Instabilities in visco-thermodiffusive swirling flows

A geometrical optics approach has been used to derive instability criteria for various swirling flows observed in nature and industrial processes. By applying a short-wavelength local analysis to the Navier-Stokes equations, coupled with the energy equation when necessary, we account for viscosity and thermal diffusivity effects. The derived criteria are validated for swirling flows modeled by a cylindrical differentially rotating annulus with axial flow induced by either a sliding inner cylinder, an axial pressure gradient, or a radial temperature gradient combined with vertical gravity. These criteria successfully reproduce known results from numerical linear stability analysis and agree with experimental and simulation data. Moreover, they unify and extend several classical instability criteria: the Rayleigh criterion for centrifugally-driven instabilities, the Ludwieg-Eckhoff-Leibovich-Stewartson criterion for isothermal swirling flows, and the Goldreich-Schubert-Fricke criterion for non-isothermal azimuthal flows. Additionally, they predict oscillatory modes in swirling flows, thereby generalizing the McIntyre instability criterion to these systems.