Monday, April 22, 2024 4pm to 5pm
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Abstract: The dynamics of a stratified fluid in which the rotation vector is slanted at an angle with respect to the local vertical (determined by gravity) is considered for the case where the aspect ratio of the characteristic vertical scale of the motion D to the horizontal scale L is not small. In cases where the Rossby number of the flow is small the natural coordinate system is non-orthogonal and modifications to the dynamics are significant. Two regimes are examined in this paper. The first is the case in which the horizontal length scale of the motion, L, is sub-planetary where the quasi geostrophic approximation is valid. The second, is the case where the horizontal scale is commensurate with the planetary radius and so the dynamics must be formulated in spherical coordinates with imposing a full variation on the relevant components of rotation. In the quasi geostrophic case the rotation axis replaces the direction of gravity as the axis along which the geostrophic flow varies in response to horizontal density gradients. The quasi-geostrophic potential vorticity equation is most naturally written in a non orthogonal coordinate system with fundamental alterations in the dynamics. Examples, such as the reformulation of the classical Eady problem are presented to illustrate the changes in the nature of the dynamics. The second case where the horizontal scale is of the order of R, the planetary radius, more fundamental changes occur and leads to more fundamental and difficult changes in the dynamical model.
Bio: A graduate of MIT with a BS and MS in aeronautical engineering and a PhD in Meteorology. Appointments at MIT (mathematics), University of Chicago (Geophysical Sciences) and the Woods Hole Oceanographic Institution. Now retired but continues his research in Geophysical Fluid Dynamics. Other interests include literature, music (clarinet) and speaking Italian.
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