Mode-to-mode nonlinear energy transfer in turbulent channel flows

TL;DR

This paper introduces a new variable to analyze nonlinear energy transfer in turbulent channel flows, revealing detailed energy transfer mechanisms among flow structures and scales at different Reynolds numbers.

Contribution

It develops a novel variable to explicitly quantify triadic nonlinear energy transfer, providing new insights into energy cascades and structure interactions in turbulence.

Findings

Transverse cascade from streamwise to spanwise modes observed in all structures.

Net forward energy cascade from resolved to subgrid scales matches Smagorinsky model predictions.

Quantification of energy transfer for different flow structures at multiple Reynolds numbers.

Abstract

We investigate nonlinear energy transfer for channel flows at friction Reynolds numbers of $Re_{\tau}=180$ and $590$. The key feature of the analysis is that we introduce a new variable, which quantifies the energy transferred from a source mode to a recipient mode through explicit examination of nonlinear triadic interactions in streamwise-spanwise wavenumber space. First, we use this variable to quantify the nonlinear energy transfer gain and loss for individual Fourier modes. The nonlinear energy transfer gain and loss cannot be directly obtained from the turbulent kinetic energy (TKE) equation. Second, we quantify the nonlinear energy transfer budgets for three types of structures: streamwise streaks, oblique waves and Tollmien-Schlichting waves. We found that a transverse cascade from streamwise-elongated modes to spanwise-elongated modes exists in all three structures. Third, we quantify the forward and inverse cascades between resolved scales and subgrid scales in the spirit of large-eddy simulation. For the cutoff wavelength range we consider, the forward and inverse cascades between the resolved scales and subgrid scales result in a net forward cascade from the resolved scales to the subgrid scales. The shape of the net forward cascade curve with respect to the cutoff wavelength resembles the net forward cascade predicted by the Smagorinsky eddy viscosity.