2.1 Survey description

An interdisciplinary oceanographic survey was conducted aboard the R/V Sarmiento de Gamboa from 9 November to 4 December 2022, as part of the Biogeochemical Impact of Mesoscale and Sub-mesoscale Processes Along the Life History of Cyclonic and Anticyclonic Eddies (eIMPACT) project. This survey, called the eIMPACT2 survey, targeted a mature AE which originated southwest of Gran Canaria island (GCI). The eddy has been named Bentayga, inspired by the Saharan-Berber heritage of the Canarian aborigines, reflecting its connection to Saharan upwelling waters off the northwestern African coast. At the time of the survey, it was approximately 4.5 months old and had traveled 560 km from its formation site (Fig. ).

Map of the study area in the Canary Eddy Corridor (CEC) during the eIMPACT2 survey (9 November–4 December 2022). Land and the continental shelf (0 and 200 m depth) are shown in light and dark gray for the Canary Islands and the northwestern African coast, respectively. Bathymetric contours are drawn every 500 m from 500 to 5000 m depth (thin black lines). The thick black lines represent the ship's grid-like trajectory during the SeaSoar phase (9–14 November). White stars mark the locations of stations from the oceanographic transect (OceT, 19–28 November). The eddy is depicted by its first detection (dark red circle), its trajectory (thick dark red line with dates), and the areas enclosed by the contour of maximum swirl speed on two key dates: (i) the start of the eIMPACT2 survey (9 November) and (ii) during sampling at OceT station 18 (25 November), shown as light red patches.

[Figure omitted. See PDF]

CTD-O (conductivity, temperature, depth – oxygen) data, collected using a towed undulating vehicle (SeaSoar Mk II; Chelsea Technologies Group) equipped with a Sea-Bird SBE911plus system and an adjoined SBE43 dissolved oxygen sensor, together with VMADCP (vessel-mounted acoustic Doppler current profiler; RDI Ocean Surveyor, 75 kHz) records, were gathered during the eIMPACT2 SeaSoar phase (9–14 November 2022) to construct three-dimensional hydrographic and dynamical fields of the eddy and its surroundings. This phase employed a southwest–northeast sampling grid comprising seven transects (278 km each), separated by $\sim \mathrm{22}$ km, and sampled vertical levels between 30 and 340 m. A total of 955 CTD-O casts were recorded, with an average horizontal spacing of $\sim \mathrm{2}$ km; continuous VMADCP measurements, providing horizontal velocity profiles from approximately 30 to 800 m depth with 16 m vertical resolution, were acquired concurrently along the same grid.

In addition to the SeaSoar phase, the eIMPACT2 cruise included the OceT phase (19–28 November 2022), during which vertical CTD-O profiles were acquired using a Sea-Bird SBE911plus system equipped with an SBE43 dissolved oxygen sensor mounted on a rosette system, along a nearly zonal transect (OceT) crossing the eddy from east to west. This phase was selected for the present study to investigate the mature stage of the Bentayga eddy. The OceT comprised 26 stations (stations 02–27), spaced $\sim \mathrm{12.7}$ $\pm$ 2.8 km apart, and extended from the surface to $\sim \mathrm{1500}$ m depth (Fig. ). Alongside these profiles, continuous VMADCP velocity measurements spanning $\sim \mathrm{30}$–800 m depth were recorded throughout the transect.

Given the duration of the two selected sampling phases – 5 d for the SeaSoar phase and 10 d for the OceT – it was necessary to assess how this temporal spread might have affected or distorted our representation of the Bentayga eddy, particularly in analyses relying on its spatial delineation. To this end, we conducted a synopticity analysis, the results of which are presented in the Sect. S1 in the Supplement. Intuitively, one might expect a quasi-synoptic sampling during the SeaSoar phase and a more asynchronous (non-synoptic) representation during OceT. Remarkably, the SeaSoar transects exhibited high synopticity, with an estimated eddy deformation of only $\sim \mathrm{1}$%. By contrast, OceT introduced a distortion of approximately 12.6% $\pm$ 6.2%. However, sensitivity analyses of our eddy-core diagnostics and derived estimates (Sects. S4–S6) indicate that the observed core deformation has a limited impact on the key results. These findings provide a certain degree of confidence in the analyses presented in the following sections.

Raw CTD-O data from both phases were processed at 1 m intervals using the manufacturer's software, and TEOS-10 algorithms were applied to compute derived variables such as absolute salinity ($S_{\mathrm{A}}$), conservative temperature ($\mathrm{\Theta }$), potential density anomaly (${\mathit{\sigma }}_{\mathit{\theta }}$), and Brunt–Väisälä frequency ($N$) . VMADCP data were processed using the CODAS software (https://currents.soest.hawaii.edu/docs/adcp_doc/, last access: 7 March 2023), resulting in 16 m vertical bins for both phases . Dissolved oxygen (${\mathrm{O}}_{\mathrm{2}}$) data collected during the OceT phase were calibrated against discrete water samples analyzed using the potentiometric Winkler method, following the protocol of . The calibration yielded a linear relationship with a slope of 1.0957, an offset of $-\mathrm{1.0462}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$, and a coefficient of determination $R^{\mathrm{2}}=\mathrm{0.9908}$. The precision of the Winkler titrations, expressed as the coefficient of variation, was 0.54 % ($\pm \mathrm{1.01}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$). Although no discrete ${\mathrm{O}}_{\mathrm{2}}$ samples were obtained during the SeaSoar phase due to its continuous sampling design, ${\mathrm{O}}_{\mathrm{2}}$ records from both phases were highly consistent, indicating stable and reliable sensor performance throughout the cruise.

To reduce noise in the OceT data, a two-dimensional Gaussian filter with horizontal and vertical scales of 12 km and 8 m, respectively, was applied to minimize the influence of unresolved short-scale fluctuations. These scales were estimated from the spatial autocorrelation of the noise field, reconstructed from high-order empirical orthogonal function (EOF) modes (modes $\ge \mathrm{4}$), using an integral length-scale analysis. For the SeaSoar phase, CTD-O and VMADCP datasets were objectively interpolated onto a regular $\mathrm{11}\mathrm{km}\times \mathrm{11}\mathrm{km}$ grid at 16 m VMADCP levels. This process assumed planar mean CTD variables and constant mean VMADCP velocities , employing a circular Gaussian covariance model with a 44 km scale ($L_x=L_y$), approximating the theoretical Rossby radius , and incorporating 3 % uncorrelated noise in the final fields .

2.2 Satellite information and derived products

The Atlas of Mesoscale Eddy Trajectories (META3.2exp), developed by SSALTO/DUACS and distributed by AVISO+ with the support of CNES, in collaboration with IMEDEA (https://www.aviso.altimetry.fr/, last access: 7 July 2024), was used to track the geometric and dynamic properties of the Bentayga eddy throughout its life cycle, from formation to dissipation. The use of the near-real-time (NRT) product was necessary, as the delayed-time (DT) version does not fully cover the period associated with the evolution of Bentayga. However, the META3.2 DT allsat product was used to provide a climatological reference for the eddy's trajectory, particularly to contextualize its interaction with filaments from the northwestern African upwelling system. The atlas is based on the global detection and tracking of mesoscale eddies using altimetry data from multiple platforms, applying the eddy detection method of to provide daily information on eddy location, speed, radius, and other characteristics and classifying them by gyre type (CE and AE). This information was complemented with sea level anomaly and geostrophic current fields obtained from the European Seas Gridded L4 Sea Surface Height and Derived Variables NRT altimetry product (SEALEVEL_EUR_PHY_L4_NRT_008_060), processed by the DUACS multi-platform altimetry system and distributed by the Copernicus Marine Service (https://marine.copernicus.eu, last access: 24 November 2023).

To characterize the interaction between the circulation driven by this eddy and the upwelling fronts and filaments off the northwest African coast, we used daily fields of sea surface temperature (SST) from the GHRSST Level 4 MUR Global Foundation Sea Surface Temperature Analysis product. This dataset, with a resolution of $\mathrm{1}\mathrm{km}\times \mathrm{1}\mathrm{km}$, is distributed by PO.DAAC . In addition, satellite chlorophyll $a$ data, with a resolution of $\mathrm{4}\mathrm{km}\times \mathrm{4}\mathrm{km}$, were obtained from the Global Ocean Colour Bio-Geo-Chemical Level 3 product distributed by the EU Copernicus Marine Service Information . Both of these products are derived from a combination of satellite information from all available platforms, utilizing specific processing, analysis, and merging schemes .

