Physics
Scientific paper
Dec 2008
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2008phfl...20l6602w&link_type=abstract
Physics of Fluids, Volume 20, Issue 12, pp. 126602-126602-12 (2008).
Physics
4
Hydrodynamic Waves, Hydrodynamics, Rotating And Swirling Flows, Flow Instabilities
Scientific paper
We report an analog laboratory study of planetary-scale turbulence and jet formation. A rotating annulus was cooled and heated at its inner and outer walls, respectively, causing baroclinic instability to develop in the fluid inside. At high rotation rates and low temperature differences, the flow became chaotic and ultimately fully turbulent. The inclusion of sloping top and bottom boundaries caused turbulent eddies to behave like planetary waves at large scales, and eddy interaction with the zonal flow then led to the formation of several alternating jets at mid-depth. The jets did not scale with the Rhines length, and spectral analysis of the flow indicated a distinct separation between jets and eddies in wavenumber space, with direct energy transfer occurring nonlocally between them. Our results suggest that the traditional ``turbulent cascade'' picture of zonal jet formation may be an inappropriate one in the geophysically important case of large-scale flows forced by differential solar heating.
Hiro Yamazaki Y.
Read Peter L.
Wordsworth Robin D.
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