Different cascade speeds for longitudinal and transverse velocity increments of small-scale turbulence

We analyse the relationship of longitudinal and transversal increment statistics measured in isotropic small-scale turbulence. This is done by means of the theory of Markov processes leading to a phenomenological Fokker-Planck equation for the two increments from which a generalized Kármán equation is derived. We discuss in detail the analysis and show that the estimated equation can describe the statistics of the turbulent cascade. A remarkable result is that the main differences between longitudinal and transversal increments can be explained by a simple rescaling symmetry, namely the cascade speed of the transverse increments is 1.5 times faster than that of the longitudinal increments. Small differences can be found in the skewness and in a higher order intermittency term. The rescaling symmetry is compatible with the Kolmogorov constants and the Kármán equation and gives new insight into the use of extended self-similarity (ESS) for transverse increments. Based on the results we propose an extended self-similarity for the transverse increments (ESST).

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“…These two aspects were already presented in [47], but here we go in more detail and add some new aspects.…”

Section: Compatibility To Known Resultsmentioning

confidence: 96%

Joint multi-scale statistics of longitudinal and transversal increments in small-scale wake turbulence

Siefert

Peinke²

2006

Journal of Turbulence

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“…In [18], evidence from experimental data Taylor-based Reynolds numbers between 180 and 550 was presented to support this view. The success of the approach introduced by Siefert and Peinke [18] motivated us to extend their re-interpretation of differential relations to structure functions of higher orders, making use of the exact relationships derived by Hill and Boratav [2], Hill [1] and Yakhot [3]. Hill derived these relations directly by inventing a clever matrix algorithm which allowed him to efficiently simplify the derivation and calculations.…”

Section: Rescaling Relations Between Longitudinal and Transverse Strumentioning

confidence: 97%

“…which is exact and contains no contribution from the pressure-it is a statement of incompressibility. Siefert and Peinke [18] observed that the structure function is a smooth function of r and that if the scale r is chosen in the inertial range, i.e. 'small' compared to the integral scale L, equation (1) can be seen as a Taylor expansion:…”

Section: Rescaling Relations Between Longitudinal and Transverse Strumentioning

confidence: 99%

Longitudinal and transverse structure functions in high-Reynolds-number turbulence

2012

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Abstract. Using exact relations between velocity structure functions [1-3] and neglecting pressure contributions in a first approximation, we obtain a closed system and derive simple order-dependent rescaling relationships between longitudinal and transverse structure functions. By means of numerical data with turbulent Reynolds numbers ranging from λ = 320 to λ = 730, we establish a clear correspondence between their respective scaling ranges, while confirming that their scaling exponents do differ. This difference does not seem to depend on the Reynolds number. Making use of the Mellin transform, we further map longitudinal to (rescaled) transverse probability density functions. Contents

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“…We present a method for deriving an underlying mathematical or model‐free equation, the Fokker‐Planck equation, that governs the time‐dependent probability distributions of the fluctuations at different delay times starting from observations of the backscattering cross section. Such an approach provides a stochastic method for describing turbulent flows, and its use has been of interest in the community in recent years [ Friedrich and Peinke , 1997; Siefert and Peinke , 2004]. In particular, the time‐dependent tails of the probability distribution functions are a signature of intermittency in turbulent flows [ Monin and Yaglom , 1975; Frisch , 1995].…”

Section: Introductionmentioning

confidence: 99%

Internal variability and pattern identification in cirrus cloud structure: The Fokker‐Planck equation approach

Shirer

Clothiaux

2006

J. Geophys. Res.

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[1] Using 35-GHz millimeter wave radar observations collected at the Southern Great Plains site of the Atmospheric Radiation Measurements (ARM) program, we study physical processes in cirrus cloud layers having different stratifications. The timedependent probability distribution functions of the backscattering cross section within different layers in the cloud describe the dynamics of the pertinent physical processes. The time-dependent tails of the probability distribution functions provide the signature of intermittency characterizing turbulent flows. In the framework of the Fokker-Planck equation approach, we derive the behavior of the drift D (1) and diffusion D (2) terms that characterize the deterministic and stochastic parts, respectively, of the dynamics of the probability distribution functions directly from the time series of observed backscattering cross section. We derive the Langevin equation that governs the temporal evolution of the backscattering cross-section signal in cloud layers having different stratification. Finally, we ascertain that the drift g and diffusion b coefficients of the backscattering cross-section signal in the upper well-mixed, neutrally stratified layer of the cirrus cloud satisfy the relationship g = 2b, which is valid for fully developed turbulence owing to the Kolmogorov À4/5 law.

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Different cascade speeds for longitudinal and transverse velocity increments of small-scale turbulence

Cited by 25 publications

References 37 publications

Joint multi-scale statistics of longitudinal and transversal increments in small-scale wake turbulence

Joint multi-scale statistics of longitudinal and transversal increments in small-scale wake turbulence

Longitudinal and transverse structure functions in high-Reynolds-number turbulence

Internal variability and pattern identification in cirrus cloud structure: The Fokker‐Planck equation approach

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