2.3 Dynamical properties

3.1 Lagrangian evolution as seen from satellite altimetry data

The Bentayga eddy formed south of GCI in June 2022, with its first detection recorded on 23 June (Figs. –). Shortly after formation, during its growth phase, it drifted away from GCI almost immediately (see trajectory and respective dates in Figs.  and ). The initial 20 d were characterized by a rapid southwestward movement, which later shifted to an almost eastward direction, with speeds $\ge \mathrm{10}$ $\mathrm{km}{\mathrm{d}}^{-\mathrm{1}}$, covering approximately 170 km from the origin to the continental margin of NW Africa, near Cape Bojador ($\sim \mathrm{26.1}$° N). During this phase, significant growth was observed only in its radius defined by the contour of maximum circum-averaged speed (Fig. c). It remained in this region for over 2 weeks, during which it interacted with upwelling filaments extending from Cape Juby to the north and Cape Bojador to the south (Fig. b). Throughout this period, the sea level anomaly (SLA) amplitude and swirl speed increased considerably, rising by approximately 4 cm and 15 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$, respectively (Fig. a and b). This behavior gave a strong nonlinear character to the Bentayga eddy, as indicated by $\mathit{\vartheta }>\mathrm{5}$ (Fig. e), a feature that persisted throughout the analyzed period.

Sea level anomaly snapshots (color map and thin gray contours) and geostrophic currents (black arrows) derived from satellite altimetry. The panels show the eddy's evolution from its first detection on 23 June 2022 through its various phases, including the eIMPACT2 survey, to its dissipation on 18 June 2023 (trajectory indicated by red circles). White stars denote oceanographic station locations during the eIMPACT2 OceT phase.

[Figure omitted. See PDF]

Time series of geometric and dynamic properties of the eddy from its first detection (23 June 2022) to its dissipation (18 June 2023). Panels show (a) amplitude, (b) swirl speed, (c) radius, (d) Rossby number (calculated as the ratio between the swirl speed and radius, normalized by $f$), and (e) the nonlinearity parameter ($\mathit{\vartheta }$, estimated as the ratio of swirl to translational speeds). In panel (e), the translational speed is indicated by the gray line, while black and red horizontal lines represent thresholds for nonlinearity ($\mathit{\vartheta }>\mathrm{1}$) and strong nonlinearity ($\mathit{\vartheta }>\mathrm{5}$) . Pale red and gray shaded areas across all panels highlight periods when the eddy was near the NW African continental margin and during the eIMPACT2 survey, respectively. Vertical dashed lines indicate the onset and end of its mature phase.

[Figure omitted. See PDF]

By the end of July, it began to move northwestward into the open ocean, maintaining this trajectory while continuing to exhibit gradual increases in the aforementioned features until 15 August (Figs.  and ). At this stage, peak values were reached in amplitude ($\sim \mathrm{20}$ cm), swirl speed ($\sim \mathrm{55}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$), and radius ($\sim \mathrm{55}$ km), with Rossby number (Ro) values of $\sim \mathrm{0.16}$ (Fig. a–d). These relatively higher values were sustained until the early days of November (Fig. a–c), when the temporal evolution of these features displayed a plateau behavior, particularly evident in the SLA amplitude and swirl speed, even after accounting for the 15–30 d fluctuations observed throughout its life cycle (Fig. a and b). This plateau indicates that the Bentayga eddy had entered its mature phase by this time, with mean values of approximately $\sim \mathrm{18}$ $\pm$ 2 cm for SLA amplitude, $\sim \mathrm{45}$ $\pm$ 4 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$ for swirl speed, and $\sim \mathrm{50}$ $\pm$ 5 km for radius. The temporal evolution of its Ro values and nonlinear character also evolved into a plateau during this phase (Fig. d and e); however, for Ro, it persisted only until mid-October, with a mean magnitude of approximately 0.15. Throughout this phase, it primarily followed a southwestward trajectory (Figs.  and c and d), although a northwestward deflection was observed in its path between mid-September and early October (Fig. ).

Starting in the first weeks of November, a gradual decline in all the previously described properties became evident (Fig. ), indicating that the eIMPACT2 survey occurred at the onset of this slow decline in the dynamic properties during the eddy's mature phase. Such a smooth and gentle decrease in the magnitude of the eddy's dynamic properties during this phase has been previously observed in the CANUS and other EBUSs . During the eIMPACT2 survey, the Bentayga eddy moved with a translational speed ($c$) of 4.5 $\pm$ 1.2 $\mathrm{km}{\mathrm{d}}^{-\mathrm{1}}$ and displayed a mean SLA amplitude of 15 $\pm$ 1 $\mathrm{cm}$, swirl speed of 38 $\pm$ 2 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$, radius of 55 $\pm$ 3 km, mean Ro values of 0.11, and a strong nonlinear character ($\mathit{\vartheta }>\mathrm{5}$). A few days after the campaign concluded, the nearly linear decline in these properties was interrupted by shorter-period fluctuations (with a temporal scale of 10–20 d), particularly noticeable in the SLA amplitude and radius. These fluctuations persisted until the end of its mature phase in mid-May 2023 (Fig. a and c). The onset of these shorter-scale fluctuations coincided with a slight northwestward deflection observed in the eddy's trajectory shortly after the end of the eIMPACT survey (6 December, Fig. ). Finally, from late May 2023 onward, the dynamical properties of the Bentayga eddy exhibited an abrupt decrease, marking its transition into the decay phase, which culminated in its dissipation on 18 June 2023.

The temporal evolution of the eddy properties was dominated by two main modes of variability (Fig. ). The first mode was a long-term component, spanning 7–11 months, associated with its overall life cycle: growth (mid-June 2022 to mid-August 2022), maturity (including the slow decline stage; mid-August 2022 to mid-May 2023), and rapid decay (starting in late May 2023) (Fig. ). The second mode of variability involved shorter-scale fluctuations, ranging from weeks to a few months, as identified through wavelet analysis (see Fig. ). Generally, these fluctuations displayed a degree of synchronicity among the analyzed properties, reflecting the dominance of geostrophic characteristics even at these timescales, as increases in SLA amplitude were systematically accompanied by increases in swirl speed. This relationship indicates that the eddy's velocity field remained primarily controlled by the pressure gradient force balanced by the Coriolis force. However, the relative energy contributions of these fluctuations differed: the SLA amplitude and eddy radius exhibited larger variations than those observed in the eddy's swirl speed variability, suggesting that shorter-scale fluctuations more strongly modulated the eddy's geometry and surface expression than its velocity field. This behavior could be interpreted as a mode of eddy pulsation, similar to that described by , suggesting a connection with changes in Bentayga's elliptical eccentricity and the presence of sharp meanders at its edges. These phenomena are likely due to eddy-to-eddy interactions or some form of submesoscale instability .

3.2 Circulation and hydrography

The following section describes the circulation and hydrography along the OceT transect. As previously noted, this transect reflects a distorted view of the eddy structure due to the lack of synopticity; however, the general features of its core remain identifiable (see Sects. S2 and S3). The rationale for using this dataset lies in its vertical extent, which enables a comprehensive view of the water column down to intermediate depths, effectively capturing the full vertical structure of the Bentayga eddy (see Sects. S4–S6).

Cross-transect velocities along the OceT (Fig. a) were primarily influenced by the anticyclonic circulation induced by the Bentayga eddy (stations 12–24, 120–280 km from OceT's origin). Stronger velocities ($>\mathrm{30}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$) extended from the surface to the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.5}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal depth, closely following its concave shape. Between stations 15–20 (175–225 km from OceT's origin), higher cross-transect velocities were observed at approximately 110–120 m depth ($>\mathrm{45}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$). However, at station 18, velocities were nearly zero throughout the entire depth profile, indicating proximity to its center (Fig. a and b). Starting from stations 15 and 20 towards the east and west, respectively, the vertical segment of higher velocities became slightly shallower, with stations 12 and 24 roughly marking the eastern and western boundaries of the eddy's exerted effect. This variation in the vertical position of the maximum cross-transect velocity layer suggests the presence of an inner core within, with a radius ($R_{\mathrm{c}}$) of $\sim \mathrm{23}$–25 km and an external surrounding ring approximately 45 km wide. This segmentation is consistent with the radial zonation presented in Sect. S3, where maximum azimuthal velocities are reached in the outer sector of the eddy at approximately 40 km from its center, gradually decreasing outward.

(a) Vertical section of cross-transect velocities (v) from VMADCP measurements along the OceT transect. Gray contours represent velocity levels at 5 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$ intervals, while black contours show isopycnals (${\mathit{\sigma }}_{\mathit{\theta }}$) ranging from 25.2 to 27.7 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ with 0.1 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ intervals. Vertical dashed lines indicate the positions of oceanographic stations, with only even station numbers labeled for clarity. (b) Vertical profiles of cross-transect velocities at the eddy's center (station 18) and at approximately the radial distance of maximum velocity ($r\approx \mathrm{40}$ km; refer to text for further details). Different vertical scales are applied for the 0–400 m and 400–1500 m depth ranges in both panels.

