The vortices near the origin of an initially laminar mixing layer have a single frequency with a well-defined phase; i.e. there is little phase jitter. Further downstream, however, the phase jitter increases suddenly. Even when the flow is forced, this same transition is observed. The forcing partially loses its influence because of the decorrelation of the phase between the forcing signal and the passing coherent structures. In the present investigation, this phenomenon is documented and the physical mechanism responsible for the phase decorrelation is identified. © 1991, Cambridge University Press. All rights reserved
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The broad problem being addressed in our research is to identify and describe the primary vortical (...
There is now overwhelming evidence that in most turbulent flows there exist regions moving with the ...
Several direct numerical simulations were performed and analyzed to study various aspects of the ear...
Coherent structures and the similarity characteristics of the turbulent mixing layer were the subjec...
It is well known that fully developed turbulent free shear layers exhibit a high degree of order, ch...
An incompressible, time developing 3-D mixing layer with idealized initial conditions was simulated ...
Large scale coherent structures are intrinsic fluid mechanical characteristics of all free-shear flo...
New flow-visualization experiments on mixing layers of various velocity and density ratios are repor...
Detailed three-dimensional three-component phase averaged measurements of the spanwise and streamwis...
The term "mixing transition" denotes an increase in molecular mixedness observed in a shear How whi...
Numerical simulations of incompressible, two-dimensional, monochromatically and bichromatically forc...
A synthetic large-scale motion is excited in a flat plate turbulent boundary layer experiment and it...
For experimenters, coherent structures (CSs) in a turbulent flow appear as macroscopic subdomains of...
The current study seeks a fundamental explanation to the development of two-dimensional coherent str...
A new theory of coherent structure in wall turbulence is presented. The theory is the first to predi...
The broad problem being addressed in our research is to identify and describe the primary vortical (...
There is now overwhelming evidence that in most turbulent flows there exist regions moving with the ...