Mesoscale eddies in the northeastern Pacific tropical‐subtropical transition zone: Statistical characterization from satellite altimetry

Kurczyn, J. A.; Beier, Emilio; Lavín, Miguel F.; Chaigneau, Alexis

doi:10.1029/2012jc007970

Cited by 79 publications

(97 citation statements)

References 48 publications

(84 reference statements)

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“…These long-lived trajectories represent between 35% and 50% of the number of tracks formed near the coast, the rest are short-lived eddies. Note that it does not exist an official definition for ''long-lived eddies'' and, depending on the authors, the choice of their minimal duration can vary from a few weeks to several months [e.g., Fang and Morrow, 2003;Chaigneau and Pizarro, 2005;Chaigneau et al, 2008;Sangr a et al, 2009;Kurczyn et al, 2012;Chelton et al, 2007Chelton et al, , 2011Chaigneau et al, 2009;Chen et al, 2011]. Here we refer to ''long-lived eddies'' as eddies having a lifetime longer than 30 days, that is consistent with previous studies Figure 2.…”

Section: 1002/2015jc010950supporting

confidence: 77%

Main eddy vertical structures observed in the four major Eastern Boundary Upwelling Systems

2015

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In the four major Eastern Boundary Upwelling Systems (EBUS), mesoscale eddies are known to modulate the biological productivity and transport near‐coastal seawater properties toward the offshore ocean, however little is known about their main characteristics and vertical structure. This study combines 10 years of satellite‐altimetry data and Argo float profiles of temperature and salinity, and our main goals are (i) to describe the main surface characteristics of long‐lived eddies formed in each EBUS and their evolution, and (ii) to depict the main vertical structure of the eddy‐types that coexist in these regions. A clustering analysis of the Argo profiles surfacing within the long‐lived eddies of each EBUS allows us to determine the proportion of surface and subsurface‐intensified eddies in each region, and to describe their vertical structure in terms of temperature, salinity and dynamic height anomalies. In the Peru‐Chile Upwelling System, 55% of the sampled anticyclonic eddies (AEs) have subsurface‐intensified maximum temperature and salinity anomalies below the seasonal pycnocline, whereas 88% of the cyclonic eddies (CEs) are surface‐intensified. In the California Upwelling System, only 30% of the AEs are subsurface‐intensified and all of the CEs show maximum anomalies above the pycnocline. In the Canary Upwelling System, ∼40% of the AEs and ∼60% of the CEs are subsurface‐intensified with maximum anomalies extending down to 800 m depth. Finally, the Benguela Upwelling System tends to generate ∼40–50% of weak surface‐intensified eddies and ∼50–60% of much stronger subsurface‐intensified eddies with a clear geographical distribution. The mechanisms involved in the observed eddy vertical shapes are discussed.

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Section: 1002/2015jc010950supporting

confidence: 77%

Main eddy vertical structures observed in the four major Eastern Boundary Upwelling Systems

2015

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“…For the TANWA these hot spots are associated with the headlands of Cap-Vert (Senegal) and Cap Timris (Mauretania). We could also confirm the existence of a seasonality in the eddy generation (Chaigneau et al, 2009;Kurczyn et al, 2012) and found cyclones form preferably during April to June, while anticyclones and ACMEs are mostly generated from October to December. After their generation, eddies of all three types propagate westward with a speed, c, of about 3.00 ± 2.15 km d −1 , which is in general agreement with the first baroclinic mode Rossby wave phase speed at that latitude range (Chelton et al, 1998).…”

Section: Discussionsupporting

confidence: 64%

Occurrence and characteristics of mesoscale eddies in the tropical northeastern Atlantic Ocean

