Spin-down in a rapidly rotating cylinder container with mixed rigid and stress-free boundary conditions

Abstract

A comprehensive study of the classical linear spin-down of a constant density viscous fluid (kinematic viscosity ) rotating rapidly (angular velocity ) inside an axisymmetric cylindrical container (radius L, height H) with rigid boundaries, that follows the instantaneous small change in the boundary angular velocity at small Ekman number E=/H2 1, was provided by Greenspan & Howard (1963). E1/2-Ekman layers form quickly triggering inertial waves together with the dominant spin-down of the quasi-geostrophic (QG) interior flow on the O(E-1/2-1) time-scale. On the longer lateral viscous diffusion time-scale O(L2/), the QG-flow responds to the E1/3-side-wall shear-layers. In our variant the side-wall and top boundaries are stress-free; a setup motivated by the study of isolated atmospheric structures, such as tropical cyclones, or tornadoes. Relative to the unbounded plane layer case, spin-down is reduced (enhanced) by the presence of a slippery (rigid) side-wall. This is evinced by the QG-angular velocity, ω*, evolution on the O(L2/) time-scale: Spatially, ω* increases (decreases) outwards from the axis for a slippery (rigid) side-wall; temporally, the long-time ( L2/) behaviour is dominated by an eigensolution with a decay rate slightly slower (faster) than that for an unbounded layer. In our slippery side-wall case, the E1/2 × E1/2 corner region that forms at the side-wall intersection with the rigid base is responsible for a E singularity within the E1/3-layer causing our asymptotics to apply only at values of E far smaller than can be reached by our Direct Numerical Simulation (DNS) of the entire spin-down process. Instead, we solve the E1/3-boundary-layer equations for given E numerically. Our hybrid asymptotic-numerical approach yields results in excellent agreement with our DNS.