Assessment of large-scale forcing in isotropic turbulence using a closed Kármán-Howarth equation

Djenidi, L.; Antonia, R. A.

Title: Assessment of large-scale forcing in isotropic turbulence using a closed Kármán-Howarth equation
Creator: Djenidi, L.; Antonia, R. A.
Relation: Physics of Fluids Vol. 32, Issue 5, no. 055104
Publisher Link: http://dx.doi.org/10.1063/5.0006466
Publisher: American Institute of Physics (AIP)
Resource Type: journal article
Date: 2020
Description: We attempt to model the effects of large-scale forcing on the statistical behavior of small scales in isotropic turbulence. More specifically, the effect of large-scale forcing on the second-order velocity structure function, S₂, in the region beyond the dissipative range, is analyzed via the transport equation for S₂ where a closure model for S₃, the third-order velocity structure function, is introduced. The model [L. Djenidi and R. A. Antonia, Fluid Turbulence Applications in Both Industrial and Environmental Topics, Marseille, 9–11 July, 2019, https://fab60.sciencesconf.org/] is based on a gradient type with an eddy-viscosity formulation and has the following expression: [formula could not be replicated], where [formula could not be replicated] is the mean rate of the turbulent kinetic energy dissipation, r is the spatial increment, and [formula could not be replicated] is a constant. The closed S₂-transport equation is further exploited to derive a model for S₂ for scales beyond the dissipative range. The model for S₂ takes the form [formula could not be replicated] with [formula could not be replicated], where CK is a constant, Reλ is the Taylor microscale Reynolds number, and the function Br accounts for the effect of the large scales. The numerical solutions of the S₂ equation and the predictions based on the model for S₂ agree very well with direct numerical simulation data for steady-state forced homogeneous and isotropic turbulence. The solutions of the S₂-transport equation without large-scale forcing show that S₂ behaves like [formula could not be replicated]. When forcing is applied, S₂ deviates from this behavior. However, increasing the Reynolds number tends to restore this behavior over an increasing range of scales. This is also observed in the predictions of the model for S₂.
Subject: statistical behavior; isotropic turbulence; gradient type; range of scales
Identifier: http://hdl.handle.net/1959.13/1453330
Identifier: uon:44650
Identifier: ISSN:1070-6631
Language: eng
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