Tsallis statistics and fully developed turbulence

Arimitsu, Toshihico; Arimitsu, Naoko

doi:10.1088/0305-4470/33/27/101

Cited by 91 publications

(118 citation statements)

References 15 publications

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“…We note that for the above five distribution functions the first-order corrections to the Boltzmann factor e −β 0 E in eqs. (6), (10), (14), (16), (20) can all be written in a universal form. When expressing the generalized Boltzmann factor in terms of the average temperature β 0 and the variance σ 2 of the various probability densities f (β), one always obtains the same result for small σ,…”

Section: F-distributionmentioning

confidence: 99%

“…Several types of generalized stochastic dynamics have been recently constructed for which Tsallis statistics can be proved rigorously [4,5,6]. Physical applications include 2-d and 3-d turbulence [7]- [14], momentum spectra of hadronic particles produced in e + e − annihilation experiments [15,16], the statistics of cosmic rays [17], and many other phenomena.…”

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confidence: 99%

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Superstatistics

Beck

Cohen

2003

Physica A: Statistical Mechanics and its Applications

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1,229

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We consider nonequilibrium systems with complex dynamics in stationary states with large fluctuations of intensive quantities (e.g. the temperature, chemical potential or energy dissipation) on long time scales. Depending on the statistical properties of the fluctuations, we obtain different effective statistical mechanical descriptions. Tsallis statistics follows from a χ 2 -distribution of an intensive variable, but other classes of generalized statistics are obtained as well. We show that for small variance of the fluctuations all these different statistics behave in a universal way.

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Section: F-distributionmentioning

confidence: 99%

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confidence: 99%

Superstatistics

Beck

Cohen

2003

Physica A: Statistical Mechanics and its Applications

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1,229

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“…is the so-called scaling exponent of the velocity structure function, whose expression was derived first by the present authors [15][16][17][18]. In this paper, we will use the formula (6) in order to extract the value of the intermittency exponent µ for the best fit to the measured scaling exponents by the method of least squares.…”

Section: Dαpmentioning

confidence: 99%

“…is the multifractal spectrum [15][16][17][18], derived by the relation P (n) (α) ∝ δ 1−f (α) n [9,18], that reveals how densely each singularity, labeled by α, fills physical space.…”

Section: Dαpmentioning

confidence: 99%

“…On this line, an investigation of turbulence based on the generalized entropy, i.e., Rényi's [11] or Tsallis' [12,13], was started by the present authors [14][15][16][17][18][19][20]. After a rather preliminary investigation of the p-model [14], it has been developed further to derive the analytical expression for the scaling exponents of velocity structure function [15][16][17][18], and to determine the probability density function (PDF) of velocity fluctuations [18][19][20] by a self-consistent statistical mechanical approach.With the help of the analytical formulae derived in [15][16][17][18][19][20], we will analyze, in this paper, the PDF's of velocity fluctuations observed in the beautiful DNS (i.e., the direct numerical simulation) conducted by Gotoh et al [21]. We will deal with the data at the Taylor microscale Reynolds number R λ = 381, since at this Reynolds number Gotoh et al observed the PDF with accuracy up to order of 10 −9 ∼ 10 −10 , in contrast with any previous experiments, real or numerical.…”

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Analysis of velocity fluctuation in turbulence based on generalized statistics

Arimitsu

2002

J. Phys.: Condens. Matter

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The numerical experiments of turbulence conducted by Gotoh et al. are analyzed precisely with the help of the formulae for the scaling exponents of velocity structure function and for the probability density function of velocity fluctuations. These formulae are derived by the present authors with the multifractal aspect based on the statistics that are constructed on the generalized measures of entropy, i.e., the extensive Rényi's or the non-extensive Tsallis' entropy. It is shown, explicitly, that there exist two scaling regions, i.e., the upper scaling region with larger separations which may correspond to the scaling range observed by Gotoh et al., and the lower scaling region with smaller separations which is a new scaling region extracted first by the present systematic analysis. These scaling regions are divided by a definite length approximately of the order of the Taylor microscale, which may correspond to the crossover length proposed by Gotoh et al. as the low end of the scaling range (i.e., the upper scaling region). 47.27.-i, 47.53.+n, 47.52.+j, 05.90.+m After the discovery of the Kolmogorov spectrum [1], there have been plenty of trials including [2,3] in order to understand the intermittent evolution of fluid in fully developed turbulence. Among them, the line based on a kind of ensemble theoretical approaches, initiated by the log-normal model [4][5][6], consists of the β-model (a unifractal dimensional analysis) [7], the p-model (a multifractal model) [8,9], the 3D binomial Cantor set model [10] and so on. On this line, an investigation of turbulence based on the generalized entropy, i.e., Rényi's [11] or Tsallis' [12,13], was started by the present authors [14][15][16][17][18][19][20]. After a rather preliminary investigation of the p-model [14], it has been developed further to derive the analytical expression for the scaling exponents of velocity structure function [15][16][17][18], and to determine the probability density function (PDF) of velocity fluctuations [18][19][20] by a self-consistent statistical mechanical approach.With the help of the analytical formulae derived in [15][16][17][18][19][20], we will analyze, in this paper, the PDF's of velocity fluctuations observed in the beautiful DNS (i.e., the direct numerical simulation) conducted by Gotoh et al. [21]. We will deal with the data at the Taylor microscale Reynolds number R λ = 381, since at this Reynolds number Gotoh et al. observed the PDF with accuracy up to order of 10 −9 ∼ 10 −10 , in contrast with any previous experiments, real or numerical. We showed in [19] that our formulae can explain quite well the PDF's observed in the real experiment by Lewis and Swinney [22] for turbulent Couette-Taylor flow at R λ = 270 (Re = 5.4 × 10 5 ) produced in a concentric cylinder system in which, however, the PDF's were measured only with accuracy of order of 10 −5 . Note that the success of the present theory in the analysis of this turbulent Couette-Taylor flow may indicate the robustness of singularities associated with velocity grad...

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An Aspect of Granulence in View of Multifractal Analysis

Arimitsu

Traffic and Granular Flow ’03

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Tsallis statistics and fully developed turbulence

Cited by 91 publications

References 15 publications

Superstatistics

Superstatistics

Analysis of velocity fluctuation in turbulence based on generalized statistics

An Aspect of Granulence in View of Multifractal Analysis

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