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Experiments on Ekman layer instability

Published online by Cambridge University Press:  28 March 2006

P. R. Tatro
Affiliation:
Massachusetts Institute of Technology Department of Meteorology
E. L. Mollo-Christensen
Affiliation:
Massachusetts Institute of Technology Department of Meteorology

Abstract

Laboratory measurements were made of the instabilities of the Ekman layer using hot wire anemometers. The apparatus consisted of two parallel circular rotating plates forming a spool; the air was admitted through screens at the outer edge and removed through a screen cage at the hub. In the Ekman layers formed on the inner surfaces of the plates, measurements were made of the mean velocities as functions of r and a; the velocity fluctuations were also measured.

It appears that the instability labelled type II by Faller always occurs first, and at zero Rossby number the critical Reynolds number is 56 ± 2. This instability originates in the boundary layer, but at slightly higher Reynolds number the fluctuations persist far into the geostrophic region, probably as inertial waves excited by the boundary-layer fluctuations.

At higher Reynolds number another instability appears of shorter wavelength and slower speed. This instability is confined to the boundary layer and is apparently the type I reported by Faller.

The phase speeds, frequencies, and wave-front orientations of both type instabilities have been measured.

Type
Research Article
Copyright
© 1967 Cambridge University Press

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