Rotating flow over shallow topographies

The flow of a rotating homogeneous incompressible fluid over various shallow topographies is investigated. In the physical system considered, the rotation axis is vertical while the topography and its mirror image are located on the lower and upper of two horizontal plane surfaces. Upstream of the topographies and outside the Ekman layers on the bounding planes the fluid is in a uniform free-stream motion. An analysis is considered in which E [Lt ] 1, Ro ∼ E½, H/D ∼ E0, and h/D ∼ E½, where E is the Ekman number, Ro the Rossby number, H/D the fluid depth to topography width ratio and h/D the topography height-to-width ratio. The governing equation for the lowest-order interior motion is obtained by matching an interior geostrophic region with Ekman boundary layers along the confining surfaces. The equation includes contributions from the non-linear inertial, Ekman suction, and topographic effects. An analytical solution for a cosine-squared topography is given for the case in which the inertial terms are negligible; i.e. Ro [Lt ] E½. Numerical solutions for the non-linear equations are generated for both cosine-squared and conical topographies. Laboratory experiments are presented which are in good agreement with the theory advanced.

[1]  A. Arakawa Computational design for long-term numerical integration of the equations of fluid motion: two-dimen , 1997 .

[2]  D. Boyer Rotating flow over a step , 1971, Journal of Fluid Mechanics.

[3]  D. Boyer Flow Past a Right Circular Cylinder in a Rotating Frame , 1970 .

[4]  D. W. Moore,et al.  The flow induced by the transverse motion of a thin disk in its own plane through a contained rapidly rotating viscous liquid , 1969, Journal of Fluid Mechanics.

[5]  Gareth P. Williams Numerical integration of the three-dimensional Navier-Stokes equations for incompressible flow , 1969, Journal of Fluid Mechanics.

[6]  A. Ingersoll Inertial Taylor Columns and Jupiter's Great Red Spot , 1969 .

[7]  M. Lighthill,et al.  On slow transverse flow past obstacles in a rapidly rotating fluid , 1968, Journal of Fluid Mechanics.

[8]  S. Jacobs The Taylor column problem , 1964, Journal of Fluid Mechanics.

[9]  K. Miyakoda,et al.  Contribution to the numerical weather prediction:computation with finite difference. , 1962 .

[10]  J. Gillis,et al.  Matrix Iterative Analysis , 1961 .

[11]  G. Platzman The computational stability of boundary conditions in numerical integration of the vorticity equation , 1954 .

[12]  G. Taylor Experiments on the motion of solid bodies in rotating fluids , 1923 .

[13]  D. Boyer Rotating flow over long shallow ridges , 1971 .

[14]  R. Hide,et al.  An experimental study of “Taylor columns”☆ , 1966 .

[15]  Douglas K. Lilly,et al.  ON THE COMPUTATIONAL STABILITY OF NUMERICAL SOLUTIONS OF TIME-DEPENDENT NON-LINEAR GEOPHYSICAL FLUID DYNAMICS PROBLEMS , 1965 .