Structure function empirical constant: Difference between revisions
From Atomix
Jmmcmillan (talk | contribs) Created page with "{{DefineConcept |parameter_name=<math>C_2</math> |description=The empirical constant relating the longitudinal structure function <math>D_{LL}</math> to the dissipation rate (..." |
Jmmcmillan (talk | contribs) No edit summary |
||
| Line 10: | Line 10: | ||
The value of the constant is generally accepted to be <math>2.1\pm 0.1</math>, based on the following studies: | The value of the constant is generally accepted to be <math>2.1\pm 0.1</math>, based on the following studies: | ||
# Sauvageot (1992): Used Doppler radar measurements of turbulence in the atmosphere to obtain a value of <math>2.0\pm 0.1</math> | # Sauvageot (1992)<ref name="Sauvageot">{{Cite journal | ||
# Saddoughi and Veeravalli (1994): Used measurements in a wind tunnel to obtain a value of <math>2.1\pm 0.1</math> | |authors= H. Sauvageot | ||
# Sreenivasan (1995): Compiled the results from experimental studies of both grid turbulence and shear flows to conclude that a value of 2.0 agreed best with the spectral inertial subrange equation | |journal_or_publisher= Artech House | ||
|paper_or_booktitle= Radar Meteorology | |||
|year= 1992 | |||
}}</ref>: Used Doppler radar measurements of turbulence in the atmosphere to obtain a value of <math>2.0\pm 0.1</math> | |||
# Saddoughi and Veeravalli (1994)<ref name="Saddoughi">{{Cite journal | |||
|authors= K. R. Sreenivasan | |||
|journal_or_publisher= J. Fluid Mech. | |||
|paper_or_booktitle= Local isotropy in turbulent boundary layers at high Reynolds number | |||
|year= 1994 | |||
|doi= https://doi.org/10.1017/S0022112094001370 | |||
}}</ref>: Used measurements in a wind tunnel to obtain a value of <math>2.1\pm 0.1</math> | |||
# Sreenivasan (1995) <ref name="Sreenivasan">{{Cite journal | |||
|authors= K. R. Sreenivasan | |||
|journal_or_publisher= Phys. Fluids | |||
|paper_or_booktitle= On the universality of the Kolmogorov constant | |||
|year= 1995 | |||
|doi= 10.1063/1.868656 | |||
}}</ref>: Compiled the results from experimental studies of both grid turbulence and shear flows to conclude that a value of 2.0 agreed best with the spectral inertial subrange equation | |||
== Notes == | |||
Latest revision as of 21:46, 12 November 2021
| Short definition of Structure function empirical constant (<math>C_2</math>) |
|---|
| The empirical constant relating the longitudinal structure function <math>D_{LL}</math> to the dissipation rate (<math>\varepsilon</math>) |
This is the common definition for Structure function empirical constant, but other definitions maybe discussed within the wiki.
{{#default_form:DefineConcept}} {{#arraymap:Velocity profilers|,|x||}}
Dimensional analysis can be used to show that <math>D_{LL}</math> must satisfy the "two-thirds law", i.e., <math>D_{LL}(r,t) = C_2\varepsilon^{2/3}r^{2/3}</math> where <math>C_2</math> is a universal constant.
The value of the constant is generally accepted to be <math>2.1\pm 0.1</math>, based on the following studies:
- Sauvageot (1992)[1]: Used Doppler radar measurements of turbulence in the atmosphere to obtain a value of <math>2.0\pm 0.1</math>
- Saddoughi and Veeravalli (1994)[2]: Used measurements in a wind tunnel to obtain a value of <math>2.1\pm 0.1</math>
- Sreenivasan (1995) [3]: Compiled the results from experimental studies of both grid turbulence and shear flows to conclude that a value of 2.0 agreed best with the spectral inertial subrange equation
Notes
- ↑ {{#arraymap:H. Sauvageot|,|x|x|, |and}}. 1992. Radar Meteorology. Artech House. doi:{{{doi}}}
- ↑ {{#arraymap:K. R. Sreenivasan|,|x|x|, |and}}. 1994. Local isotropy in turbulent boundary layers at high Reynolds number. J. Fluid Mech.. doi:https://doi.org/10.1017/S0022112094001370
- ↑ {{#arraymap:K. R. Sreenivasan|,|x|x|, |and}}. 1995. On the universality of the Kolmogorov constant. Phys. Fluids. doi:10.1063/1.868656
