Rossby wave

Rossby (or planetary) waves are giant meanders in high-altitude winds that are a major influence on weather. Their emergence is due to shear in rotating fluids, so that the Coriolis force changes along the sheared coordinate. In planetary atmospheres, they are due to the variation in the Coriolis effect with latitude. The waves were first identified in the Earth's atmosphere in 1939 by Carl-Gustaf Arvid Rossby who went on to explain their motion. Rossby waves are a subset of inertial waves.

Terrestrial waves

The special identifying feature of the Rossby waves is its phase velocity (that of the wave crests) always has a westward component. However, the wave's group velocity (associated with the energy flux) can be in any direction. In general: shorter waves have an eastward group velocity and long waves a westward group velocity.

The terms "barotropic" and "baroclinic" Rossby waves are used to distinguish their vertical structure. Barotropic Rossby waves do not vary in the vertical, and have the fastest propagation speeds. The baroclinic wave modes are slower, with speeds of only a few centimetres per second or less.

Atmospheric waves

[
northern hemisphere's jet stream developing (a, b) and finally detaching a "drop" of cold air (c). Orange: warmer masses of air; pink: jet stream.] Rossby waves in the atmosphere are easy to observe as (usually 4-6) large-scale meanders of the jet stream. When these loops become very pronounced, they detach the masses of cold, or warm, air that become cyclones and anticyclones and are responsible for day-to-day weather patterns at mid-latitudes.

The wave speed is given by

:

where "c" is the wave speed, "u" is the mean westerly flow, "" is the Rossby parameter, and "k" is the total wavenumber.

Furthermore, the Rossby parameter is defined::"φ" is the latitude, "ω" is the angular speed of the Earth's rotation, and "a" is the mean radius of the Earth.

Oceanic waves

Oceanic Rossby waves are thought to communicate climatic changes due to variability in forcing, due to both the wind and buoyancy. Both barotropic and baroclinic waves cause variations of the sea surface height, although the length of the waves made them difficult to detect until the advent of satellite altimetry. Observations by the NASA/CNES TOPEX/Poseidon satellite confirmed the existence of oceanic Rossby waves [Chelton, D. B., and M. G. Schlax. 1996. "Global observations of oceanic Rossby waves." . 272:234-38 (12 April 1996)]

Baroclinic waves also generate significant displacements of the oceanic thermocline, often of tens of meters. Satellite observations have revealed the stately progression of Rossby waves across all the ocean basins, particularly at low- and mid-latitudes. These waves can take months or even years to cross a basin like the Pacific.

Bibliography

* Rossby, C-G (1939), Relation between variations in the intensity of the zonal circulation of the atmosphere and the displacements of the semi-permanent centers of action, "J. Marine Research" pp38-55
* Platzman, G (1968) The Rossby wave, "Quart. J. Roy. Meteorol. Soc." pp94-248
* Dickinson, R E (1978) Rossby waves - long-period oscillations of oceans and atmospheres, "Ann. Rev. Fluid Mech." pp10-195

References

ee also

*Atmospheric wave
*Harmonic waves

External links

* [http://amsglossary.allenpress.com/glossary/search?p=1&query=Rossby+wave&submit=Search Rossby Waves, from the American Meteorological Society]
* [http://www.noc.soton.ac.uk/JRD/SAT/Rossby/Rossbyintro.html An introduction to oceanic Rossby waves and their study with satellite data]