Skewness and flatness factors of the longitudinal velocity derivative in wall-bounded flows

Djenidi, Lyazid; Antonia, Robert A.; Talluru, Murali K.; Abe, Hiroyuki

Title: Skewness and flatness factors of the longitudinal velocity derivative in wall-bounded flows
Creator: Djenidi, Lyazid; Antonia, Robert A.; Talluru, Murali K.; Abe, Hiroyuki
Relation: ARC
Relation: Physical Review Fluids Vol. 2, Issue 6, no. 064608
Publisher Link: http://dx.doi.org/10.1103/PhysRevFluids.2.064608
Publisher: American Physical Society
Resource Type: journal article
Date: 2017
Description: Hot-wire measurements are carried out in turbulent boundary layers over smooth and rough walls in order the assess the behavior of the skewness (S) and flatness (F) factors of the longitudinal velocity derivative as y, the distance from the wall, increases. The measurements are complemented by direct numerical simulations of a smooth wall turbulent channel flow. It is observed that, as the distance to the wall increases, S and F vary significantly before approaching a constant in the outer layer of the boundary layer. Further, S and F exhibit a nontrivial dependence on the Taylor microscale Reynolds number (Re_λ). For example, in the region below about 0.2δ (δ is the boundary layer thickness) where Re_λ varies significantly, S and F strongly vary with Re_λ and can be multivalued at a given Re_λ. In the outer region, between 0.3δ and 0.6δ, S, F, and Re_λ remain approximately constant. The channel flow direct numerical simulation data for S and F exhibit a similar behavior. These results point to the ambiguity that can arise when assessing the Re_λ dependence of S and F in wall shear flows. In particular, the multivaluedness of S and F can lead to erroneous conclusions if y/δ is known only poorly, as is the case for the atmospheric shear layer (ASL). If the laboratory turbulent boundary layer is considered an adequate surrogate to the neutral ASL, then the behavior of S and F in the ASL is expected to be similar to that reported here.
Subject: skewness factors; flatness factors; hot-wire measurements; turbulent boundary layers; channel flow; shear flow
Identifier: http://hdl.handle.net/1959.13/1397277
Identifier: uon:34227
Identifier: ISSN:2469-990X
Language: eng
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