Viscous flow of interacting electrons in two dimensional materials features a bunch of exotic effects. A model resembling the Navier-Stokes equation for classical fluids accounts for them in the so called hydrodynamic regime. This regime occurs when electron-electron collisions are frequent enough. We performed a detailed analysis of the hydrodynamic requirements and found three new routes to achieve viscous electron flow: favouring frequent inelastic collisions, the application of a magnetic field or a high-frequency electric field. Our results show that the conventional requirement of frequent electron-electron collisions is too restrictive and, as a consequence, materials and phenomena to be described using hydrodynamics are widened. We discuss recent experiments regarding Poiseuille-like flows, superballistic conduction and negative resistances as signatures for viscous flow onset. We conclude that these usual signatures of viscous electron flow are achieved by following alternative meta-hydrodynamic routes.
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