Energy transfer in turbulent channel flows and implications for resolvent modelling
Energy transfer in turbulent channel flows and implications for resolvent modelling
We analyse the inter-scale transfer of energy for two types of plane Poiseuille flow: the P4U exact coherent state of Park & Graham (J. Fluid Mech., vol. 782, 2015, pp. 430-454) and turbulent flow in a minimal channel. For both flows, the dominant energy-producing modes are streamwise-constant streaks with a spanwise spacing of approximately 100 wall units. Since the viscous dissipation for these scales is not sufficient to balance production, the nonlinear terms redistribute the excess energy to other scales. Spanwise-constant scales (that is, Tollmien-Schlichting-like modes with zero spanwise wavenumber), in particular, account for a significant amount of net energy gain from the nonlinear terms. We compare the energy balance to predictions from resolvent analysis, and we show that it does not model energy transfer well. Nevertheless, we find that the energy transferred from the streamwise-constant streaks can be predicted reasonably well by a Cess eddy viscosity profile. As such, eddy viscosity is an effective model for the nonlinear terms in resolvent analysis and explains good predictions for the most energetic streamwise-constant streaks. It also improves resolvent modes as a basis for structures whose streamwise lengths are greater than their spanwise widths by counteracting non-normality of the resolvent operator. This is quantified by computing the inner product between the optimal resolvent forcing and response modes, which is a metric of non-normality. Eddy viscosity does not respect the conservative nature of the nonlinear energy transfer, which must sum to zero over all scales. Since eddy viscosity tends to remove energy, it is less effective in modelling nonlinear transport for scales that receive energy from the nonlinear terms.
low-dimensional models, turbulence modelling, turbulence theory
Symon, Sean
2e1580c3-ba27-46e8-9736-531099f3d850
Illingworth, Simon J.
0e1c7b04-2c41-4152-996f-6aa92583bf5b
Marusic, Ivan
e8863dbc-d29e-4087-9269-ea1ef1d63f48
25 January 2021
Symon, Sean
2e1580c3-ba27-46e8-9736-531099f3d850
Illingworth, Simon J.
0e1c7b04-2c41-4152-996f-6aa92583bf5b
Marusic, Ivan
e8863dbc-d29e-4087-9269-ea1ef1d63f48
Symon, Sean, Illingworth, Simon J. and Marusic, Ivan
(2021)
Energy transfer in turbulent channel flows and implications for resolvent modelling.
Journal of Fluid Mechanics, 911, [A3].
(doi:10.1017/jfm.2020.929).
Abstract
We analyse the inter-scale transfer of energy for two types of plane Poiseuille flow: the P4U exact coherent state of Park & Graham (J. Fluid Mech., vol. 782, 2015, pp. 430-454) and turbulent flow in a minimal channel. For both flows, the dominant energy-producing modes are streamwise-constant streaks with a spanwise spacing of approximately 100 wall units. Since the viscous dissipation for these scales is not sufficient to balance production, the nonlinear terms redistribute the excess energy to other scales. Spanwise-constant scales (that is, Tollmien-Schlichting-like modes with zero spanwise wavenumber), in particular, account for a significant amount of net energy gain from the nonlinear terms. We compare the energy balance to predictions from resolvent analysis, and we show that it does not model energy transfer well. Nevertheless, we find that the energy transferred from the streamwise-constant streaks can be predicted reasonably well by a Cess eddy viscosity profile. As such, eddy viscosity is an effective model for the nonlinear terms in resolvent analysis and explains good predictions for the most energetic streamwise-constant streaks. It also improves resolvent modes as a basis for structures whose streamwise lengths are greater than their spanwise widths by counteracting non-normality of the resolvent operator. This is quantified by computing the inner product between the optimal resolvent forcing and response modes, which is a metric of non-normality. Eddy viscosity does not respect the conservative nature of the nonlinear energy transfer, which must sum to zero over all scales. Since eddy viscosity tends to remove energy, it is less effective in modelling nonlinear transport for scales that receive energy from the nonlinear terms.
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energy-transfer-in-turbulent-channel-flows-and-implications-for-resolvent-modelling
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e-pub ahead of print date: 25 January 2021
Published date: 25 January 2021
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Keywords:
low-dimensional models, turbulence modelling, turbulence theory
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Local EPrints ID: 452178
URI: http://eprints.soton.ac.uk/id/eprint/452178
ISSN: 0022-1120
PURE UUID: 0633ede7-bc7f-4db5-94f6-2c3ebbfb459f
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Date deposited: 29 Nov 2021 17:31
Last modified: 16 Mar 2024 14:26
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Author:
Simon J. Illingworth
Author:
Ivan Marusic
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