Application of an Integral Fluctuation Theorem to Turbulent Flows

N. Reinke; Daniel  Nickelsen; A. Engel; J. Peinke

doi:10.1007/978-3-319-29130-7_3

Application of an Integral Fluctuation Theorem to Turbulent Flows

N. Reinke
, Daniel Nickelsen
, A. Engel
, J. Peinke

University of Oldenburg

Research output: Conference Article in Proceeding or Book/Report chapter › Book chapter › Research › peer-review

Abstract

There is a long lasting discussion on universal properties of turbulence. The following questions arise: do turbulent properties change with the Reynolds number, or are they even dependent on the large scale properties of turbulence? An important feature would be that turbulence could be taken as universal below some scales. In this case, even for turbulent flows which are generated on a large scale by different processes, the same subgrid models can be used, an important aspect for numerical simulations. For large eddy simulations, it is essential to know the connections between larger scales and the unresolved subgrid turbulence. From this aspect it is important to get a profound understanding of the turbulent cascade, relating turbulent structures on different scales. Rigorous results on the turbulent cascade are still missing.

Original language	English
Title of host publication	Springer Proceedings in Physics
Number of pages	6
Volume	165
Publication date	3 Mar 2016
Pages	19-25
ISBN (Print)	9783319291291, 9783319291307
DOIs	https://doi.org/10.1007/978-3-319-29130-7_3
Publication status	Published - 3 Mar 2016
Externally published	Yes

Series	Springer Proceedings in Physics
ISSN	1867-4941

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10.1007/978-3-319-29130-7_3

Cite this

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abstract = "There is a long lasting discussion on universal properties of turbulence. The following questions arise: do turbulent properties change with the Reynolds number, or are they even dependent on the large scale properties of turbulence? An important feature would be that turbulence could be taken as universal below some scales. In this case, even for turbulent flows which are generated on a large scale by different processes, the same subgrid models can be used, an important aspect for numerical simulations. For large eddy simulations, it is essential to know the connections between larger scales and the unresolved subgrid turbulence. From this aspect it is important to get a profound understanding of the turbulent cascade, relating turbulent structures on different scales. Rigorous results on the turbulent cascade are still missing.",

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AU - Reinke, N.

AU - Nickelsen, Daniel

AU - Engel, A.

AU - Peinke , J.

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Y1 - 2016/3/3

N2 - There is a long lasting discussion on universal properties of turbulence. The following questions arise: do turbulent properties change with the Reynolds number, or are they even dependent on the large scale properties of turbulence? An important feature would be that turbulence could be taken as universal below some scales. In this case, even for turbulent flows which are generated on a large scale by different processes, the same subgrid models can be used, an important aspect for numerical simulations. For large eddy simulations, it is essential to know the connections between larger scales and the unresolved subgrid turbulence. From this aspect it is important to get a profound understanding of the turbulent cascade, relating turbulent structures on different scales. Rigorous results on the turbulent cascade are still missing.

AB - There is a long lasting discussion on universal properties of turbulence. The following questions arise: do turbulent properties change with the Reynolds number, or are they even dependent on the large scale properties of turbulence? An important feature would be that turbulence could be taken as universal below some scales. In this case, even for turbulent flows which are generated on a large scale by different processes, the same subgrid models can be used, an important aspect for numerical simulations. For large eddy simulations, it is essential to know the connections between larger scales and the unresolved subgrid turbulence. From this aspect it is important to get a profound understanding of the turbulent cascade, relating turbulent structures on different scales. Rigorous results on the turbulent cascade are still missing.

U2 - 10.1007/978-3-319-29130-7_3

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SN - 9783319291307

VL - 165

T3 - Springer Proceedings in Physics

SP - 19

EP - 25

BT - Springer Proceedings in Physics

ER -

Application of an Integral Fluctuation Theorem to Turbulent Flows

Abstract

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