[Figure omitted. See PDF]

The surrounding ring spans roughly stations 20 and 24 to the west and stations 12 and 15 to the east – corresponding to distances of up to 70 km from the eddy center – with its lower (deeper) boundaries closely following the spatial behavior of the aforementioned isopycnal (Fig. a). Vertical profiles of cross-transect velocity (Fig. b) reveal a slight horizontal asymmetry, with stronger velocities occurring at deeper depths within the inner core and at shallower depths in the ring area (Fig. a and b). Although a closer examination of this sector indicates that it lacks spatial homogeneity (Fig. ), the deformation noted at the beginning of this section and the inherently higher variability in this area make it prone to misinterpretation. As such, a more detailed analysis of this sector is not pursued in the present study. Nevertheless, its presence adds complexity to the overall azimuthal velocity distribution, highlighting radial variations that could impact the stability and mixing properties of the Bentayga eddy . These circulation patterns remained spatially coherent above the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{26.6}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal. However, at greater potential density anomalies (26.7–27.4 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$), the anticyclonic circulation weakened ($<\mathrm{15}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$) and became more spatially disordered. Outside the observed horizontal boundaries of the Bentayga eddy, cross-transect velocities aligned with the external cyclonic circulation on either side (Fig. d).

From Fig. c, the deepening of the isopycnal surfaces is evident for ${\mathit{\sigma }}_{\mathit{\theta }}\ge \mathrm{25.4}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ between stations 12 and 24, with the seasonal pycnocline (associated with $N$ values $\ge \mathrm{5}$ cph) exhibiting a concave shape along this horizontal segment. In contrast, lighter isopycnals displayed a slight convex shape between stations 15 and 20 (175–225 km from OceT's eastern origin) along the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.2}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal. The presence of a deep surface mixed layer (extending from the surface to a depth of 80 m), containing even lighter waters ($<\mathrm{25.2}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$), along with a shallower and less intense pycnocline (with $N$ values of 3–4 cph), likely prevented doming of these lighter isopycnals. The core of the Bentayga eddy was centered between these shallower and deeper pycnoclines ($\sim \mathrm{110}$ m depth), enclosing nearly homogeneous water and forming a pycnostad with a mean potential density anomaly of 25.3 $\pm$ 0.05 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ ($N\le \mathrm{2.5}$ cph). As expected, outside the influence of the eddy (westward from station 24 and eastward from station 12), the density field was influenced by the cyclonic circulation on both sides, with a mesoscale elevation of water (isopycnal lifting) noticeable even at depths around 500 m (Fig. c).

Vertical sections along the OceT of (a) conservative temperature ($\mathrm{\Theta }$), (b) absolute salinity ($S_{\mathrm{A}}$), and (c) Brunt–Väisälä frequency ($N$). In panels (a) and (b), thick black contours correspond to ${\mathit{\sigma }}_{\mathit{\theta }}$ levels of 25.2, 25.5, 26.6, and 26.8 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$. In panel (c), black contours represent isopycnals (${\mathit{\sigma }}_{\mathit{\theta }}$) ranging from 25.2 to 27.7 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$, with a contour interval of 0.1 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$. Vertical dashed lines indicate the positions of oceanographic stations as shown in Fig. a. Consistent with Fig. , different vertical scales were applied for the 0–400 m and 400–1500 m depth ranges.

[Figure omitted. See PDF]

Most of the structures for the distribution of ${\mathit{\sigma }}_{\mathit{\theta }}$ along the OceT described above are also observed in the first 600 m of the vertical sections of $\mathrm{\Theta }$ and $S_{\mathrm{A}}$ (Fig. a and b). Between stations 12 and 24, the 12.5–22 $\mathrm{°}\mathrm{C}$ isotherms and 36–36.9 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$ isohalines exhibited the previously mentioned deepening. Signs of minor elevation in the horizontal segment between stations 15 and 20 were also noticeable along the 23 $\mathrm{°}\mathrm{C}$ isotherm and the 36.9 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$ isohaline, as well as a core of nearly constant temperature and salinity, with mean values of 22.5 $\pm$ 0.2 $\mathrm{°}\mathrm{C}$ and 36.83 $\pm$ 0.01 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$. This well-mixed core was vertically bounded by two sharp positive thermoclines ($\sim \mathrm{0.1}$ $\mathrm{°}\mathrm{C}{\mathrm{m}}^{-\mathrm{1}}$), a sharp positive upper halocline (0.02 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}{\mathrm{m}}^{-\mathrm{1}}$), and a weaker negative lower halocline ($-\mathrm{0.01}$ $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}{\mathrm{m}}^{-\mathrm{1}}$). In the $S_{\mathrm{A}}$ field, the structure of the eddy core was more clearly defined by the 36.8 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$ isohaline, forming a lens-like shape of relatively fresher water compared to the surrounding waters at the same vertical levels. This high degree of homogeneity is also discussed in Sects. S2 and S3 (see Figs. S4–S8) and matches the radial distance between the OceT data and the profiles used in those analyses well.

It is important to note that, aside from the mesoscale perturbations in the thermohaline properties along the OceT, their overall hydrographic distribution corresponded to the expected water mass composition for the region, with a dominance of 12 and 15 $\mathrm{°}\mathrm{C}$ Eastern North Atlantic Central Waters (ENACW12 and ENACW15, respectively) (Fig. ). At intermediate depths (700–1300 m), relatively colder and fresher waters were observed from station 7 westward (approximately 60 km from OceT's origin) (Fig. a and b). These waters were consistent with the thermohaline values and the higher contribution of the diluted Antarctic Intermediate Water (AAIW) previously described in this region at these depths . In this study, the acronym AA, from the nomenclature proposed by , will be used to refer to this water mass, as its thermohaline properties align with those observed locally in this region (Fig. ), albeit with slight variations from the classical definition of AAIW .

Conservative temperature ($\mathrm{\Theta }$) versus absolute salinity ($S_{\mathrm{A}}$) distribution along the OceT transect, presented as a $\mathrm{\Theta }-S_{\mathrm{A}}$ diagram. Gray dots represent data from all oceanographic stations. The thermohaline structure at the eddy center (station 18) is highlighted with a thick black continuous line. Thermohaline properties from regions outside eddy's influence, westward (station 26) and eastward (station 04), are depicted with thick blue and red dashed lines, respectively. Symbols mark typical source water masses for the area , including Madeira Mode Water (MMW), Eastern North Atlantic Central Water (ENACW15 and ENACW12, at 15 and 12 $\mathrm{°}\mathrm{C}$, respectively), Subpolar Mode Water (SPMW), and diluted Antarctic Intermediate Water (AA). Thin black dashed lines denote ${\mathit{\sigma }}_{\mathit{\theta }}$ levels from 24 to 29 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ at intervals of 0.5 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$.

[Figure omitted. See PDF]

No disturbances in the ${\mathit{\sigma }}_{\mathit{\theta }}$ field were observed at these intermediate depths despite the mentioned variability, indicating that density remained compensated (Fig. c). This compensation may also explain the localized enrichment of thermohaline fine structure, likely due to lateral intrusions, which were more noticeable in the $S_{\mathrm{A}}$ field (Fig. b). Additionally, within the area thought to be influenced by the Bentayga eddy (stations 12–24), the relative contribution of AA appeared stronger and was accompanied by a higher presence of Subpolar Mode Water (SPMW) above it (Fig. a and b; Fig. ). This suggests a possible connection between the anticyclonic circulation driven by the eddy and the vertical extent of its trapping capacity (i.e., its nonlinearity ratio, $\mathit{\vartheta }$; see Fig. e). However, as explained in Sect. , reliable VMADCP velocity records were not obtained for these depths, preventing further analyses.

To further investigate the impact of the Bentayga eddy on the water column along the OceT, anomalies in ${\mathit{\sigma }}_{\mathit{\theta }}$, $\mathrm{\Theta }$, and $S_{\mathrm{A}}$ were analyzed (Fig. ). As noted earlier, it was surrounded by several cyclonic mesoscale eddies, which caused perturbations outside its horizontal boundaries, affecting the water column from stations 02–11 and 25–27 (Fig. d). To account for these external influences, the mean profiles used as a reference state for anomaly calculations were derived using the method. First, an average distribution was calculated as a function of ${\mathit{\sigma }}_{\mathit{\theta }}$ for depth, $z$, $\mathrm{\Theta }$, and $S_{\mathrm{A}}$ (i.e., $\stackrel{\mathrm{‾}}{z}\left({\mathit{\sigma }}_{\mathit{\theta }}\right)$, $\stackrel{\mathrm{‾}}{\mathrm{\Theta }}\left({\mathit{\sigma }}_{\mathit{\theta }}\right)$, and $\stackrel{\mathrm{‾}}{S_{\mathrm{A}}}\left({\mathit{\sigma }}_{\mathit{\theta }}\right)$). These averaged profiles were then interpolated back to the original $z$ coordinate and subtracted from the respective vertical sections.

Vertical sections of anomalies in (a) conservative temperature (A$\mathrm{\Theta }$), (b) absolute salinity (A$S_{\mathrm{A}}$), and (c) potential density anomaly (A${\mathit{\sigma }}_{\mathit{\theta }}$) along the OceT transect during the eIMPACT2 survey. Thick black contours in all panels denote ${\mathit{\sigma }}_{\mathit{\theta }}$ levels at 25.2, 25.5, 26.6, and 26.8 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$. Vertical dashed lines indicate the positions of oceanographic stations as shown in Fig. a. Consistent with Fig. , distinct vertical scales are used for the 0–400 m and 400–1500 m depth ranges.

