Layering and turbulence surrounding an anticyclonic oceanic vortex: <i>in situ</i> observations and quasi-geostrophic numerical simulations

Hua, Bach Lien; Ménesguen, Claire; Gentil, Sylvie Le; Schopp, Richard; Marsset, Bruno; Aiki, Hidenori

doi:10.1017/jfm.2013.369

Cited by 38 publications

(85 citation statements)

References 44 publications

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“…This suggests that tracer stirring may be an important process in the region. The presence of sharp PV jumps in the mixed layer (Figures a, a, and b), linked with horizontal variability of the current field, also suggest that critical‐level of instability could play a role in the location of the layering around the eddy (Hua et al, ; Nguyen et al, ).…”

Section: Discussionmentioning

confidence: 99%

Dynamical Characterization of a Low Oxygen Submesoscale Coherent Vortex in the Eastern North Atlantic Ocean

Pietri

Karstensen

2018

JGR Oceans

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A submesoscale coherent vortex (SCV) with a low oxygen core is characterized from underwater glider and mooring observations from the eastern tropical North Atlantic, north of the Cape Verde Islands. The eddy crossed the mooring with its center and a 1 month time series of the SCV's hydrographic and upper 100 m currents structure was obtained. About 45 days after, and ∼100 km west, the SCV frontal zone was surveyed in high temporal and spatial resolution using an underwater glider. Satellite altimetry showed the SCV was formed about 7 months before at the Mauritanian coast. The SCV was located at 80–100 m depth, its diameter was ∼100 km and its maximum swirl velocity ∼0.4 m s−1. A Burger number of 0.2 and a vortex Rossby number 0.15 indicate a flat lens in geostrophic balance. Mooring and glider data show in general comparable dynamical and thermohaline structures, the glider in high spatial resolution, the mooring in high temporal resolution. Surface maps of chlorophyll concentration suggest high productivity inside and around the SCV. The low potential vorticity (PV) core of the SCV is surrounded by filamentary structures, sloping down at different angles from the mixed layer base and with typical width of 10–20 km and a vertical extent of 50–100 m.

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Section: Discussionmentioning

confidence: 99%

Dynamical Characterization of a Low Oxygen Submesoscale Coherent Vortex in the Eastern North Atlantic Ocean

Pietri

Karstensen

2018

JGR Oceans

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“…For long, it has been considered that lateral intrusions driven by double‐diffusion are causing the decay of Meddies. However, new theories on the origin of those intrusions were recently made implying flow instability and stirring processes [ Hua et al ., ; Meunier et al ., ]. Here it is hard to see any intrusion at the rim of the SCV, the gradients separating the SCV and the surroundings being pretty sharp for each eddy crossing by the glider (see Figure c).…”

Section: Discussionmentioning

confidence: 99%

A submesoscale coherent vortex in the Ligurian Sea: From dynamical barriers to biological implications

et al. 2017

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In June 2013, a glider equipped with oxygen and fluorescence sensors has been used to extensively sample an anticyclonic Submesoscale Coherent Vortex (SCV) in the Ligurian Sea (NW Mediterranean Sea). Those measurements are complemented by full‐depth CTD casts (T, S, and oxygen) and water samples documenting nutrients and phytoplankton pigments within the SCV and outside. The SCV has a very homogeneous core of oxygenated waters between 300 and 1200 m formed 4.5 months earlier during the winter deep convection event. It has a strong dynamical signature with peak velocities at 700 m depth of 13.9 cm s−1 in cyclogeostrophic balance. The eddy has a small radius of 6.2 km corresponding to high Rossby number of −0.45. The vorticity at the eddy center reaches −0.8f. Cross‐stream isopycnic diffusion of tracers between the eddy core and the surroundings is found to be very limited due to dynamical barriers set by the SCV associated with a diffusivity coefficient of about 0.2 m2 s−1. The deep core is nutrients‐depleted with concentrations of nitrate, phosphate, and silicate, 13–18% lower than the rich surrounding waters. However, the nutriclines are shifted of about 20–50 m toward the surface thus increasing the nutrients availability for phytoplankton. Chlorophyll‐a concentrations at the deep chlorophyll maximum are subsequently about twice bigger as compared to outside. Pigments further reveal the predominance of nanophytoplankton inside the eddy and an enhancement of the primary productivity. This study demonstrates the important impact of postconvective SCVs on nutrients distribution and phytoplankton community, as well as on the subsequent primary production and carbon sequestration.

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“…An analysis of several model runs (not shown here) indicates that most of the simulated ACes are close to Gaussian in profile and elliptical in shape. Thus, HRS is quadripolar (Figure a), whose mode 2 deformation is due to the shear of neighboring currents and eddies (Hua et al, ). These elements support our interpretation that subduction is important in creating the minimum stratification layers conducting to C‐BCIs at the mode waters depths.…”

Section: Upper Layers Dynamicsmentioning

confidence: 99%

Mesoscale and Submesoscale Processes in the Southeast Atlantic and Their Impact on the Regional Thermohaline Structure

et al. 2018

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The turbulent processes in the Cape Basin, the southeasternmost gate of the Atlantic Ocean, play a key role in the transport and mixing of upper to intermediate water masses entering the area from the Indian Ocean, making them especially relevant for the Indo‐Atlantic transfer of heat and salt. In this paper, two numerical simulations at different horizontal resolutions are used to study mesoscale and submesoscale dynamics, their phenomenology, their evolution, and their impact on the local water masses. Submesoscale processes seasonally affect both, the upper and intermediate layers, but there are clear dynamical differences between the two layers. Several types of instabilities underline this spatial and temporal variability. Near the surface, mixed layer instabilities occur during winter, while mesoscale‐driven instabilities, as the symmetric type, prevail in summer. The connection between these two seasonal regimes is ensured, in anticyclonic eddies and within the mixed layers, by Charney baroclinic instabilities, involved in the local formation and subduction of mode water, that we have dubbed as Agulhas Rings mode water. Intermediate depths are instead characterized by mesoscale mechanisms of density compensation and lateral stirring of the tracer variance, triggering a significant filamentogenesis whose vertical scales are comparable to those mentioned in previous studies. This leads to a particularly efficient mixing of Antarctic Intermediate Waters of Indian and Atlantic origins. Lagrangian estimates highlight the new and significant role of fine scale structures in setting the water masses properties of upper and lower thermocline waters materializing the Indo‐Atlantic exchange and therefore potentially affecting the global ocean circulation.

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Layering and turbulence surrounding an anticyclonic oceanic vortex: in situ observations and quasi-geostrophic numerical simulations

Cited by 38 publications

References 44 publications

Dynamical Characterization of a Low Oxygen Submesoscale Coherent Vortex in the Eastern North Atlantic Ocean

Dynamical Characterization of a Low Oxygen Submesoscale Coherent Vortex in the Eastern North Atlantic Ocean

A submesoscale coherent vortex in the Ligurian Sea: From dynamical barriers to biological implications

Mesoscale and Submesoscale Processes in the Southeast Atlantic and Their Impact on the Regional Thermohaline Structure

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