Av. Bobrovich et Gm. Reznik, Planetary waves in a stratified ocean of variable depth. Part 2. Continuously stratified ocean, J FLUID MEC, 388, 1999, pp. 147-169
Linear Rossby waves in a continuously stratified ocean over a corrugated ro
ugh-bottomed topography are investigated by asymptotic methods. The main re
sults are obtained for the case of constant buoyancy frequency. In this cas
e there exist three types of modes: a topographic mode, a barotropic mode,
and a countable set of baroclinic modes. The properties of these modes depe
nd on the type of mode, the relative height delta of the bottom bumps, the
wave scale L, the topography scale L-b and the Rossby scale L-i. For small
delta the barotropic and baroclinic modes are transformed into the 'usual'
Rossby modes in an ocean of constant depth and the topographic mode degener
ates. With increasing delta the frequencies of the barotropic and topograph
ic modes increase monotonically and these modes become close to a purely to
pographic mode for sufficiently large delta. As for the baroclinic modes, t
heir frequencies do not exceed O(beta L) for any delta. For large delta the
so-called 'displacement' effect occurs when the mode velocity becomes smal
l in a near-bottom layer and the baroclinic mode does not 'feel' the actual
rough bottom relief. At the same time, for some special values of the para
meters a sort of resonance arises under which the large- and small-scale co
mponents of the baroclinic mode intensify strongly near the bottom.
As in the two-layer model, a so-called 'screening' effect takes place here.
It implies that for L-b much less than L-i the small-scale component of th
e mode is confined to a near-bottom boundary layer (L-b/L-i)H thick, wherea
s in the region above the layer the scale L of motion is always larger than
or of the order of L-i.