[Figure omitted. See PDF]

In terms of potential density anomaly and conservative temperature, the Bentayga eddy displayed a single core of lighter and warmer waters, extending from $\sim \mathrm{80}$ to 500 m depth ($<-\mathrm{0.2}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ and $>\mathrm{1}$ $\mathrm{°}\mathrm{C}$, respectively), horizontally spanning stations 12–24 (Fig. a and c), with the strongest anomalies located near the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.5}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal at $\sim \mathrm{150}$–155 m depth. At this level, density and temperature anomalies reached about $-\mathrm{1}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ and 4 $\mathrm{°}\mathrm{C}$, respectively. In contrast, the absolute salinity anomaly field exhibited a double-core structure: a shallower core of lower salinity between 80 and 140 m depth, enclosed between the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.2}$ and 25.5 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnals (anomalies below $-\mathrm{0.05}$ $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$), and a deeper saltier core extending from $\sim \mathrm{150}$ to 550 m depth, with maximum positive anomalies ($>\mathrm{0.1}$ $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$) centered between 200 and 300 m depth (Fig. b). At intermediate depths (800–1300 m), colder and fresher anomalies were observed just below the core of positive thermohaline anomalies (Fig. a and b). These anomalies reflected the influence of SPMW and AA water masses (Fig. ), with temperature anomalies below $-\mathrm{0.25}$ $\mathrm{°}\mathrm{C}$ and salinity anomalies below $-\mathrm{0.1}$ $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$.

3.3 3D view of the horizontal velocity field

The objectively interpolated fields of VMADCP horizontal velocity (u, v) and potential density anomaly (${\mathit{\sigma }}_{\mathit{\theta }}$) (Fig. ) clearly reveal the dominant influence of the Bentayga eddy in the sampled area, with its anticyclonic circulation prevailing across much of the region and remaining evident even at the shallower recorded depths ($<\mathrm{60}$ m, Fig. a). Outside this prominent circulation, the northwestern and southeastern corners of the interpolated field exhibited cyclonic eddies (CEs) with flow magnitudes comparable to those of this anticyclonic system. Additionally, a smaller AE was identified northeast of the primary system (Fig. d). This secondary structure, approximately half its size, displayed weaker anticyclonic circulation. However, since it was located near the northeastern edge of the SeaSoar sampling grid, its geometry was likely not well-resolved.

Objectively interpolated VMADCP velocity vectors (black arrows) superimposed on potential density anomaly (${\mathit{\sigma }}_{\mathit{\theta }}$) fields at different depths: (a) 56 m, (b) 88 m, (c) 120 m, and (d) 184 m. Each panel uses a distinct color scale representing ${\mathit{\sigma }}_{\mathit{\theta }}$ values, with 25 contour levels uniformly spaced across the respective density range to highlight the isopycnal structure. Velocity vectors are scaled relative to the magnitude at each depth (see legend in the bottom right corner of each panel). The ship's grid-like sampling trajectory during the eIMPACT2 SeaSoar phase (pale white circles) and the virtual transect used for the vertical section in Fig.  (white line) are also indicated. Objective interpolation correlation scales were set to $L_x=L_y=\mathrm{44}$ km, with 3 % uncorrelated noise applied.

[Figure omitted. See PDF]

Although the anticyclonic circulation induced by the Bentayga eddy was well-defined from depths as shallow as 30–60 m (see Figs.  and ), the expected doming of the upper isopycnals bounding the core was not clearly observed. Instead, it appeared only subtly and in a spatially localized manner, as seen in the horizontal sections of the upper 100 m (Fig. a and b), and consistent with the structure depicted by the 25.2 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal along the OceT transect (Fig. ). This localized doming of the upper isopycnals within the eddy may, in turn, reflect the advection of relatively lighter water from the surrounding ring, circulating around – and possibly penetrating into – the core. Moreover, the presence of this less dense “external” water may have locally intensified the vertical density contrast in that sector of the eddy, potentially hindering or even preventing the upward displacement of the isopycnals native to that region. At these depths ($<\mathrm{100}$ m depth), the eddy exhibited a generally circular, though slightly irregular, shape (horizontal aspect ratio of nearly 1.0), with meandering horizontal boundaries. With increasing depth, the structure became more regular and elliptical, maintaining a nearly constant horizontal aspect ratio of approximately 0.8 (Fig. c and d). Notably, the horizontal section at 120 m depth indicates that lighter water circulating around the core extended even to those depths (Fig. c). Below 120 m, the Bentayga eddy was characterized primarily by local isopycnal deepening and exhibited a reduction in size with increasing depth (Figs. d, and ).

Vertical sections of the horizontal velocity components, ${\mathit{\sigma }}_{\mathit{\theta }}$, and $S_{\mathrm{A}}$ were extracted along the virtual transect depicted in Fig. , offering a continuous depth-wise representation of the observed features and patterns (Fig. ). To better represent the circulation around the eddy center, horizontal velocity vectors were rotated along the transect axis. The anticyclonic circulation associated with the Bentayga eddy dominated the entire water column along this transect, with peak cross-transect velocities exceeding 30 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$ in the upper 200 m (Fig. a). Within this vertical segment, just below the mixing layer ($z>\mathrm{70}$–80 m), the isopycnals exhibited a steep inclination where the vertical density gradient was strongest. The highest velocities ($>\mathrm{60}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$) were located at the eddy's edges, progressively converging towards the boundaries of the eddy core with increasing depth. This subtle inward inclination was most pronounced between 80 and 150 m, where slight doming and deepening of the isopycnals delineating the core were also observed. Furthermore, within it, the isopycnals displayed small-scale irregularities, characterized by doming on one side and deepening on the other side. These patterns were mirrored by the isohalines delineating the relatively less saline eddy core (36.8–36.9 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$). While previous interpretations attributed these features to the lateral advection of lighter waters from the surrounding ring into the core, the observed isopycnal and isohaline perturbations may also be indicative of vertical displacements within the eddy structure.

Objectively interpolated cross-transect velocity components along the virtual transect shown in Fig. . Panels represent (a) cross-transect velocities measured directly by the VMADCP ($v$), (b) geostrophic velocities estimated using the thermal wind balance ($v^{\mathrm{g}}$), and (c) ageostrophic velocities calculated as the difference between VMADCP and geostrophic velocities ($v^{\mathrm{a}}=v-v^{\mathrm{g}}$). Black contours correspond to ${\mathit{\sigma }}_{\mathit{\theta }}$ levels (every 0.05 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$), with thicker lines highlighting the 25.2, 25.5, and 26.6 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnals, which are also labeled for reference. Light green contours denote isohalines (36.8–36.9 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$, every 0.05 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$).

[Figure omitted. See PDF]

Using the thermal wind balance relationship, the geostrophic current field was derived from the interpolated density field, with VMADCP records at 312 m depth serving as the reference level (Fig. b). Generally, VMADCP-measured velocities were more intense than the geostrophic currents, though their spatial patterns showed only minor discrepancies. Similar to the VMADCP observations, geostrophic currents were strongest at depths shallower than 200 m ($>\mathrm{30}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$), with maximum values above 100 m depth (50–55 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$). The ageostrophic horizontal velocity was revealed by subtracting the geostrophic component from the VMADCP velocity field (Fig. c). These velocities were strongest within the upper 150 m of the water column ($>\mathrm{5}$ $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$), peaking at over 10 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$ between 80 and 120 m depth.

Water parcels that follow curved trajectories within an AE require a net centripetal acceleration to maintain their motion in equilibrium. In these conditions, the appropriate momentum balance is the cyclogeostrophic one, which includes this centripetal acceleration explicitly . Assuming steady, inviscid, and axisymmetric flow, the radial component of the horizontal momentum equation becomes 10$$-{\displaystyle \frac{v_{\mathit{\theta }}^{\mathrm{2}}}{r}}=f{v}_{\mathit{\theta }}-{\displaystyle \frac{\mathrm{1}}{{\mathit{\rho }}_{\mathrm{0}}}}{\displaystyle \frac{\partial p}{\partial r}},$$ where $v_{\mathit{\theta }}$ is the azimuthal velocity, $r$ is the radial distance to the eddy center, ${\mathit{\rho }}_{\mathrm{0}}$ is the mean background density, and $p$ is the pressure. As shown in , the left-hand side expresses the centripetal acceleration required to sustain the curved trajectory, balancing the physical forces that provide it – namely, an inward Coriolis acceleration and an outward-directed pressure gradient. This implies that, when streamline curvature becomes significant in an AE, part of the observed ageostrophic horizontal velocity arises as a compensating effect of the curvature itself.

To quantify the importance of curvature in the momentum balance, a nondimensional number can be defined as $C=v_{\mathit{\theta }}/\left(fr\right)$, known as the cyclogeostrophic Rossby number. Values of $C\gtrsim \mathrm{0.1}$ are typically considered sufficient to indicate that the centripetal acceleration required to sustain flow curvature becomes dynamically significant e.g.,. Given that the virtual transect was nearly orthogonal to the eddy's mean flow, the azimuthal velocity component $v_{\mathit{\theta }}$ closely corresponds to the cross-transect velocity shown in Fig. a. This component, under the assumption $v\approx v_{\mathit{\theta }}$, was therefore used in the calculation of $C$ for the Bentayga eddy.

