IUTAM Symposium on Asymptotic Methods for Turbulent Shear Flows at High Reynolds Numbers

Session 1.- Different approaches to asymptotic expansions in turbulent boundary layers (Invited lecture).- Turbulent Poiseuille channel flow interpreted by composite expansions.- A high Reynolds number analysis of turbulent heat transfer in the entrance region of a pipe or channel.- Asymptotic analysis of turbulent flow for a rotating cylinder.- Session 2.- Asymptotics for turbulent shear flows: A survey of some French contributions (Invited lecture).- Application of the defect formulation to the incompressible turbulent boundary layer.- Axisymmetric turbulent sink flows.- Wake layer in a turbulent boundary layer with pressure gradient: a new approach (Invited lecture).- Session 3.- Recent advances in wall-bounded shear flows. Survey of contributions from the USA (Invited lecture).- Asymptotic and computational results for a turbulent jet impinging on a nearby wall.- Asymptotic analysis of fully turbulent flows in slender convergent and divergent channels.- Heat and momentum transfer in turbulent boundary layers in the presence of strong adverse pressure gradients.- Similarity of turbulent shear flows: The natural convection boundary layer next to heated vertical surfaces.- Section 4.- Asympotic methods in turbulent combustion (Invited lecture).- Asymptotic study of turbulent swirling jets.- Longitudinal vortex embedded in turbulent Couette flow.- Section 5.- Progress in computation of rapid distortion of turbulent flows (Invited lecture).- Structure of a confined turbulent wake under shear and irrotational strain.- A theoretical model for nonlinear spots.- Intermittency of turbulence and the scaling hypothesis.- Analytical and numerical multiscale calculations for eddy viscosity.- Section 6.- Asymptotic stability of turbulent swirling jets fanning out along a plate.- Lagrangian direct-interaction approximation for homogeneous isotropic turbulence.- Generalised multiple expansion for the jet problem.- Back of the envelope analysis of turbulence models.