Couette flow turbulence reduction by the flow spanwise reflection symmetry breaking: On the universality of the control strategy

A novel turbulence control strategy for wall-bounded shear flow is proposed by Chagelishvili et al, 2014. The essence of this strategy involves continuously imposition of specially designed seed velocity perturbations with spanwise asymmetry near the flow wall. The configuration of this imposed velocity field, enhanced due to the shear flow non-normality, breaks the flow spanwise reflection symmetry, specifically, resulting in the generation of a secondary nonuniform spanwise mean flow. Consequently, this secondary flow significantly reduces flow turbulence. In Chagelishvili et al, 2014, the first steps were taken towards developing this new turbulence control strategy and demonstrating its efficiency. The plane Couette flow was considered, as a representative example, and a theoretical and hypothetical weak near-wall volume forcing was designed, which though theoretical, provided valuable insights into the characteristics of the seed velocity field. Obviously, the practical significance of this control strategy should be confirmed by evaluating its effectiveness in flows at various Reynolds numbers, and with different parameters of the imposed seed velocity field. In this paper, we investigate the effectiveness and universality of the turbulence control strategy for Couette flow at various Reynolds numbers and different locations of the volume forcing. Through direct numerical simulations, we show universality of the discussed turbulence control method. The application of a specially designed, weak near-wall volume forcing with a fixed configuration and amplitude results in the same effective turbulence control, reducing turbulence kinetic energy production by 30-40\% across a wider range Reynolds numbers, \(Re_{\tau} = 52,92,128,270\) and various localizations.