The diagnosed vertical distribution of $C$ reveals values exceeding 0.1 at depths $z\le \mathrm{160}$ m when using either the mean or the upper 10 % of $v_{\mathit{\theta }}$ within the eddy core. Peak values ($\gtrsim \mathrm{0.15}$) occurred between 80 and 160 m, coinciding with the depth range of the strongest observed cross-transect ($v$) and ageostrophic ($v^{\mathrm{a}}$) velocities. This suggests that curvature effects contribute significantly to the momentum balance in the core region, particularly for radial distances $r\lesssim \mathrm{40}$ km, promoting compensating ageostrophic velocities within the core that help sustain the anticyclonic circulation of the Bentayga eddy.

3.4 Oxygen distribution and biogeochemical signatures

The distribution of ${\mathrm{O}}_{\mathrm{2}}$ across the Bentayga eddy provides valuable insights into its biogeochemical imprint (Fig. ). Vertical sections along the OceT transect reveal a well-defined subsurface minimum in absolute ${\mathrm{O}}_{\mathrm{2}}$ concentrations (Fig. a), with values below 210 $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$ centered around 110–130 m depth and extending across stations 14–22. This oxygen-depleted layer coincides with the pycnostad core of the eddy, bounded by the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.2}$–25.5 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnals. Anomalies relative to a reference vertical profile, derived from stations outside the eddy influence (as described in Sect. ), further highlight this core as a region of moderate ${\mathrm{O}}_{\mathrm{2}}$ deficit (${\mathrm{AO}}_{\mathrm{2}}<-\mathrm{5}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$) (Fig. b). Beneath this negative anomaly layer, ${\mathrm{O}}_{\mathrm{2}}$ concentrations exceed the reference values, producing positive anomalies (${\text{AO}}_{\mathrm{2}}>\mathrm{15}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$) that closely follow the 25.5–25.6 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnals.

Dissolved oxygen structure of the Bentayga eddy. (a) Absolute ${\mathrm{O}}_{\mathrm{2}}$ concentrations [$\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$] along the OceT transect. (b) ${\mathrm{O}}_{\mathrm{2}}$ anomalies (AO₂) relative to the reference profile. (c) Apparent oxygen utilization (AOU). (d) Horizontal section at 130 m depth showing objectively interpolated ${\mathrm{O}}_{\mathrm{2}}$ (color map) and AOU (dark green contours).

[Figure omitted. See PDF]

The apparent oxygen utilization (AOU) field (Fig. c) offers additional support for this interpretation. Within the eddy core, AOU values remain relatively low at around 10 $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$, slightly higher than surface waters (ranging from $-\mathrm{10}$ to 0 $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$) but well below typical values for thermocline or intermediate-depth waters. These low AOU values extend deeper inside the eddy than in surrounding waters, with concentrations $<\mathrm{35}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$ reaching depths of $\sim \mathrm{270}$ m and $<\mathrm{80}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$ persisting to $\sim \mathrm{400}$ m. In contrast, values exceeding 120 $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$ are observed below 500 m throughout the transect, outside the influence of the eddy. This vertical structure suggests that the eddy retains relatively young, recently subducted water masses, likely of surface or coastal origin. The limited oxygen consumption implied by the low AOU values indicates a weakly ventilated but not yet biogeochemically aged core.

A horizontal section at 130 m depth (Fig. d) further confirms the spatial coherence of this relatively oxygen-depleted, low-AOU core. However, it seems that during the SeaSoar phase, AOU values within the core were even lower, ranging between 0 and 2 $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$, and were encircled by a weak negative-AOU ring ($-\mathrm{4}$ to $-\mathrm{1}$ $\mathrm{\mu }\mathrm{mol}{\mathrm{kg}}^{-\mathrm{1}}$). These slightly negative values indicate that the water was slightly oversaturated with respect to atmospheric equilibrium, consistent with the recent subduction of well-oxygenated surface waters into the eddy core and limited biological and microbial oxygen demand. This distribution supports the interpretation that the eddy trapped and transported oxygen-poor waters offshore, potentially sourced from coastal upwelling regions, as suggested by the satellite-derived eddy trajectory and its dynamical properties. The combination of hydrographic isolation and distinct ${\mathrm{O}}_{\mathrm{2}}$ and AOU signatures underscores the eddy's role in redistributing oxygen and modifying ventilation patterns at thermocline depths, pointing to biogeochemical impacts that extend beyond its dynamic and thermohaline structure.

Radial profiles of azimuthal velocity ($v_{\mathit{\theta }}$) for the OceT transect at selected depths: (a) 64 m, (b) 112 m, and (c) 192 m, derived from the OceT. Gray diamonds represent the observed data, while solid black lines correspond to the linear regression fit using $v_{\mathit{\theta }}={\mathit{\omega }}_{\mathit{\theta }}r$, with $v_{\mathit{\theta }}=\mathrm{0}$ at $r=\mathrm{0}$. The slope of the regression (${\mathit{\omega }}_{\mathit{\theta }}$) is proportional to the angular velocity of the eddy. (d) Depth-wise variation of the solid-body core's rotation frequency (${\mathit{\omega }}_{\mathit{\theta }}$) and its corresponding period.

[Figure omitted. See PDF]

3.5 Azimuthal velocity structure and eddy-core rotational dynamics

To investigate the rotational structure of the Bentayga eddy, we analyzed the radial distribution and vertical variability of azimuthal velocities ($v_{\mathit{\theta }}$) derived from multiple observational phases. This combined approach provided a comprehensive view of the eddy's internal dynamics, capturing both vertical coherence and horizontal structural transitions. Figure  shows the depth-resolved azimuthal velocity profiles extracted from the OceT transect. At each depth, a least-squares fit of the form $v_{\mathit{\theta }}={\mathit{\omega }}_{\mathit{\theta }}r$ was applied to the observed velocity data to quantify the degree of solid-body rotation within the eddy core. Here, ${\mathit{\omega }}_{\mathit{\theta }}$ denotes the angular velocity, and the constraint $v_{\mathit{\theta }}=\mathrm{0}$ at the eddy center ($r=\mathrm{0}$) was imposed to ensure physical consistency. The linear fit was iteratively computed over increasing radial distances, and an effective core radius was defined as the radial distance at which the correlation coefficient ($r_{xy}$) between the fitted and observed data reached its maximum.

The results reveal a well-defined solid-body core extending laterally up to $\sim \mathrm{23}$–28 km (close to the observed $R_{\mathrm{c}}$ in Sect.  and in the Sect. S3) and vertically from the shallowest observed level ($\sim \mathrm{40}$ m) to approximately 350 m depth, where $r_{xy}\ge \mathrm{0.9}$. Below 350 m, the rotational coherence weakened, with $r_{xy}$ reaching a minimum of $\sim \mathrm{0.75}$ between 360 and 400 m. Interestingly, $r_{xy}$ increased again between 415 and 450 m, remaining above 0.8 down to $\sim \mathrm{600}$ m, after which it declined sharply, indicating the gradual erosion of solid-body characteristics with depth. The vertical structure of the rotation frequency ${\mathit{\omega }}_{\mathit{\theta }}$ (Fig. d) showed a nearly constant surface-averaged angular velocity down to 80 m, at approximately $\mathrm{1.35}\times {\mathrm{10}}^{-\mathrm{5}}$ $\mathrm{rad}{\mathrm{s}}^{-\mathrm{1}}$ (corresponding to a $\sim \mathrm{5}$ d period). A peak in ${\mathit{\omega }}_{\mathit{\theta }}$ was observed between 110 and 130 m, reaching $\mathrm{1.85}\times {\mathrm{10}}^{-\mathrm{5}}$ $\mathrm{rad}{\mathrm{s}}^{-\mathrm{1}}$ ($\sim \mathrm{3.9}$ d period), after which the rotation rate declined abruptly, reaching $\sim \mathrm{70}$ % of its peak by 210 m. This behavior suggests that the core is composed of vertically stratified layers, each rotating quasi-independently rather than as a uniform column, as similarly observed in Meddies and other intrathermocline structures .

(a) Radial distribution of azimuthal velocity ($v_{\mathit{\theta }}$) between 80 and 160 m depth, relative to the center of the Bentayga eddy normalized by $R_{\mathrm{c}}$. Gray markers represent individual measurements from different survey phases: SeaSoar (T3 and T4; dark gray diamonds), Orthotransects (ZT and MT; light gray circles), and OceT (dark gray open squares) (see Sect. S3 and Fig. S9 for further details). The binned mean profile is shown as red-filled black squares, calculated over 5 km radial intervals; vertical bars indicate $\pm \mathrm{1}$ standard deviation. Blue-circled markers highlight bins with fewer than 10 observations. An hybrid model-derived velocity profile is overlaid (black dashed). (b) Normalized relative vorticity ($\mathit{\zeta }/f$, squares and solid lines) and strain rate ($\mathit{\eta }/f$, triangles and dashed lines) as a function of normalized radial distance. Symbols denote observed values, and curves follow the same color scheme as in panel (a). The green shaded region in both panels marks the extent of the well-mixed eddy core ($\left|r\right|\le R_{\mathrm{c}}=\mathrm{23}$ km).