2016

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Abstract. Coherent mesoscale features (referred to here as eddies) in the tropical northeastern Atlantic Ocean (between 12-22 • N and 15-26 • W) are examined and characterized. The eddies' surface signatures are investigated using 19 years of satellite-derived sea level anomaly (SLA) data. Two automated detection methods are applied, the geometrical method based on closed streamlines around eddy cores, and the Okubo-Weiß method based on the relation between vorticity and strain. Both methods give similar results. Mean eddy surface signatures of SLA, sea surface temperature (SST) and sea surface salinity (SSS) anomalies are obtained from composites of all snapshots around identified eddy cores. Anticyclones/cyclones are identified by an elevation/depression of SLA and enhanced/reduced SST and SSS in their cores. However, about 20 % of all anticyclonically rotating eddies show reduced SST and reduced SSS instead. These kind of eddies are classified as anticyclonic mode-water eddies (ACMEs). About 146 ± 4 eddies per year with a minimum lifetime of 7 days are identified (52 % cyclones, 39 % anticyclones, 9 % ACMEs) with rather similar mean radii of about 56 ± 12 km. Based on concurrent in situ temperature and salinity profiles (from Argo float, shipboard, and mooring data) taken inside of eddies, distinct mean vertical structures of the three eddy types are determined. Most eddies are generated preferentially in boreal summer and along the West African coast at three distinct coastal headland regions and carry South Atlantic Central Water supplied by the northward flow within the Mauretanian coastal current system. Westward eddy propagation (on average about 3.00 ± 2.15 km d −1 ) is confined to distinct zonal corridors with a small meridional deflection dependent on the eddy type (anticyclones -equatorward, cyclones -poleward, ACMEs -no deflection). Heat and salt fluxes out of the coastal region and across the Cape Verde Frontal Zone, which separates the shadow zone from the ventilated subtropical gyre, are calculated.

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“…The highest coastal upwelling rate in the CCS occurs in spring (Kurczyn et al 2012). This upwelling, combined with an especially strong equatorward flowing California Current, can explain the observed lowest …”

Section: ) Surroundings Of the Tropical Pacific Off Central Mexicomentioning

confidence: 99%

“…The poleward flow of the MCC corresponds to the cyclonic phase of this annual Rossby wave, but there are no studies to date that have described its complete seasonal and interannual variation. In the mesoscale, the dynamics of the TPCM are dominated by intense eddy activity (Kurczyn et al 2012(Kurczyn et al , 2013Lavín et al 2013). This current pattern, including the continuous exchanges through the entrance of the Gulf of California (Collins et al 2015), govern the spatial distribution and temporal variability of the water masses in the TPCM.…”

Section: Introductionmentioning

confidence: 99%

Water Masses and Circulation in the Tropical Pacific off Central Mexico and Surrounding Areas

Portela

Beier

Barton

et al. 2016

Journal of Physical Oceanography

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The seasonal variations and the interactions of the water masses in the tropical Pacific off central Mexico (TPCM) and four surrounding areas were examined based on an extensive new hydrographic database. The regional water masses were redefined in terms of absolute salinity (S A ) and conservative temperature (Q) according to the Thermodynamic Equation of Seawater 2010 (TEOS-10). Hydrographic data and the evaporation minus (precipitation 1 runoff) balance were used to investigate the origin and seasonality of two salinity minima in the area. The shallow (50-100 m) salinity minimum originates with the California Current System and becomes saltier as it extends southeastward and mixes with tropical subsurface waters while the surface salinity minimum extends farther north in the TPCM in summer and fall because of the northward advection of tropical surface waters. The interactions between water masses allow a characterization of the seasonal pattern of circulation of the Mexican Coastal Current (MCC), the tropical branch of the California Current, and the flows through the entrance of the Gulf of California. The seasonality of the MCC inferred from the distribution of the water masses largely coincides with the geostrophic circulation forced by an annual Rossby wave.

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Mesoscale eddies in the northeastern Pacific tropical‐subtropical transition zone: Statistical characterization from satellite altimetry

Cited by 79 publications

References 48 publications

Main eddy vertical structures observed in the four major Eastern Boundary Upwelling Systems

Main eddy vertical structures observed in the four major Eastern Boundary Upwelling Systems

Occurrence and characteristics of mesoscale eddies in the tropical northeastern Atlantic Ocean

Water Masses and Circulation in the Tropical Pacific off Central Mexico and Surrounding Areas

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