Wall-attached temperature structures in supersonic turbulent boundary layers

It is well known that low- and high-speed velocity streaks are statistically asymmetric. However, it is unclear how different the low- and high-temperature structures (T-structures) are even though they are strongly coupled with the streamwise velocity. Therefore, this paper identifies three-dimensi...

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Bibliographic Details
Published inPhysics of fluids (1994) Vol. 34; no. 11
Main Authors Yuan, Xianxu, Tong, Fulin, Li, Weipeng, Chen, Jianqiang, Dong, Siwei
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.11.2022
Subjects
Channel flow
Compressibility
Direct numerical simulation
Fluid flow
Heat flux
High speed
High temperature
Linear functions
Logarithms
Mathematical models
Self-similarity
Turbulent boundary layer
Velocity
Wall temperature
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Summary:It is well known that low- and high-speed velocity streaks are statistically asymmetric. However, it is unclear how different the low- and high-temperature structures (T-structures) are even though they are strongly coupled with the streamwise velocity. Therefore, this paper identifies three-dimensional wall-attached temperature structures in supersonic turbulent boundary layers over cooled and heated walls (coming from direct numerical simulations) and separates them into positive and negative families. Wall-attached T-structures are self-similar; especially, the length and width of the positive family are linear functions of the height. The superposed temperature variance in both positive and negative families exhibits a logarithmic decay with the wall distance, while the superposed intensity of the wall-normal heat flux in the negative family shows a logarithmic growth. The modified strong Reynolds analogy proposed by Huang, Coleman, and Bradshaw [“Compressible turbulent channel flows: DNS results and modelling,” J. Fluid Mech. 305, 185–218 (1995)] is still valid in the negative family. The relative position between T-structures of opposite signs depends on the wall temperature and that in the cooled-wall case differs significantly from the relative position between low- and high-speed streaks, especially those tall ones. In the cooled-wall case, although positive temperature fluctuations below and above the maximum of the mean temperature can cluster to large-scale wall-attached structures, they are very likely dynamically unrelated.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0121900