Horizontal and vertical structure of observed tropospheric equatorial
Rossby waves
George N. Kiladis and M. Wheeler
1995: J. Geophys. Res., 100, 22981-22997.
Abstract
Equatorial Rossby (ER) waves are identified in an 8-year data set of
National Meteorological Center
operational analyses. The westward moving waves have symmetric circulations
about the equator and eastward energy dispersion, with maximum zonal wind
perturbations along the equator and meridional wind maxima
roughly 10°-15° off
the equator. They have maximum amplitude in the lower troposphere and are
associated with convective signals at roughly the mean latitude of the tropical
convergence zones. The circulations thus possess many of the features of the
equatorially trapped n = 1 Rossby modes derived by
Matsuno [1966]. They are
generally around zonal planetary wavenumber 6 scale and have a deep, nearly
equivalent barotropic structure up to 100 mbar. This is in contrast with the
Madden-Julian Oscillation and mixed Rossby gravity waves, which generally have a
first baroclinic mode vertical structure.
During the intensive observing period (IOP) of the Tropical Ocean
Global Atmosphere (TOGA) Coupled Ocean-Atmosphere Response Experiment
(COARE) and in other years,
westward propagating ER disturbances along the equator are observed
by using 6- to 30-day
filtered circulation data at 850 mbar. Zonal wind anomalies at 850 mbar
are preferentially associated with like-signed anomalies in a deep layer at this
frequency, as was observed during COARE.
The ER waves are most common during
northern winter in the central Pacific,
although they can be detected sporadically over the other ocean basins and in
other seasons as well. One source for the equatorial Rossby waves appears to be
upper level extratropical Rossby wave activity propagating into the eastern
Pacific, although the equatorial waves are sometimes present during the northern
summer when the extratropical source is absent. We cite evidence that
propagation of ER wave activity from the central into the western Pacific is
related to occurrences of westerly wind bursts.