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Abstract
Mathematical attributes of full self-preserving solutions (‘full’ meaning self-similar at all scales with non-zero viscosity) for isotropic decay as well as for homogeneous shear flow turbulence are examined from a fundamental theoretical standpoint. Fully self-preserving solutions are those wherein the two-point double and triple velocity correlations are self-similar at all scales. It is shown that the full self-preserving solutions for isotropic decay corresponds to a t −1 asymptotic power law decay, consistent with earlier studies. Fully self-preserving solutions for homogeneous shear flow correspond to a production-equals-dissipation equilibrium, with bounded turbulent kinetic energy and dissipation. It is then shown that the fully self-preserving solutions of isotropic decay and of homogeneous shear flow both require severe constraints on the behavior of the low-wavenumber energy spectra. These constraints render the full self-preserving solutions as mathematical consistent but having no physical relevance. The implications of the dependence of the full self-preserving solutions on the low-wavenumber spectra for one-point (engineering) turbulence models is discussed.
Invited speaker, Santa Fe CNLS-LANL Workshop on Turbulence and Cascade.
Acknowledgements
CZ and TTC were supported by the United States Department of Energy LDRD Program, no. LDRD-94135. This work by the second author was performed under the auspices of the U.S. Department of Energy by the University of California Lawrence Livermore National Laboratory under contract no. W-7405-Eng-48.
Notes
Invited speaker, Santa Fe CNLS-LANL Workshop on Turbulence and Cascade.
†We are indebted to Professor Speziale for this analysis.
‡Equation (Equation3) and Equation (Equation71) are obtained from different approaches. They lead to the same α when n = 1, but provided different values of α when n ≠ 1.
†The authors are indebted to J. Herring, of the National Center for Atmospheric Research for this interpretation.
‡Several papers have reported a tendency to a t −1 power-law decay, see [Citation22, Citation23, Citation24, Citation25]. For related turbulence modeling issues, please see [Citation28, Citation29, Citation30, Citation31, Citation32, Citation33, Citation34].