GFD XI: baroclinic instability of the thermal wind
The purpose of the experiment is to observe `Hadley' and `eddying' regimes in a differentially heated, rotating fluid annulus.
The experimental arrangement is the same as in GFD Lab
VII - see figure opposite. It consists of a cylindrical plexiglass tank filled with water to a depth of about 15cm and placed on a rotating table. Initially, the water is of uniform temperature. But centered on the rotation axis, we place a metal bucket filled with ice. This sets up a radial temperature gradient (decreasing "poleward") that will drive motions in the tank. Temperature variations in the tank are monitored at strategic positions using thermisters attached to data loggers. Currents are observed using paper dots, potassium permanganate crystals etc.
`Hadley' and `eddying' turbulent regimes can be set up in the tank by adjusting the rotation rate, Ω, of the tank - Ω can be ranged from zero to 10 rpm
observe the following:
- when the table is not rotating a simple overturning circulation is
observed, with sinking at the edges of the cold can, outflow near the bottom boundary layer, inflow aloft.
- when weakly rotating, an Ω of 0.3 rpm or less, we see the development of the thermal
wind and a Hadley Circulation as described in GFD Lab
VII with a single meridional overturning cell.
- if the rotation rate is increased in small increments (0.2 rpm or so) we
can map the transition from axisymmetric flow through regular waves to turbulent eddies.
- when the table is rotating rapidly, an Ω of 1 rpm or more, we see the development of
turbulent eddies in the tank, through baroclinic instability. The baroclinic eddies
carry heat from the 'equator' of the tank to the 'pole' in the center.
Here is a sequence of images showing the evolution of the flow in the fully
Click here to look at a movie.