Scaling of mixed longitudinal-transverse velocity structure functions

The difference between scaling exponents of longitudinal and transverse velocity structure functions in the far-field of a round jet is found to depend on the anisotropy of the flow. The effect of the large-scale anisotropy is assessed by considering different initial conditions at the jet nozzle, and hence different ratios of the longitudinal to transverse rms velocities. The effect of the Taylor microscale Reynolds number on the small scale anisotropy is also considered. Both effects account, to a large extent, for the observed difference between longitudinal and transverse exponents and the disagreement between previously published results of different authors. This disagreement also depends on the method used to determine the inertial range. An empirical description of the overall behaviour of the structure functions provides reasonable estimates for the longitudinal and transverse exponents, accounting reasonably well for the anisotropy of both large- and small-scale motions.

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Calculation of velocity structure functions for vortex models of isotropic turbulence

Physics of Fluids ◽

10.1063/1.869081 ◽

1996 ◽

Vol 8 (11) ◽

pp. 3072-3084 ◽

Cited By ~ 18

Author(s):

P. G. Saffman ◽

D. I. Pullin

Keyword(s):

Velocity Structure ◽

Isotropic Turbulence ◽

Structure Functions

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Anomalous scaling for Lagrangian velocity structure functions in fully developed turbulence

Physical Review E ◽

10.1103/physreve.83.025301 ◽

2011 ◽

Vol 83 (2) ◽

Cited By ~ 6

Author(s):

Guo-Wei He

Keyword(s):

Velocity Structure ◽

Structure Functions ◽

Anomalous Scaling ◽

Fully Developed Turbulence ◽

Developed Turbulence ◽

Lagrangian Velocity

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Low-order velocity structure functions in relatively high Reynolds number turbulence

EPL (Europhysics Letters) ◽

10.1209/epl/i1999-00461-5 ◽

1999 ◽

Vol 48 (2) ◽

pp. 163-169 ◽

Cited By ~ 10

Author(s):

R. A Antonia ◽

B. R Pearson

Keyword(s):

Reynolds Number ◽

High Reynolds Number ◽

Velocity Structure ◽

Structure Functions ◽

High Reynolds ◽

Low Order

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Scaling and Similarity of the Anisotropic Coherent Eddies in Near-Surface Atmospheric Turbulence

Journal of the Atmospheric Sciences ◽

10.1175/jas-d-17-0246.1 ◽

2018 ◽

Vol 75 (3) ◽

pp. 943-964 ◽

Cited By ~ 9

Author(s):

Khaled Ghannam ◽

Gabriel G. Katul ◽

Elie Bou-Zeid ◽

Tobias Gerken ◽

Marcelo Chamecki

Keyword(s):

Scaling Laws ◽

Velocity Structure ◽

Scaling Law ◽

Longitudinal Velocity ◽

Structure Functions ◽

Length Scale ◽

Near Surface ◽

Vegetation Canopies ◽

Velocity Spectra ◽

Attached Eddies

Abstract The low-wavenumber regime of the spectrum of turbulence commensurate with Townsend’s “attached” eddies is investigated here for the near-neutral atmospheric surface layer (ASL) and the roughness sublayer (RSL) above vegetation canopies. The central thesis corroborates the significance of the imbalance between local production and dissipation of turbulence kinetic energy (TKE) and canopy shear in challenging the classical distance-from-the-wall scaling of canonical turbulent boundary layers. Using five experimental datasets (two vegetation canopy RSL flows, two ASL flows, and one open-channel experiment), this paper explores (i) the existence of a low-wavenumber k−1 scaling law in the (wind) velocity spectra or, equivalently, a logarithmic scaling ln(r) in the velocity structure functions; (ii) phenomenological aspects of these anisotropic scales as a departure from homogeneous and isotropic scales; and (iii) the collapse of experimental data when plotted with different similarity coordinates. The results show that the extent of the k−1 and/or ln(r) scaling for the longitudinal velocity is shorter in the RSL above canopies than in the ASL because of smaller scale separation in the former. Conversely, these scaling laws are absent in the vertical velocity spectra except at large distances from the wall. The analysis reveals that the statistics of the velocity differences Δu and Δw approach a Gaussian-like behavior at large scales and that these eddies are responsible for momentum/energy production corroborated by large positive (negative) excursions in Δu accompanied by negative (positive) ones in Δw. A length scale based on TKE dissipation collapses the velocity structure functions at different heights better than the inertial length scale.

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Solar wind low-frequency magnetohydrodynamic turbulence: extended self-similarity and scaling laws

Nonlinear Processes in Geophysics ◽

10.5194/npg-3-247-1996 ◽

1996 ◽

Vol 3 (4) ◽

pp. 247-261 ◽

Cited By ~ 14

Author(s):

V. Carbone ◽

P. Veltri ◽

R. Bruno

Keyword(s):

Solar Wind ◽

Scaling Laws ◽

Velocity Structure ◽

Fluid Flows ◽

Structure Functions ◽

Point Of View ◽

Self Similarity ◽

Extended Self ◽

Scaling Exponents ◽

Magnetohydrodynamic Turbulence

Abstract. In this paper we review some of the work done in investigating the scaling properties of Magnetohydrodynamic turbulence, by using velocity fluctuations measurements performed in the interplanetary space plasma by the Helios spacecraft. The set of scaling exponents ξq for the q-th order velocity structure functions, have been determined by using the Extended Self-Similarity hypothesis. We have found that the q-th order velocity structure function, when plotted vs. the 4-th order structure function, displays a range of self-similarity which extends over all the lengths covered by measurements, thus allowing for a very good determination of ξq. Moreover the results seem to show that the scaling exponents are the same regardless the various observation periods considered. The obtained scaling exponents have been compared with the results of some intermittency models for Kraichnan's turbulence, derived in the framework of infinitely divisible fragmentation processes, showing the good agreement between these models and our observations. Finally, on the basis of the actually available data sets, we show that scaling laws in Solar Wind turbulence seem to be different from turbulent scaling laws in the ordinary fluid flows. This is true for high-order velocity structure functions, while low-order velocity structure functions show the same scaling laws. Since our measurements involve length scales which extend over many order of magnitude where dissipation is practically absent, our results show that Solar Wind turbulence can be regarded as a testing bench for the investigation of general scaling behaviour in turbulent flows. In particular our results strongly support the point of view which attributes a key role to the inertial range dynamics in determining the intermittency characteristics in fluid flows, in contrast with the point of view which attributes intermittency to a finite Reynolds number effect.

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