New Exact Betchov-like Relation for the Helicity Flux in Homogeneous Turbulence

Damiano Capocci; Perry L Johnson; Sean Oughtton; Luca Biferale; Moritz Linkmann

doi:10.1017/jfm.2023.236

New Exact Betchov-like Relation for the Helicity Flux in Homogeneous Turbulence

Damiano Capocci, Perry L Johnson, Sean Oughtton, Luca Biferale, Moritz Linkmann

School of Mathematics

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

Abstract

In homogeneous and isotropic turbulence, the relative contributions of different physical mechanisms to the energy cascade can be quantified by an exact decomposition of the energy flux (P. Johnson, Phys. Rev. Lett., 124, 104501 (2020), J. Fluid Mech. 922, A3(2021)). We extend the formalism to the transfer of kinetic helicity across scales, important in the presence of large-scale mirror breaking mechanisms, to identify physical processes resulting in helicity transfer and quantify their contributions to the mean flux in the inertial range. All subfluxes transfer helicity from large to small scales. About 50% of the mean flux is due to the scale-local vortex flattening and vortex twisting. We derive a new exact relation between these effects, similar to the Betchov relation for the energy
flux, revealing that the mean contribution of the former is three times larger than that of the latter. Multi-scale effects account for the remaining 50% of the mean flux, with approximate equipartition between multi-scale vortex flattening, twisting and entangling.

Original language	English
Article number	R1
Journal	Journal of Fluid Mechanics
Volume	963
Early online date	11 May 2023
DOIs	https://doi.org/10.1017/jfm.2023.236
Publication status	Published - 25 May 2023

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10.1017/jfm.2023.236

New Exact Betchov-like Relation for the Helicity Flux in Homogeneous TurbulenceAccepted author manuscript, 582 KB

https://arxiv.org/abs/2301.04193

Superstructures and exact coherent states in the asymptotic suction boundary layer
Linkmann, M.
EU other
1/05/20 → 30/09/24
Project: Research

Cite this

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title = "New Exact Betchov-like Relation for the Helicity Flux in Homogeneous Turbulence",

abstract = "In homogeneous and isotropic turbulence, the relative contributions of different physical mechanisms to the energy cascade can be quantified by an exact decomposition of the energy flux (P. Johnson, Phys. Rev. Lett., 124, 104501 (2020), J. Fluid Mech. 922, A3(2021)). We extend the formalism to the transfer of kinetic helicity across scales, important in the presence of large-scale mirror breaking mechanisms, to identify physical processes resulting in helicity transfer and quantify their contributions to the mean flux in the inertial range. All subfluxes transfer helicity from large to small scales. About 50% of the mean flux is due to the scale-local vortex flattening and vortex twisting. We derive a new exact relation between these effects, similar to the Betchov relation for the energyflux, revealing that the mean contribution of the former is three times larger than that of the latter. Multi-scale effects account for the remaining 50% of the mean flux, with approximate equipartition between multi-scale vortex flattening, twisting and entangling.",

author = "Damiano Capocci and Johnson, {Perry L} and Sean Oughtton and Luca Biferale and Moritz Linkmann",

note = "Funding Information: Computational resources were provided through Scottish Academic Access on Cirrus ( www.cirrus.ac.uk ), and the UK Turbulence Consortium on ARCHER2 ( www.archer2.ac.uk ). This work received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 882340) and from the Priority Programme SPP 1881 {\textquoteleft}Turbulent Superstructures{\textquoteright} of the Deutsche Forschungsgemeinschaft (DFG, Li3694/1). Publisher Copyright: {\textcopyright} The Author(s), 2023. Published by Cambridge University Press.",

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AU - Capocci, Damiano

AU - Johnson, Perry L

AU - Oughtton, Sean

AU - Biferale, Luca

AU - Linkmann, Moritz

N1 - Funding Information: Computational resources were provided through Scottish Academic Access on Cirrus ( www.cirrus.ac.uk ), and the UK Turbulence Consortium on ARCHER2 ( www.archer2.ac.uk ). This work received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement no. 882340) and from the Priority Programme SPP 1881 ‘Turbulent Superstructures’ of the Deutsche Forschungsgemeinschaft (DFG, Li3694/1). Publisher Copyright: © The Author(s), 2023. Published by Cambridge University Press.

PY - 2023/5/25

Y1 - 2023/5/25

N2 - In homogeneous and isotropic turbulence, the relative contributions of different physical mechanisms to the energy cascade can be quantified by an exact decomposition of the energy flux (P. Johnson, Phys. Rev. Lett., 124, 104501 (2020), J. Fluid Mech. 922, A3(2021)). We extend the formalism to the transfer of kinetic helicity across scales, important in the presence of large-scale mirror breaking mechanisms, to identify physical processes resulting in helicity transfer and quantify their contributions to the mean flux in the inertial range. All subfluxes transfer helicity from large to small scales. About 50% of the mean flux is due to the scale-local vortex flattening and vortex twisting. We derive a new exact relation between these effects, similar to the Betchov relation for the energyflux, revealing that the mean contribution of the former is three times larger than that of the latter. Multi-scale effects account for the remaining 50% of the mean flux, with approximate equipartition between multi-scale vortex flattening, twisting and entangling.

AB - In homogeneous and isotropic turbulence, the relative contributions of different physical mechanisms to the energy cascade can be quantified by an exact decomposition of the energy flux (P. Johnson, Phys. Rev. Lett., 124, 104501 (2020), J. Fluid Mech. 922, A3(2021)). We extend the formalism to the transfer of kinetic helicity across scales, important in the presence of large-scale mirror breaking mechanisms, to identify physical processes resulting in helicity transfer and quantify their contributions to the mean flux in the inertial range. All subfluxes transfer helicity from large to small scales. About 50% of the mean flux is due to the scale-local vortex flattening and vortex twisting. We derive a new exact relation between these effects, similar to the Betchov relation for the energyflux, revealing that the mean contribution of the former is three times larger than that of the latter. Multi-scale effects account for the remaining 50% of the mean flux, with approximate equipartition between multi-scale vortex flattening, twisting and entangling.

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JO - Journal of Fluid Mechanics

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ER -

New Exact Betchov-like Relation for the Helicity Flux in Homogeneous Turbulence

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Superstructures and exact coherent states in the asymptotic suction boundary layer

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