Concurrent scale interactions in the far-field of a turbulent mixing layer

The interaction between the large- and small-scales in the self-similar region of a nominally two-dimensional planar mixing layer is examined at a centreline Reynolds number Reλ ≈ 260 (where Reλ is the Reynolds number based on Taylor microscale). Particle image velocimetry experiments are performed...

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Bibliographic Details
Published inPhysics of fluids (1994) Vol. 26; no. 12
Main Authors Buxton, O. R. H., Ganapathisubramani, B.
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.12.2014
Subjects
Alignment
Amplitudes
Fluid dynamics
Fluid flow
Flux
Kinetic energy
Large eddy simulation
Particle image velocimetry
Reynolds number
Self-similarity
Turbulent mixing
Variation
Velocity measurement
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Summary:The interaction between the large- and small-scales in the self-similar region of a nominally two-dimensional planar mixing layer is examined at a centreline Reynolds number Reλ ≈ 260 (where Reλ is the Reynolds number based on Taylor microscale). Particle image velocimetry experiments are performed at two different spatial resolutions, one that captures the range from integral scale (L) to Taylor microscale (λ) and the other that captures the range from Taylor microscale to the Kolmogorov length scale (η), simultaneously. It is found that the amplitude of the small-scale fluctuations (scales <λ) is modulated by the large-scale velocity fluctuations (scales >λ). Negative large-scale fluctuations (i.e. large-scale fluctuations that are less than the local mean) are found to coincide with regions where an increase in the amplitude of the small-scale fluctuations is found. This amplification effect, of the small-scales by the large-scales, is found to increase with the magnitude of the large-scale fluctuations. By drawing an analogy between the two different spatially resolved datasets and a large eddy simulation it is shown that the turbulent kinetic energy flux to the sub-grid-scales (SGS) is highly sensitive to the alignment between the fluctuating velocity vector and the gradient of the mean shear of the flow. When these two large-scale vectors are perpendicular there is a notable increase in the small-scale turbulent kinetic energy (TKE) flux. This small-scale TKE flux was observed to be influenced by this large-scale alignment even for the smallest scales present, where the correlation between u1 and u2 has vanished (SGS scale <λ/8).
ISSN:1070-6631
1089-7666
DOI:10.1063/1.4903970