, pages 23-34.
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Shahin N. Oskouie, Zixuan Yang & Bing-Chen Wang. (2018) Study of passive plume mixing due to two line source emission in isotropic turbulence. Physics of Fluids 30:7.
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Massimo Marro, Pietro Salizzoni, Lionel Soulhac & Massimo Cassiani. (2018) Dispersion of a Passive Scalar Fluctuating Plume in a Turbulent Boundary Layer. Part III: Stochastic Modelling. Boundary-Layer Meteorology 167:3, pages 349-369.
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Shahin N. Oskouie, Bing-Chen Wang & Eugene Yee. (2015) Study of the interference of plumes released from two near-ground point sources in an open channel. International Journal of Heat and Fluid Flow 55, pages 9-25.
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H. Nakayama, K. Jurcakova & H. Nagai. (2013) Large-Eddy Simulation of plume dispersion within various actual urban areas. Advances in Science and Research 10:1, pages 33-41.
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S.E. Gant & A. Kelsey. (2012) Accounting for the effect of concentration fluctuations on toxic load for gaseous releases of carbon dioxide. Journal of Loss Prevention in the Process Industries 25:1, pages 52-59.
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Marcelo Chamecki, Charles Meneveau & Marc B. Parlange. (2009) Large eddy simulation of pollen transport in the atmospheric boundary layer. Journal of Aerosol Science 40:3, pages 241-255.
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Cesar Aguirre, Armando B. Brizuela, Ivana Vinkovic & Serge Simoëns. (2006) A subgrid Lagrangian stochastic model for turbulent passive and reactive scalar dispersion. International Journal of Heat and Fluid Flow 27:4, pages 627-635.
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I. Vinkovic, C. Aguirre, S. Simoëns & M. Gorokhovski. (2006) Large eddy simulation of droplet dispersion for inhomogeneous turbulent wall flow. International Journal of Multiphase Flow 32:3, pages 344-364.
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Zhengtong Xie & Jiachun Li. (2006) A Numerical Study for Turbulent Flow and Thermal Influence over Inhomogenous Canopy of Roughness Elements. Environmental Fluid Mechanics 5:6, pages 577-597.
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Ivana Vinkovic, Cesar Aguirre, Serge Simoëns & Jean-Noël Gence. (2005) Couplage d'un modèle stochastique lagrangien sous-maille avec une simulation grandes échelles. Comptes Rendus Mécanique 333:4, pages 325-330.
Crossref
I. Vinkovic, C. Aguirre & S. Simoëns. 2005. Engineering Turbulence Modelling and Experiments 6. Engineering Turbulence Modelling and Experiments 6 969 978 .

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