[Figure omitted. See PDF]

Complementing this vertical analysis, the radial structure of azimuthal velocities in the 80–160 m depth range was evaluated across several eIMPACT2 survey phases and is shown in Fig. a. Despite minor asymmetries, the velocity profiles remain consistent across them. Within the well-mixed core ($\left|r\right|\le R_{\mathrm{c}}=\mathrm{23}$ km), the profiles exhibit a nearly linear increase in $v_{\mathit{\theta }}$, consistent with solid-body rotation. Beyond this region, azimuthal velocities gradually increase to a maximum near $\left|r\right|\sim \mathrm{35}$–45 km before declining smoothly, a pattern reminiscent of Gaussian-type vortices. To capture this structural transition, a hybrid vortex model was developed by combining Rankine and Gaussian profiles using a logistic weighting function (see Sect. S3 and Eqs. S9–S12 for full formulation). This model, shown as a dashed black curve in Fig. a, reproduces the linear behavior within the core and the gradual decay in the outer region. The transition starts around $R_{\mathrm{c}}$, and the hybrid formulation remains valid up to $R_{\mathrm{e}}\approx \mathrm{3}{R}_{\mathrm{c}}\approx \mathrm{70}$ km, with $R_{\mathrm{e}}$ corresponding to the outer edge of the previously defined surrounding ring, thereby capturing the eddy's full dynamical extent. In addition, Fig. b shows the normalized relative vorticity ($\mathit{\zeta }/f$) and strain rate ($\mathit{\eta }/f$), computed from $v_{\mathit{\theta }}\left(r\right)$ assuming axisymmetry. While $\mathit{\zeta }/f$ follows the hybrid model closely – especially in the surrounding ring sector – the strain rate displays higher variability and deviates from theoretical expectations, possibly due to azimuthal asymmetries, resolution limits, or submesoscale deformation processes not accounted for in the axisymmetric model assumptions (see discussion in Sects. S3–S5).

To dynamically characterize the internal structure of the Bentayga eddy, the Rossby number (Ro) was calculated as the ratio of the vertical component of the relative vorticity field to planetary vorticity (${\mathit{\zeta }}_{\text{OI}}$ and $f_{\text{OI}}$, respectively). The relative vorticity (${\mathit{\zeta }}_{\text{OI}}$) was derived from the objectively interpolated VMADCP velocity fields using ${\mathit{\zeta }}_{\text{OI}}=\partial v/\partial x-\partial u/\partial y$. A horizontal section of the three-dimensional Ro field was extracted at a depth of 104 m, corresponding to the level of maximum VMADCP velocities recorded during the eIMPACT2 SeaSoar phase (Fig. a, see also Fig. ). Additionally, a vertical section along the virtual transect shown in Fig. a was examined (Fig. b). These analyses revealed that its core was dominated by negative vorticity, with Ro values within the core reaching below $-\mathrm{0.45}$ and a peak negative vorticity of approximately $-\mathrm{0.61}f$ at its center. Ro increased radially from the core toward the outer regions, transitioning to positive values in the central part of the surrounding ring (45–50 km from the eddy center), where Ro ranged between 0.1 and 0.2.

Rossby number (Ro) and strain rate (${\mathit{\eta }}_{\text{OI}}$) derived from the objectively interpolated VMADCP velocity fields. (a) Horizontal section of Ro at 104 m depth, corresponding to the depth of maximum swirl speed of the eddy (refer to Fig. ). Contours of Ro are shown every 0.05, with negative values represented by dashed lines and positive values by solid lines. (b) Vertical section of Ro along the virtual transect in panel (a) (thick black line). Contours of Ro are displayed every 0.05, with dashed lines for negative values. (c, d) Same as (a) and (b) but for the ${\mathit{\eta }}_{\text{OI}}$. Contours are shown every 0.025. Objectively interpolated ${\mathit{\sigma }}_{\mathit{\theta }}$ contours (every 0.1 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$) are shown as gray (a, c) and black lines (b, d). In (b) and (d) values of ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.2}$, 25.5, and 26.6 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ are highlighted and labeled with thick black lines for clarity, and, additionally, the 36.8–36.9 isohalines (every 0.05 $\mathrm{g}{\mathrm{kg}}^{-\mathrm{1}}$) are included as thick light green contours.

[Figure omitted. See PDF]

In addition to Ro, the strain rate field (${\mathit{\eta }}_{\text{OI}}$) was analyzed to further characterize the dynamical structure of the eddy and its surrounding environment (Fig. c and d). The strain rate was also computed from the interpolated VMADCP velocities using ${\mathit{\eta }}_{\text{OI}}=\sqrt{(\partial u/\partial x-\partial v/\partial y{)}^{\mathrm{2}}+(\partial v/\partial x+\partial u/\partial y{)}^{\mathrm{2}}}$ and normalized by $f_{\text{OI}}$. The horizontal section at 104 m depth (Fig. c) revealed a well-defined annular band of elevated strain rate (0.1–0.2) encircling the eddy core, especially concentrated near its western and northeastern flanks. These strain maxima occurred between 35–60 km radial distance from the eddy center, roughly aligning with the radial position of maximum azimuthal velocities (see Fig. a) and indicating enhanced deformation at the transition between the inner core and surrounding ring. In the vertical section along the virtual transect (Fig. d), strain values were lowest ($<\mathrm{0.05}$) within the core region above ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{26.6}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$, consistent with the nearly solid-body rotation observed in the core (Figs.  and ). Notably, strain values inside the eddy core reached $\sim \mathrm{0.1}$ in localized regions where the ${\mathit{\sigma }}_{\mathit{\theta }}=\mathrm{25.3}$ $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ isopycnal displayed asymmetric behavior. A distinct patch of high strain ($\sim \mathrm{0.3}$) emerged at depths of 80–200 m in the eddy's western and eastern flanks, suggesting strong horizontal shear possibly related to interactions with the surrounding flow or adjacent cyclonic structures.

Together, the vertical coherence of ${\mathit{\omega }}_{\mathit{\theta }}$ (Fig. ), the radial transition captured by the hybrid model (Fig. ), and the complementary patterns in the Rossby number and strain rate fields (Fig. ) offer a consistent and physically grounded depiction of the eddy's rotational structure. These diagnostics collectively support the use of a solid-body approximation within the core and a smooth transition to a Gaussian-like regime in the surrounding ring, while revealing a rotationally coherent interior embedded within a broader region of enhanced deformation – hallmarks of a mature anticyclonic intrathermocline eddy. This provides a robust framework for defining the integration limits used in subsequent calculations of energy content, hydrographic anomalies, and transport properties.

The horizontal location where the Rossby number (Ro) changes sign – i.e., where ${\mathit{\zeta }}_{\text{OI}}=\mathrm{0}$ – was used to dynamically identify the outer boundary of the eddy's spatially coherent horizontal structure. This occurred at a radial distance of approximately 62 km, closely aligning with the outer edge of the ${\mathit{\eta }}_{\text{OI}}$ maximum zone in the surrounding ring. Notably, this location corresponds to $\sqrt{\mathrm{2}}{R}_{\text{max}}$, where $R_{\text{max}}\approx \mathrm{41}$ km marks the radius of maximum azimuthal velocity (Fig. ; see also Sect. S3). Interestingly, $R_{\text{max}}$ is in excellent agreement with the climatological first baroclinic Rossby radius of deformation, estimated at 42.8 km for this latitude using the empirical polynomial from . As expected for Gaussian-like anticyclones, the Ro sign reversal occurs beyond the velocity peak. This consistency between theory and observation reinforces the validity of our dynamical interpretation and the robustness of our radial zonation. We therefore adopt this boundary to define the outer shell enclosing the rotationally coherent region of the eddy, which also coincides with the external edge of the strain-dominated sector, and use it as a reference to evaluate its vertical structure and water-trapping capacity.

Once this boundary was defined, circum-averaged azimuthal velocities were computed at each VMADCP depth, yielding a vertical profile of the average shell velocities along with their corresponding standard deviation (Fig. ). Maximum shell velocities were observed near the surface, at depths shallower than 120 m, with a relative peak centered at 104 m (approximately 50 $\pm$ 10 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$). Below this peak, the shell velocity magnitude decreased sharply, extending down to 200 m depth, with a mean vertical shear of 0.004 ${\mathrm{s}}^{-\mathrm{1}}$. At greater depths, the velocity reduction was more gradual, with a mean shear of 0.002 ${\mathrm{s}}^{-\mathrm{1}}$ down to about 600 m depth. As shown in Fig. , velocities below 550 m approached the eddy's mean translational speed ($c$), and between 550 and 750 m they fell below this threshold. This suggests that, at such depths, the eddy's water-trapping capacity may no longer be sufficient to significantly limit exchange with the surroundings, thereby reducing its ability to transport and maintain these water masses along its trajectory.

