Viscous Fluid Flow over a Corrugated Bottom in a Strongly Rotating System

Abstract

The problem of a laterally unbounded viscous flow across slight bottom corrugations at a right angle in a strongly rotating system is considered. It is shown that when the ratio of the Rossby number to the Reynolds number ${\delta }^2\text{\hspace{0.17em}≡\hspace{0.17em}Ro/Re ≪ 1}$ and ${\mathrm{Re\hspace{0.17em}=\hspace{0.17em}\delta }}^{\mathrm{-m}}\text{, m < 1}$ , the flow far away from the bottom is both geostrophic and hydrostatic to a high degree and that flow near the bottom is of the boundary‐layer type with negligible inertia. A steady‐state solution for the entire flow field is obtained in which boundary‐layer suction maintains the mass continuity as fluid is pushed across the uneven bottom at a constant speed. Experimental results for a bottom of constant slope are presented which are in good agreement with theory.