Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence
Rapidly rotating turbulent flow is characterized by the emergence of columnar structures that are representative of quasi-two-dimensional behavior of the flow. It is known that when energy is injected into the fluid at an intermediate scale L f, it cascades towards smaller as well as larger scales....
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paper:paper_15393755_v86_n3_p_Sen2023-06-08T16:20:55Z Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence Mininni, Pablo Daniel Columnar structures Eddy viscosity Forcing function Forcings Helicities Large-scale energy spectrum Nonuniversality Per unit Quasi-two-dimensional behavior Rossby numbers Rotating turbulence Small scale Time-scales Total energy Two-dimensional (2D) turbulence Wave numbers Anisotropy Aspect ratio Reynolds number Spectroscopy Three dimensional computer graphics Shear flow Rapidly rotating turbulent flow is characterized by the emergence of columnar structures that are representative of quasi-two-dimensional behavior of the flow. It is known that when energy is injected into the fluid at an intermediate scale L f, it cascades towards smaller as well as larger scales. In this paper we analyze the flow in the inverse cascade range at a small but fixed Rossby number, Ro f≈0.05. Several numerical simulations with helical and nonhelical forcing functions are considered in periodic boxes with unit aspect ratio. In order to resolve the inverse cascade range with reasonably large Reynolds number, the analysis is based on large eddy simulations which include the effect of helicity on eddy viscosity and eddy noise. Thus, we model the small scales and resolve explicitly the large scales. We show that the large-scale energy spectrum has at least two solutions: one that is consistent with Kolmogorov-Kraichnan-Batchelor-Leith phenomenology for the inverse cascade of energy in two-dimensional (2D) turbulence with a ∼k⊥-5/3 scaling, and the other that corresponds to a steeper ∼k⊥-3 spectrum in which the three-dimensional (3D) modes release a substantial fraction of their energy per unit time to the 2D modes. The spectrum that emerges depends on the anisotropy of the forcing function, the former solution prevailing for forcings in which more energy is injected into the 2D modes while the latter prevails for isotropic forcing. In the case of anisotropic forcing, whence the energy goes from the 2D to the 3D modes at low wave numbers, large-scale shear is created, resulting in a time scale τ sh, associated with shear, thereby producing a ∼k -1 spectrum for the total energy with the horizontal energy of the 2D modes still following a ∼k⊥-5/3 scaling. © 2012 American Physical Society. Fil:Mininni, P.D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2012 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15393755_v86_n3_p_Sen http://hdl.handle.net/20.500.12110/paper_15393755_v86_n3_p_Sen |
institution |
Universidad de Buenos Aires |
institution_str |
I-28 |
repository_str |
R-134 |
collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
topic |
Columnar structures Eddy viscosity Forcing function Forcings Helicities Large-scale energy spectrum Nonuniversality Per unit Quasi-two-dimensional behavior Rossby numbers Rotating turbulence Small scale Time-scales Total energy Two-dimensional (2D) turbulence Wave numbers Anisotropy Aspect ratio Reynolds number Spectroscopy Three dimensional computer graphics Shear flow |
spellingShingle |
Columnar structures Eddy viscosity Forcing function Forcings Helicities Large-scale energy spectrum Nonuniversality Per unit Quasi-two-dimensional behavior Rossby numbers Rotating turbulence Small scale Time-scales Total energy Two-dimensional (2D) turbulence Wave numbers Anisotropy Aspect ratio Reynolds number Spectroscopy Three dimensional computer graphics Shear flow Mininni, Pablo Daniel Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
topic_facet |
Columnar structures Eddy viscosity Forcing function Forcings Helicities Large-scale energy spectrum Nonuniversality Per unit Quasi-two-dimensional behavior Rossby numbers Rotating turbulence Small scale Time-scales Total energy Two-dimensional (2D) turbulence Wave numbers Anisotropy Aspect ratio Reynolds number Spectroscopy Three dimensional computer graphics Shear flow |
description |
Rapidly rotating turbulent flow is characterized by the emergence of columnar structures that are representative of quasi-two-dimensional behavior of the flow. It is known that when energy is injected into the fluid at an intermediate scale L f, it cascades towards smaller as well as larger scales. In this paper we analyze the flow in the inverse cascade range at a small but fixed Rossby number, Ro f≈0.05. Several numerical simulations with helical and nonhelical forcing functions are considered in periodic boxes with unit aspect ratio. In order to resolve the inverse cascade range with reasonably large Reynolds number, the analysis is based on large eddy simulations which include the effect of helicity on eddy viscosity and eddy noise. Thus, we model the small scales and resolve explicitly the large scales. We show that the large-scale energy spectrum has at least two solutions: one that is consistent with Kolmogorov-Kraichnan-Batchelor-Leith phenomenology for the inverse cascade of energy in two-dimensional (2D) turbulence with a ∼k⊥-5/3 scaling, and the other that corresponds to a steeper ∼k⊥-3 spectrum in which the three-dimensional (3D) modes release a substantial fraction of their energy per unit time to the 2D modes. The spectrum that emerges depends on the anisotropy of the forcing function, the former solution prevailing for forcings in which more energy is injected into the 2D modes while the latter prevails for isotropic forcing. In the case of anisotropic forcing, whence the energy goes from the 2D to the 3D modes at low wave numbers, large-scale shear is created, resulting in a time scale τ sh, associated with shear, thereby producing a ∼k -1 spectrum for the total energy with the horizontal energy of the 2D modes still following a ∼k⊥-5/3 scaling. © 2012 American Physical Society. |
author |
Mininni, Pablo Daniel |
author_facet |
Mininni, Pablo Daniel |
author_sort |
Mininni, Pablo Daniel |
title |
Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
title_short |
Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
title_full |
Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
title_fullStr |
Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
title_full_unstemmed |
Anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
title_sort |
anisotropy and nonuniversality in scaling laws of the large-scale energy spectrum in rotating turbulence |
publishDate |
2012 |
url |
https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15393755_v86_n3_p_Sen http://hdl.handle.net/20.500.12110/paper_15393755_v86_n3_p_Sen |
work_keys_str_mv |
AT mininnipablodaniel anisotropyandnonuniversalityinscalinglawsofthelargescaleenergyspectruminrotatingturbulence |
_version_ |
1768543916038029312 |