Mean meridional currents in the central and eastern equatorial Atlantic

TitleMean meridional currents in the central and eastern equatorial Atlantic
Publication TypeJournal Article
Year of Publication2014
AuthorsPerez R.C, Hormann V., Lumpkin R, Brandt P., Johns W.E, Hernandez F., Schmid C., Bourles B.
JournalClimate Dynamics
Volume43
Pagination2943-2962
Date Published2014/12
Type of ArticleArticle
ISBN Number0930-7575
Accession NumberWOS:000344862200005
Keywordsatmospheric variability; cold-tongue; Data assimilation; drifter observations; instability waves; long waves; Meridional currents; north-atlantic; pacific-ocean; tropical atlantic; Tropical cells; upper-ocean
Abstract

Ship-based acoustic Doppler current profiler (ADCP) velocity measurements collected by several major field programs in the tropical Atlantic are averaged and combined with estimates of the mean near-surface velocity derived from drifters and Argo float surface drifts (ADCP+D) to describe the mean cross-equatorial and vertical structure of the meridional currents along 23 degrees W and 10 degrees W. Data from moored ADCPs and fixed-depth current meters, a satellite-derived velocity product, and a global ocean reanalysis were additionally used to evaluate the mean ADCP+D meridional velocity. The dominant circulation features in the long-term mean ADCP+D meridional velocity in the upper 100 m are the tropical cells (TCs) located approximately between 5 degrees S and 5 degrees N, with near-surface poleward flow and subsurface equatorward flow that is stronger and shallower in the northern cell compared to the southern cell. The thickness of the surface limb of the TCs decreases and the northern cell is found to shift further south of the equator from the central to eastern tropical Atlantic. Analysis of two-season means estimated from the ship-based ADCP, near-surface drift, and moored velocity data, as well as the simulated fields, indicates that the maximum poleward velocity in the surface limb of the TCs intensifies during December-May along 23 degrees W largely due to seasonal compensation between the geostrophic and ageostrophic (or wind-driven) components of the meridional velocity, whereas the maximum equatorward flow in the subsurface limb of the northern cell intensifies during June-November along both 23 degrees W and 10 degrees W due to the seasonality of the geostrophic meridional velocity.

DOI10.1007/s00382-013-1968-5
Short TitleClim. Dyn.
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