Vertical profile of the averaged VMADCP shell velocities (thick black line) with its corresponding standard deviation (represented by thin black lines) during the eIMPACT SeaSoar phase. The dashed vertical line indicates the average translational speed of the eddy (5.4 $\mathrm{cm}{\mathrm{s}}^{-\mathrm{1}}$) during the eIMPACT2 survey.

[Figure omitted. See PDF]

3.6 Potential vorticity and stratification

The radial distributions of Ro and ${\mathit{\eta }}_{\text{OI}}$ provide a dynamical framework for interpreting the eddy's structure, with the former emphasizing rotational dominance and the latter indicating minimal deformation in the core and increasing strain toward the periphery – together confirming a highly coherent, vorticity-dominated interior. Complementing this, the vertical stratification and PV fields characterize the internal stability of the water column and the magnitude of PV anomalies within the eddy. Given the conservative nature of PV in the absence of external forcing and dissipation, such anomalies are robust indicators of water mass retention. Combined, these analyses elucidate the interplay between the eddy's rotational dynamics and its stratification-controlled trapping capacity. As discussed earlier (Sects.  and ), ITEs are characterized by a large reduction in PV within their core, primarily due to their reduced stratification and the homogeneous water they enclose, resulting in significant negative PV anomalies relative to the surrounding environment. The calculated PV of the Bentayga eddy related to isopycnal tilting was found to be 2 orders of magnitude smaller than the PV associated with water column stretching. This aligns with previous findings, such as those for the PUMP eddy by , and reflects the characteristic behavior of ITEs, where the vertical density gradient, ${\partial }_z{\mathit{\sigma }}_{\mathit{\theta }}$, i.e., the stratification of the water column, predominantly controls the magnitude of their core's PV.

As seen in Fig. , the lowest PV values ($\sim {\mathrm{10}}^{-\mathrm{11}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$) were observed in the shallowest layers and within the inner core, where water exhibited high homogeneity and low stratification. As anticipated, higher PV values ($>\mathrm{5}\times {\mathrm{10}}^{-\mathrm{10}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$) were detected in regions of greater stratification, where closely spaced isopycnal surfaces indicated compression of the water column in the vertical dimension. The highest PV values ($>\mathrm{9}\times {\mathrm{10}}^{-\mathrm{10}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$) were detected near regions of strong isopycnal lifting at the periphery of the Bentayga eddy, possibly influenced by adjacent CEs. Furthermore, the spatial distribution of PV highlights the sharp stratification contrast between its anomalously low-PV core and the surrounding layers of relatively higher PV (Fig. b). At greater depths, below these surrounding layers, PV values diminished gradually, reaching approximately $\mathrm{1}\times {\mathrm{10}}^{-\mathrm{10}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$, indicating a progressive decrease in PV distribution with depth.

Ertel's potential vorticity (PV) derived from objectively interpolated VMADCP velocities and ${\mathit{\sigma }}_{\mathit{\theta }}$ fields. (a) Vertical section of ${\log }_{\mathrm{10}}$(PV) along the virtual transect indicated by the thick black line in Figs.  and a. Extreme PV levels are represented by thick white and gray contours, highlighting the lowest ($\mathrm{5}\times {\mathrm{10}}^{-\mathrm{11}}$, $\mathrm{10}\times {\mathrm{10}}^{-\mathrm{11}}$, and $\mathrm{15}\times {\mathrm{10}}^{-\mathrm{11}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$) and highest PV values ($\mathrm{5}\times {\mathrm{10}}^{-\mathrm{10}}$, $\mathrm{7}\times {\mathrm{10}}^{-\mathrm{10}}$, and $\mathrm{9}\times {\mathrm{10}}^{-\mathrm{10}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$), respectively. Thin black contours indicate ${\mathit{\sigma }}_{\mathit{\theta }}$ levels (spaced every 0.05 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$). For clarity, ${\mathit{\sigma }}_{\mathit{\theta }}$ levels at 25.2, 25.5, and 26.6 $\mathrm{kg}{\mathrm{m}}^{-\mathrm{3}}$ are labeled and displayed as thick black lines. (b) Three-dimensional view of the PV field, represented by the $\mathrm{15}\times {\mathrm{10}}^{-\mathrm{11}}$ and $\mathrm{5}\times {\mathrm{10}}^{-\mathrm{10}}$ ${\mathrm{m}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$ surfaces, shown as dark blue and light yellow sheet-like patches, respectively.

[Figure omitted. See PDF]

3.7 Energy content

The net available potential energy (APE) and kinetic energy (KE) within the Bentayga eddy were estimated using Eqs. () and (), integrating from the surface to a depth ($H$) of 550 m, corresponding to the eddy's effective trapping depth as inferred from hydrographic and velocity anomalies (see Sect. ). This depth marks the lower boundary of the coherent thermohaline structure, beyond which the eddy signature decays rapidly. Table  presents the detailed APE and KE values obtained using three physically grounded radial limits: the solid-body core radius ($R_{\mathrm{c}}=\mathrm{23}$ km), the radius of maximum azimuthal velocity ($R_{\text{max}}=\mathrm{41}$ km), and the external edge of the surrounding ring ($R_{\mathrm{e}}=\mathrm{70}$ km). These limits were defined based on the rotational and structural characteristics of the eddy and are discussed in detail in the Sect. S3.

Energy content and Burger number estimates for the Bentayga eddy, evaluated across three horizontal scales ($L_x=\mathrm{2}R$) corresponding to distinct integration radii: the solid-body core ($R_{\mathrm{c}}$), the radius of maximum azimuthal velocity ($R_{max}$), and the outer edge of the surrounding ring ($R_{\mathrm{e}}$). Kinetic energy (KE) and available potential energy (APE) were used to compute the energy Burger number (${\mathit{\text{Bu}}}_{\mathrm{E}}=\text{KE}/\text{APE}$). The table also presents the length-scale Burger number (${\mathit{\text{Bu}}}_{\text{L}}=N^{\mathrm{2}}{L}_Z^{\mathrm{2}}/f^{\mathrm{2}}{L}_x^{\mathrm{2}}$) and the parameterized energy Burger number (${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}={\mathit{\text{Bu}}}_{\text{L}}/(\mathrm{1}+\mathit{\text{Ro}}{)}^{\mathrm{2}}$), estimated using two values of Rossby number: the average ($\mathit{\text{Ro}}=\mathrm{0.47}$) and the maximum ($\mathit{\text{Ro}}=\mathrm{0.65}$) vorticity within the eddy core. All calculations were performed using fixed values of the squared Brunt–Väisälä frequency ($N^{\mathrm{2}}=\mathrm{3.55}\times {\mathrm{10}}^{-\mathrm{5}}$ ${\mathrm{s}}^{-\mathrm{2}}$) and Coriolis parameter ($f=\mathrm{6.33}\times {\mathrm{10}}^{-\mathrm{5}}$ ${\mathrm{s}}^{-\mathrm{1}}$), representative of the eddy's core conditions.

Across this radial range, APE increased from 0.006 to 0.031 PJ, while KE increased more sharply from 0.001 to 0.021 PJ ($\mathrm{1}\mathrm{PJ}={\mathrm{10}}^{\mathrm{15}}$ J). At the solid-body core radius ($R_{\mathrm{c}}$), APE was approximately 368 % greater than KE; this contrast decreased to 126 % at $R_{max}$ and further to 45 % at $R_{\mathrm{e}}$. As a result, the energy Burger number (${\mathit{\text{Bu}}}_{\mathrm{E}}=\text{KE}/\text{APE}$) rose from 0.21 at $R_{\mathrm{c}}$ to 0.69 at $R_{\mathrm{e}}$, indicating a progressive shift toward kinetic energy dominance as larger portions of the eddy's surrounding ring are incorporated. This predominance of APE over KE is a hallmark of well-established intrathermocline eddies (ITEs) and is consistent with findings from previous studies e.g.,. Moreover, it reflects a mature stage in the eddy's life cycle, during which the balance between available potential and kinetic energy shifts as the structure adjusts and stabilizes e.g.,.

