Abstract
Abstract. Oceanic eddies exist throughout the world oceans, but are more energetic when associated with western boundary currents (WBC) systems. In these regions, eddies play an important role in mixing and energy exchange. Therefore, it is important to quantify and qualify eddies associated with these systems. This is particularly true for the Southern Hemisphere WBC system where only few eddy censuses have been performed to date. In these systems, important aspects of the local eddy population are still unknown, like their spatial distribution and propagation patterns. Moreover, the understanding of these patterns helps to establish monitoring programs and to gain insight in how eddies would affect local mixing. Here, we use a global eddy data set to qualify eddies based on their surface characteristics in the Agulhas Current (AC), the Brazil Current (BC) and the East Australian Current (EAC) systems. The analyses reveal that eddy propagation within each system is highly forced by the local mean flow and bathymetry. Large values of eddy amplitude and temporal variability are associated with the BC and EAC retroflections, while small values occur in the centre of the Argentine Basin and in the Tasman Sea. In the AC system, eddy polarity dictates the propagation distance. BC system eddies do not propagate beyond the Argentine Basin, and are advected by the local ocean circulation. EAC system eddies from both polarities cross south of Tasmania but only the anticyclonic ones reach the Great Australian Bight. For all three WBC systems, both cyclonic and anticyclonic eddies present a geographical segregation according to radius size and amplitude. Regions of high eddy kinetic energy are associated with the eddies' mean amplitudes, and not with their densities.
Highlights
Oceanic mesoscale eddies are defined by a closed circulation (Cushman-Roisin and Beckers, 2006), having an internal water parcel with different characteristics from the surrounding fluid (Flierl, 1979)
While high mean eddy kinetic energy (EKE) is associated with the western boundary currents (WBC) retroflection regions, high eddy density seems not to be the case
In the Agulhas Current (AC) system, high mean EKE values occur in the AC retroflection (∼ 17◦ E, 37◦ S) and expand further west, reaching the Cape Basin
Summary
Oceanic mesoscale eddies are defined by a closed circulation (Cushman-Roisin and Beckers, 2006), having an internal water parcel with different characteristics from the surrounding fluid (Flierl, 1979). Despite being found in all oceans, eddies are most intense when associated with western boundary currents (WBCs) (Chelton et al, 2011) In these highly energetic regions, eddies often originate from mean flow instabilities being shed by the currents’ meanders. The WBCs of the Southern Hemisphere subtropical gyres are the Agulhas Current (AC) the Brazil Current (BC), and the East Australian Current (EAC) These currents abruptly separate from the coast, in a process normally associated with the formation of a quasi-stationary retroflection meander (da Silveira et al, 1999; Fig. 1). This meander may occlude and shed a large anticyclonic eddy in a process forced by continental geography, bathymetry and wind patterns Smaller cyclonic and anticyclonic eddies participate on the complex energetic eddy field of WBCs and are an important part of the local circulation (e.g. Boebel et al, 2003; Bowen et al, 2005; Mata et al, 2006)
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