The boundary conditions of viscous electron flow

Abstract

The sensitivity of charge, heat, or momentum transport to the sample geometry is a hallmark of viscous electron flow. Therefore, hydrodynamic electronics requires the detailed understanding of electron flow in finite geometries. The solution of the corresponding generalized Navier-Stokes equations depends sensitively on the nature of boundary conditions. The latter are generally characterized by a slip length ζ with extreme cases being no-slip (ζ→0) and no-stress (ζ→∞) conditions. We develop a kinetic theory that determines the temperature dependent slip length at a rough interface for Dirac liquids, e.g. graphene, and for Fermi liquids. For strongly disordered edges that scatter electrons in a fully diffuse way, we find that the slip length is of the order of the momentum conserving mean free path lee that determines the electron viscosity. For boundaries with nearly specular scattering ζ is parametrically large compared to lee. Since for all quantum fluids lee diverges as T→0, the ultimate low-temperature flow is always in the no-stress regime. Only at intermediate T and for sufficiently large sample sizes can the slip lengths be short enough such that no-slip conditions are appropriate. We discuss numerical examples for several experimentally investigated systems.