On the laminar solutions and stability of accelerating and decelerating channel flows

Abstract

We study the effect of acceleration and deceleration on the stability of channel flows. To do so, we derive an exact solution for laminar profiles of channel flows with arbitrary, time-varying wall motion and pressure gradient. This solution then allows us to investigate the stability of any unsteady channel flow. In particular, we investigate the nonnormal growth of perturbations in flows with exponentially decaying acceleration and deceleration, with comparisons to growth in a constant flow (i.e., the time-invariant simple shear or parabolic profile). We apply this acceleration and deceleration through the velocity of the walls and through the flow rate. For accelerating flows, disturbances never grow larger than disturbances in a constant flow, while decelerating flows show massive amplification of disturbances -- at a Reynolds number of 800, disturbances in the decelerating flow grow $\mathscr{O}(10^4)$ times larger than disturbances grow in a constant flow. This amplification increases as we raise the rate of deceleration and the Reynolds number. We find that this amplification arises due to a transition from spanwise perturbations leading to the largest amplification, to streamwise perturbations leading to the largest amplification that only occurs in the decelerating flow. By evolving the optimal perturbations through the linearized equations of motion, we reveal that the decelerating case achieves this massive amplification through a down-gradient Reynolds stress mechanism, which accelerating and constant flows cannot maintain. Finally, we end the paper by validating that these perturbations exhibit the same growth behaviors in direct numerical simulations