Multi-affine Model for the Velocity Distribution in Fully Turbulent Flows

Tamás Vicsek; Albert-László Barabasi

doi:10.1088/0305-4470/24/15/010

Multi-affine Model for the Velocity Distribution in Fully Turbulent Flows

Tamás Vicsek, Albert-László Barabasi

Eotvos Lorand University

Research output: Contribution to journal › Letter › peer-review

Abstract (may include machine translation)

A simple multi-affine model for the velocity distribution in fully developed turbulent flows is introduced to capture the essential features of the underlying geometry of the velocity field. The authors show that in this model the various relevant quantities characterizing different aspects of turbulence can be readily calculated. A simultaneous good agreement is found with the available experimental data for the velocity structure functions, the Dq spectra obtained from studies of the velocity derivatives, and the exponent describing the scaling of the spectrum of the kinetic energy fluctuations. Their results are obtained analytically assuming a single free parameter. The fractal dimension of the region where the dominating contribution to dissipation comes from is estimated to be D approximately=2.88.

Original language	English
Pages (from-to)	L845-L851
Number of pages	7
Journal	Journal of Physics A: General Physics
Volume	24
Issue number	15
DOIs	https://doi.org/10.1088/0305-4470/24/15/010
State	Published - Aug 1991
Externally published	Yes

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title = "Multi-affine Model for the Velocity Distribution in Fully Turbulent Flows",

abstract = "A simple multi-affine model for the velocity distribution in fully developed turbulent flows is introduced to capture the essential features of the underlying geometry of the velocity field. The authors show that in this model the various relevant quantities characterizing different aspects of turbulence can be readily calculated. A simultaneous good agreement is found with the available experimental data for the velocity structure functions, the Dq spectra obtained from studies of the velocity derivatives, and the exponent describing the scaling of the spectrum of the kinetic energy fluctuations. Their results are obtained analytically assuming a single free parameter. The fractal dimension of the region where the dominating contribution to dissipation comes from is estimated to be D approximately=2.88.",

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AU - Barabasi, Albert-László

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Y1 - 1991/8

N2 - A simple multi-affine model for the velocity distribution in fully developed turbulent flows is introduced to capture the essential features of the underlying geometry of the velocity field. The authors show that in this model the various relevant quantities characterizing different aspects of turbulence can be readily calculated. A simultaneous good agreement is found with the available experimental data for the velocity structure functions, the Dq spectra obtained from studies of the velocity derivatives, and the exponent describing the scaling of the spectrum of the kinetic energy fluctuations. Their results are obtained analytically assuming a single free parameter. The fractal dimension of the region where the dominating contribution to dissipation comes from is estimated to be D approximately=2.88.

AB - A simple multi-affine model for the velocity distribution in fully developed turbulent flows is introduced to capture the essential features of the underlying geometry of the velocity field. The authors show that in this model the various relevant quantities characterizing different aspects of turbulence can be readily calculated. A simultaneous good agreement is found with the available experimental data for the velocity structure functions, the Dq spectra obtained from studies of the velocity derivatives, and the exponent describing the scaling of the spectrum of the kinetic energy fluctuations. Their results are obtained analytically assuming a single free parameter. The fractal dimension of the region where the dominating contribution to dissipation comes from is estimated to be D approximately=2.88.

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JO - Journal of Physics A: General Physics

JF - Journal of Physics A: General Physics

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ER -

Multi-affine Model for the Velocity Distribution in Fully Turbulent Flows

Abstract (may include machine translation)

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