The effect of Reynolds and Mach number variation in compressible isothermal channel flow is investi- gated through a series of direct numerical simulations (DNS), at bulk Mach number M b = 1.5, 3 and bulk Reynolds number up to Re b = 34000, which is sufficient to sense sizeable high-Reynolds-number effects not reached before in this type of flow. Dedicated incompressible DNS are also performed at precisely matching Reynolds number, to directly gauge the performance of compressibility transformations for the mean velocity profiles and Reynolds stresses. As in previous studies, we find inaccuracy of the classical van Driest transformation to remove effects of variable density and viscosity, especially at low Reynolds number. On the oth...
We study compressible turbulent flow in a circular pipe at computationally high Reynolds number. Cla...
A scaling formula for the mean velocity and wall distance in compressible turbulent wall-bounded flo...
This work reports results of direct numerical simulations (DNS) of compressible internal flows. For ...
The effect of the Reynolds number in a supersonic isothermal channel flow is studied using a direct ...
A study of compressible supersonic turbulent flow in a plane channel with isothermal walls has been ...
The present paper addresses some topical issues in modelling compressible turbulent shear flows. The...
Compressible turbulent channel flows at two Mach numbers (M = 0.8 and 1.3) are simulated by the nume...
Classical Mach-number (M) scaling in compressible wall turbulence was suggested by van Driest (Van D...
The aim of this work is to improve the present understanding of compressibility effects in wall-boun...
The aim of this work is to improve the present understanding of compressibility effects in wall-boun...
The high-Reynolds-number behaviour of the canonical incompressible turbulent channel flow is investi...
The motivation for this work is the fact that in turbulent flows where compressibility effects are i...
The effects of surface roughness on compressible turbulent flow have not been studied as closely as ...
When analyzing many turbulent flows, the effects of compressibility can be neglected. Even some rela...
In this paper, direct numerical simulation (DNS) is presented for spatially evolving turbulent bound...
We study compressible turbulent flow in a circular pipe at computationally high Reynolds number. Cla...
A scaling formula for the mean velocity and wall distance in compressible turbulent wall-bounded flo...
This work reports results of direct numerical simulations (DNS) of compressible internal flows. For ...
The effect of the Reynolds number in a supersonic isothermal channel flow is studied using a direct ...
A study of compressible supersonic turbulent flow in a plane channel with isothermal walls has been ...
The present paper addresses some topical issues in modelling compressible turbulent shear flows. The...
Compressible turbulent channel flows at two Mach numbers (M = 0.8 and 1.3) are simulated by the nume...
Classical Mach-number (M) scaling in compressible wall turbulence was suggested by van Driest (Van D...
The aim of this work is to improve the present understanding of compressibility effects in wall-boun...
The aim of this work is to improve the present understanding of compressibility effects in wall-boun...
The high-Reynolds-number behaviour of the canonical incompressible turbulent channel flow is investi...
The motivation for this work is the fact that in turbulent flows where compressibility effects are i...
The effects of surface roughness on compressible turbulent flow have not been studied as closely as ...
When analyzing many turbulent flows, the effects of compressibility can be neglected. Even some rela...
In this paper, direct numerical simulation (DNS) is presented for spatially evolving turbulent bound...
We study compressible turbulent flow in a circular pipe at computationally high Reynolds number. Cla...
A scaling formula for the mean velocity and wall distance in compressible turbulent wall-bounded flo...
This work reports results of direct numerical simulations (DNS) of compressible internal flows. For ...