| Presenter | Title of presentation | Files | Abstract |
| V.V.Babenko | Phenomenon of vortex self-organisation in layers with obstruction. | Not Available | here |
| A.A.Baklanov | Modelling of urban air flows with application to air pollution, emergency preparedness and weather prediction. | here | here |
| J.J.Finnigan | Turbulent flow in canopies on complex topography and the effects of stable stratification | here | here |
| Ye.A.Gayev | Easily penetrable roughness flows in nature and in engineering | here | here |
| J.C.R.Hunt | Discrete and continuum models of flow and dispersion through canopies. | Not Available | here |
| R.Meroney | Fires in porous media: natural and urban canopies [Please note that some of these files are very large.] | here | here |
| H.Nepf | Transport in aquatic canopies. | here | here |
| R.Shaw | Observation and simulation of flow in vegetation canopies. | here | here |
| Presenter | Title of presentation | Files | Abstract |
| J.H.Amorim | Air pollutants dispersion disturbance due to urban vegetation. | here | here |
| D.A.Belikov | The computational investigation of the influence of weather conditions on ozone formation in urban atmosphere. | here | here |
| R.Bornstein | History of numerical urban boundary-layer simulation techniques. | here | here |
| O.Coceal | Turbulent flow over groups of urban-like obstacles. | here | here |
| I.Ekmekci | Experimental and numerical investigation of wind loads on roofs of various geometries. | here | here |
| E.Ya.Epik | The physical modelling of flows after moving obstructions. | here | here |
| J.J.Finnigan | (1) Turbulent fine structure and spectra in canopies (2) Large eddy structure and low dimensional modelling of canopy turbulence. | here | (1) (2) |
| K.Fortuniak | Slab surface energy balance scheme and its application to parameterisation of the energy fluxes on urban areas. | here | here |
| Ye.A.Gayev | (1) Analysis of flows through vegetated beds (2) Mathematical modelling of convection plume over an infinite-length porous source of heat and moisture (3) Viscous flow through a duct with easily penetrable roughness modelled by Navier-Stokes equations (4) LES of turbulent boundary layer flow within and above an easily penetrable roughness. | here | (1) (2) (3) (4) |
| B.P.Golovnya | Simulation of shear flow in channels with canopies. | here | here |
| V.O.Gorban | Interaction of near-wall flow with a square prism. | here | here |
| E.vanGorsel | Aspects of canopy flow in steep terrain. | here | here |
| H.Hiraoka | Modelling a microclimate within vegetation. | here | here |
| M.T.Hussainov | An experimental study of effect of particles on turbulence of gas in a gas-solid particles flow. | here | here |
| F.B.Kaplanski | Transport processes in an oscillating vortex pair and ring. | here | here |
| I.Kovalets | Advanced meteorological pre-processing for the real-time emergency response systems dealing with the atmospheric dispersion in complex terrain. | here | here |
| P.I.Kudinov | Numerical simulation of air pollution transfer in urban areas. | here | here |
| A.F.Kurbatskii | Modelling and simulation of turbulent penetrative convection and pollutant dispersion above the urban heat island in stably stratified environment. | here | here |
| H.Lauerbach J. Eichhorn | Flow through deciduous tree crowns: comparison of measurements and high resolution numerical modelling. | here | here |
| R.Meroney | Fluids that whirl. [Please note that some of these files are very large.] | here | |
| M.Milliez | Detailed numerical modelling of local atmospheric dispersion in an idealized urban area. | here | here |
| A.Mochida | Optimization of tree canopy model for CFD application to local area wind energy prediction. | here | here |
| V.Munteanu | The role of convective diffusion on absorption of Hg(II), Cu(II), Pb(II), Cd(II) by submerged aquatic vegetation from Dubasari reservoir of the Dniester river. | here | here |
| H.Nakayama | LES analysis on fluctuating dispersion in actual urban canopy. | here | here |
| Yu.P.Nekrasov | Investigation of local statistical characteristics ot turbulent wind flow in atmospheric boundary layer with obstacles. | here | here |
| V.I.Nochvai | Surface ozone modelling with wind field and orography in Kyiv. | here | here |
| D.Pokrajac | Interpretation of PIV measurements of open channel flow over rough bed using double-averaged Navier-Stokes equations. | here | here |
| A.A.Prykhodko | Mathematical modelling of vertically-axis wind turbine work on the basis of Navier-Stokes equations. | here | here |
| A.N.Ryabinin | Boundary layer with saltating particles. | here | here |
| E.Savory | (1) Solar-induced thermal effects on the flow in a street canyon (2) Physical modelling of concentration fluctuations in simple obstacle arrays. | here | (2) |
| I.Selezov | Water wave transformation due to bottom obstacles. | here | here |
| U.Shavit | (1) Dispersion within emergent vegetation using PIV and concentration measurements (2) Theoretical, numerical and experimental study of the macroscopic velocity profile near permeable interfaces. | here | (1) (2) |
| Ye.A.Shkvar | Modelling of multiphase flows over surface with penetrable rough relief. | here | here |
| N.N.Smirnov | Multi-phase fluids underground filtration: manifestation of capillary effects and flow instability. | Not Available | here |
| A.Sogachev | Modelling of airflow over complex natural landscapes for experimental data interpretation in environmental research. | here | here |
| A.V.Starchenko | (1) A numerical simulation of air flow in urban obstructions (2) A numerical simulation of wind field and air quality above industrial center. | here | (1) (2) |
| K.Bal E.Struyf | Top-bottom investigation of water and nutrient fluxes to the coastal zone through a lowland river basin. | here | here |