Vorticity amplification in viscoelastic channel flows with long-wave surface distortions

TL;DR

This paper investigates how long-wave surface distortions generate significant vorticity perturbations in viscoelastic channel flows, revealing mechanisms that differ markedly from Newtonian fluids and highlighting the impact of elasticity and inertia.

Contribution

It identifies new vorticity amplification mechanisms in viscoelastic flows caused by long-wave surface distortions, including elastic and elasto-inertial effects, which are absent in Newtonian fluids.

Findings

Elastic response causes streamlines to match bottom topography.

Resonance in elasto-inertial flows amplifies vorticity in critical layers.

Long-wave distortions significantly affect viscoelastic flows across parameters.

Abstract

Surface distortions to an otherwise planar channel flow introduce vorticity perturbations. We examine this scenario in viscoelastic fluids, and identify new mechanisms by which significant vorticity perturbations can be generated in both inertialess and elasto-inertial channel flows. We focus on the case where the lengthscale of the surface distortion is much longer than the channel depth, where we find significant departure from plane shear (Page & Zaki, J. Fluid Mech. 801 2016) due to the non-monotonic base-flow streamwise-normal elastic stress. In inertialess flows, a purely elastic response results in streamlines deforming to match the bottom topography in the lower half the channel. However, the vanishing stress at the centreline introduces a blocking effect, and the associated $O(1)$ jump in normal velocity is balanced by a narrow, large amplitude streamwise-oscillating `jet', resulting in a localised, chevron-shaped vorticity perturbation field. In elasto-inertial flows, resonance between the frequency of elasto-inertial `Alfven' waves and the frequency apparent to an observer moving with the fluid results in vorticity amplification in a pair of critical layers on either side of the channel. The vorticity in both layers is equal in magnitude and as such the perturbation vorticity field penetrates the full channel depth even when inertia is dominant. The results demonstrate that long-wave distortions - which are relatively innocuous in Newtonian fluids - can drive a significant flow distortion in viscoelastic fluids for a wide range of parameter values.