The logarithmic structure function law in wall-layer turbulence

P. A. DAVIDSON; T. B. NICKELS; P.-Å. KROGSTAD

doi:10.1017/S0022112005008001

Abstract

The $k^{-1}$ spectral law for near-wall turbulence has received only limited experimental support, the most convincing evidence being that of Nickels et al. (Phys. Rev. Lett. vol. 95, 2005, 074501.1). The real-space analogue of this law is a logarithmic dependence on $r$ of the streamwise longitudinal structure function. We show that, unlike the $k^{-1}$ law, the logarithmic law is readily seen in the experimental data. We argue that this difference arises from the finite value of Reynolds number in the experiments. Reducing the Reynolds number is equivalent to restricting the range of eddy sizes which contribute to the $k^{-1}$, or ln$r$, laws. While the logarithmic law is relatively insensitive to a truncation in the range of eddy sizes (it continues to hold over the relevant range of eddy sizes), it turns out that the $k^{-1}$ law is not. This is a direct consequence of the so-called aliasing problem associated with one-dimensional spectra, whereby energy is systematically and artificially displaced to small wavenumbers.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Davidson, P. A. Krogstad, P.-Å. and Nickels, T. B. 2006. A refined interpretation of the logarithmic structure function law in wall layer turbulence. Physics of Fluids, Vol. 18, Issue. 6,

Klewicki, Joe Fife, Paul Wei, Tie and McMurtry, Pat 2007. A physical model of the turbulent boundary layer consonant with mean momentum balance structure. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 365, Issue. 1852, p. 823.

Cabrit, Olivier and Nicoud, Franck 2009. Direct simulations for wall modeling of multicomponent reacting compressible turbulent flows. Physics of Fluids, Vol. 21, Issue. 5,

Talamelli, Alessandro Persiani, Franco H M Fransson, Jens Alfredsson, P Henrik V Johansson, Arne M Nagib, Hassan Rüedi, Jean-Daniel R Sreenivasan, Katepalli and A Monkewitz, Peter 2009. CICLoPE—a response to the need for high Reynolds number experiments. Fluid Dynamics Research, Vol. 41, Issue. 2, p. 021407.

Davidson, P. A. and Krogstad, P.-Å. 2009. A simple model for the streamwise fluctuations in the log-law region of a boundary layer. Physics of Fluids, Vol. 21, Issue. 5,

Klewicki, Joseph C. 2010. Reynolds Number Dependence, Scaling, and Dynamics of Turbulent Boundary Layers. Journal of Fluids Engineering, Vol. 132, Issue. 9,

Marusic, I. McKeon, B. J. Monkewitz, P. A. Nagib, H. M. Smits, A. J. and Sreenivasan, K. R. 2010. Wall-bounded turbulent flows at high Reynolds numbers: Recent advances and key issues. Physics of Fluids, Vol. 22, Issue. 6,

Dixit, Shivsai Ajit and Ramesh, O. N. 2013. On the scaling in sink-flow turbulent boundary layers. Journal of Fluid Mechanics, Vol. 737, Issue. , p. 329.

Davidson, P. A. and Krogstad, P.-Å. 2014. A universal scaling for low-order structure functions in the log-law region of smooth- and rough-wall boundary layers. Journal of Fluid Mechanics, Vol. 752, Issue. , p. 140.

Cimarelli, A. De Angelis, Elisabetta Talamelli, A. and Casciola, C. M. 2014. Progress in Turbulence V. Vol. 149, Issue. , p. 85.

Cimarelli, A. De Angelis, E. Schlatter, P. Brethouwer, G. Talamelli, A. and Casciola, C. M. 2015. Sources and fluxes of scale energy in the overlap layer of wall turbulence. Journal of Fluid Mechanics, Vol. 771, Issue. , p. 407.

Hamba, Fujihiro 2015. Turbulent energy density and its transport equation in scale space. Physics of Fluids, Vol. 27, Issue. 8,

de Silva, C. M. Marusic, I. Woodcock, J. D. and Meneveau, C. 2015. Scaling of second- and higher-order structure functions in turbulent boundary layers. Journal of Fluid Mechanics, Vol. 769, Issue. , p. 654.

Chung, D. Marusic, I. Monty, J. P. Vallikivi, M. and Smits, A. J. 2015. On the universality of inertial energy in the log layer of turbulent boundary layer and pipe flows . Experiments in Fluids, Vol. 56, Issue. 7,

Örlü, Ramis Segalini, Antonio Klewicki, Joseph and Alfredsson, P. Henrik 2016. High-order generalisation of the diagnostic scaling for turbulent boundary layers. Journal of Turbulence, Vol. 17, Issue. 7, p. 664.

Örlü, Ramis Segalini, Antonio Klewicki, Joseph and Alfredsson, P. Henrik 2016. Proceedings of the 5th International Conference on Jets, Wakes and Separated Flows (ICJWSF2015). Vol. 185, Issue. , p. 333.

Yang, Xiang I. A. Marusic, Ivan and Meneveau, Charles 2016. Moment generating functions and scaling laws in the inertial layer of turbulent wall-bounded flows. Journal of Fluid Mechanics, Vol. 791, Issue. ,

Katul, Gabriel G. Banerjee, Tirtha Cava, Daniela Germano, Massimo and Porporato, Amilcare 2016. Generalized logarithmic scaling for high-order moments of the longitudinal velocity component explained by the random sweeping decorrelation hypothesis. Physics of Fluids, Vol. 28, Issue. 9,

Pan, Y. and Chamecki, M. 2016. A scaling law for the shear-production range of second-order structure functions. Journal of Fluid Mechanics, Vol. 801, Issue. , p. 459.

Chamecki, Marcelo Dias, Nelson L. Salesky, Scott T. and Pan, Ying 2017. Scaling Laws for the Longitudinal Structure Function in the Atmospheric Surface Layer. Journal of the Atmospheric Sciences, Vol. 74, Issue. 4, p. 1127.

Download full list

Article contents

The logarithmic structure function law in wall-layer turbulence

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The logarithmic structure function law in wall-layer turbulence

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests