Asymptotics of the centre mode instability in viscoelastic channel flow: with and without inertia

Motivated by the recent numerical results of Khalid et al., Phys. Rev. Lett., 127, 134502 (2021), we consider the large-Weissenberg-number ($W$) asymptotics of the centre mode instability in inertialess viscoelastic channel flow. The instability is of the critical layer type in the distinguished ultra-dilute limit where $W(1-\beta)=O(1)$ as $W \rightarrow \infty$ ($\beta$ is the ratio of solvent-to-total viscosity). In contrast to centre modes in the Orr-Sommerfeld equation, $1-c=O(1)$ as $W \rightarrow \infty$ where $c$ is the phase speed normalised by the centreline speed as a central `outer' region is always needed to adjust the non-zero cross-stream velocity at the critical layer down to zero at the centreline. The critical layer acts as a pair of intense `bellows' which blows the flow streamlines apart locally and then sucks them back together again. This compression/rarefaction amplifies the streamwise-normal polymer stress which in turn drives the streamwise flow through local polymer stresses at the critical layer. The streamwise flow energises the cross-stream flow via continuity which in turn intensifies the critical layer to close the cycle. We also treat the large-Reynolds-number ($Re$) asymptotic structure of the upper (where $1-c=O(Re^{-2/3})$) and lower branches of the $Re$-$W$ neutral curve confirming the inferred scalings from previous numerical computations. Finally, we argue that the viscoelastic centre mode instability was actually first found in viscoelastic Kolmogorov flow by Boffetta et al., J. Fluid Mech., 523, 161-170 (2005).