Superposition of system response in modulated turbulent plane Couette flow

TL;DR

This study demonstrates that the response of turbulent plane Couette flow to velocity modulations can be effectively described by linear superposition of laminar responses, even in turbulent conditions, under certain modulation amplitudes and frequencies.

Contribution

It reveals that linear superposition principles apply to turbulent flow responses to modulated forcing, extending laminar flow models to turbulent regimes under specific conditions.

Findings

Flow response can be modeled by superposition of Fourier modes.

Laminar flow models accurately predict turbulent response.

Superposition holds for small modulation amplitudes.

Abstract

Traditionally, the response of a turbulent flow to modulated perturbations is expected to be complex. We conduct direct numerical simulations of turbulent Plane Couette flow, the shear flow between two differentially moving plates, to reveal intriguing behaviour in response to a modulation in the velocity of one of the plates: the response of the flow to modulations can be calculated from a superposition of the response to each Fourier mode of the modulation. We fix the shear Reynolds number as $Re_s=3\times10^4$, and measure the propagation of a modulated forcing in the flow close to the resonant frequency of the system. We find that the amplitude and phase response of the flow can be largely captured using models based on laminar flow, regardless of the waveform used to force the flow. Furthermore, we find that linear superposition can effectively describe the flow's response to these perturbations as long as the modulation is smaller than the base flow. Our findings unveil the persistence of linear superposition in a turbulent flow under specific conditions, even when perturbations occur at time-scales closely aligned with the system's characteristic time-scales.