To explore the origin of this trend, we evaluated the length-scale Burger number, ${\mathit{\text{Bu}}}_{\text{L}}=N^{\mathrm{2}}{L}_Z^{\mathrm{2}}/f^{\mathrm{2}}{L}_x^{\mathrm{2}}$, and its theoretical connection to the energy partitioning through the parameterized form ${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}={\mathit{\text{Bu}}}_{\text{L}}/(\mathrm{1}+\mathit{\text{Ro}}{)}^{\mathrm{2}}$, where $L_Z=H=\mathrm{550}$ m and $L_x=\mathrm{2}R$. Ro values used in this parameterization were derived from the eddy core and correspond to the average ($\left|\mathit{\text{Ro}}\right|=\mathrm{0.47}$) and maximum ($\left|\mathit{\text{Ro}}\right|=\mathrm{0.65}$) relative vorticity. For consistency, all calculations were performed using fixed values of $N^{\mathrm{2}}=\mathrm{3.55}\times {\mathrm{10}}^{-\mathrm{5}}$ ${\mathrm{s}}^{-\mathrm{2}}$ and $f=\mathrm{6.33}\times {\mathrm{10}}^{-\mathrm{5}}$ ${\mathrm{s}}^{-\mathrm{1}}$, representative of the eddy's core. The results show that ${\mathit{\text{Bu}}}_{\text{L}}$ decreases with increasing radius, from 1.27 at $R_{\mathrm{c}}$ to 0.14 at $R_{\mathrm{e}}$, reflecting the changing aspect ratio of the integrated volume. ${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}$ also decreases accordingly and shows the closest agreement with ${\mathit{\text{Bu}}}_{\mathrm{E}}$ at $R=R_{\text{max}}$. However, this apparent convergence must be interpreted with caution, as the estimations rely on data collected during the eIMPACT2 OceT phase, which is particularly susceptible to sampling-induced distortions. At larger radii, ${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}$ progressively underestimates the observed ratio, reflecting not only the expected sampling-related distortion but also the growing influence of processes not captured – such as the contribution of horizontal shear, flow strain, ageostrophic motions, and radial structural complexity to the relative increase in kinetic energy. At $R=R_{\mathrm{c}}$, by contrast, ${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}$ overestimates ${\mathit{\text{Bu}}}_{\mathrm{E}}$ by nearly a factor of 2, although the version computed using the maximum core vorticity provides a closer approximation. This outcome reinforces the notion that energy partitioning within the eddy is fundamentally constrained by its geometry and dynamical state, while also highlighting the limitations of theoretical scalings when applied to observational data affected by sampling biases.

Sections S4 and S5 demonstrate that the solid-body core remains the least affected by sampling-induced distortions, reinforcing the interpretation of $R_{\mathrm{c}}$ as the most reliable spatial limit for estimating the eddy's intrinsic energetics. This supports the notion that the eddy's core retains the most coherent and energetically stable signature. However, the progressive divergence observed between theoretical expectations and empirical estimates at larger radii highlights the inherent difficulties of reconciling these approaches, particularly under these sampling conditions. Despite these uncertainties, the general pattern indicates that the internal energy balance of the eddy is primarily governed by geometric and dynamical constraints. Previous studies e.g., emphasized the role of aspect ratio in shaping eddy energetics, while illustrated how strong vorticity can modulate the distribution of kinetic and potential energy within mesoscale ocean structures.

To contextualize these results, Table  summarizes the energy partitioning and dynamical indicators of several ITEs previously documented in the literature. Most exhibit ${\mathit{\text{Bu}}}_{\mathrm{E}}$ between 0.5 and 1.5, although substantial variability arises depending on the eddy's age, stratification, and geographical setting. Within this framework, the Bentayga eddy's value of ${\mathit{\text{Bu}}}_{\mathrm{E}}=\mathrm{0.21}$, when evaluated at $R_{\mathrm{c}}$, lies at the lower end of the spectrum, consistent with a strongly baroclinic structure dominated by potential energy. In contrast, the PUMP eddy – also sampled within the CEC – displayed a KE value approximately 50 % higher than its APE . This divergence is particularly noteworthy considering that both eddies were of similar age at the time of their respective surveys, suggesting potential differences in their formation mechanisms, environmental interactions, or stages within their life cycles. In summary, both the empirical estimates and the theoretical parameterizations support the use of $R_{\mathrm{c}}$ as the most representative integration radius for quantifying the energy content and dynamical state of the Bentayga eddy. This limit encompasses a region of high structural coherence and minimal sampling distortion, thus providing a conservative yet robust lower bound for evaluating the eddy's contribution to regional mesoscale energetics.

Comparison of energy content and associated dynamical parameters for intrathermocline eddies (ITEs) from previous studies. The vertical extent ($H$) and characteristic radius ($R$) used to estimate the available potential energy (APE) and kinetic energy (KE) are listed alongside the resulting energy Burger number (${\mathit{\text{Bu}}}_{\mathrm{E}}=\text{KE}/\text{APE}$). Additionally, the length-scale Burger number (${\mathit{\text{Bu}}}_{\text{L}}=N^{\mathrm{2}}{L_Z}^{\mathrm{2}}/f^{\mathrm{2}}{L_X}^{\mathrm{2}}$), Rossby number, and parameterized energy Burger number (${\mathit{\text{Bu}}}_{\mathrm{E}}^{\mathrm{L}}={\mathit{\text{Bu}}}_{\text{L}}/(\mathrm{1}+\mathit{\text{Ro}}{)}^{\mathrm{2}}$) are presented. Here, the background squared Brunt–Väisälä frequency ($N^{\mathrm{2}}$), the Coriolis parameter ($f$), and the eddy's vertical and horizontal scales ($L_Z$ and $L_X$, respectively), used for the calculations, are also included. When $L_Z$ and $L_X$ correspond to the spatial domain used for APE and KE calculations, the associated values of $H$ and $R$, as defined in this table, are referenced.

The ^∗ symbol denotes values that were not explicitly provided in the respective studies. These were inferred from figures, calculated using related information, or estimated based on the provided methodology. Assumptions and approximations for these values are detailed in their respective references.

3.8 Thermohaline anomalies and transport

Distinct thermohaline anomalies were identified within the Bentayga eddy compared to the surrounding environment (Fig. ). These anomalies formed the basis for computing the vertical profiles of available heat anomaly (AHA) and available salt anomaly (ASA). Radial integration from the eddy center to the core outer boundary ($R_{\mathrm{c}}=\mathrm{23}$ km) revealed marked vertical differences between the $\text{ASA}\left(z\right)$ and $\text{AHA}\left(z\right)$ distributions (Fig. ). As previously discussed in Sect. , the radial limit adopted here corresponds to the distance at which Doppler-like distortions arising from sampling asynopticity are minimized (see Sects. S1–S6). Accordingly, the resulting estimates should be interpreted as conservative lower-bound values for the full eddy-induced effect. Within this boundary, thermohaline anomalies – and their associated eddy-driven fluxes – exhibit the highest degree of spatial and temporal coherence.

Vertical profiles of radially integrated available heat anomaly ($\text{AHA}\left(z\right)$) and available salt anomaly ($\text{ASA}\left(z\right)$) within the core of the Bentayga eddy ($R_{\mathrm{c}}=\mathrm{23}$ km) during the eIMPACT OceT phase. The solid black line represents $\text{AHA}\left(z\right)$, while the dashed black line corresponds to $\text{ASA}\left(z\right)$. The horizontal dashed line indicates the effective trapping depth ($H=\mathrm{550}$ m), used as the lower limit for vertical integration.

[Figure omitted. See PDF]

$\text{ASA}\left(z\right)$ displayed predominantly positive values, except within the vertical range of 80–150 m and below 700 m. Negative anomalies in the upper layer, attributed to the salinity deficit in the core, reached a minimum of $-\mathrm{0.18}$ $\mathrm{Gkg}{\mathrm{m}}^{-\mathrm{1}}$ ($\mathrm{1}\mathrm{Gkg}={\mathrm{10}}^{\mathrm{9}}$ kg) at 112 m depth. Below this depth, $\text{ASA}\left(z\right)$ increased steadily, peaking at 0.89 $\mathrm{Gkg}{\mathrm{m}}^{-\mathrm{1}}$ at 232 m. This was followed by a sharp decline with an average rate of 4.0 $\mathrm{Mkg}{\mathrm{m}}^{-\mathrm{2}}$ ($\mathrm{1}\mathrm{Mkg}={\mathrm{10}}^{\mathrm{6}}$ kg) down to 400 m, transitioning to a more gradual decrease (0.8 $\mathrm{Mkg}{\mathrm{m}}^{-\mathrm{2}}$) at greater depths. In contrast, $\text{AHA}\left(z\right)$ remained strictly positive from $\sim \mathrm{50}$ to 750 m, with a maximum value of 27.0 $\mathrm{PJ}{\mathrm{m}}^{-\mathrm{1}}$ at 160 m – significantly shallower than the $\text{ASA}\left(z\right)$ peak. A minor reduction in $\text{AHA}\left(z\right)$ at 90 m briefly interrupted the general increasing trend, which rose with a slope of $-\mathrm{0.2}$ $\mathrm{PJ}{\mathrm{m}}^{-\mathrm{2}}$ up to the maximum. Below 160 m, the profile declined at 0.1 $\mathrm{PJ}{\mathrm{m}}^{-\mathrm{2}}$ until 400 m and then more gradually (0.02 $\mathrm{PJ}{\mathrm{m}}^{-\mathrm{2}}$) at greater depths. Given that the critical trapping depth of the Bentayga eddy was 550 m, the negative anomalies in $\text{ASA}\left(z\right)$ and $\text{AHA}\left(z\right)$ below 700 m were unlikely to be influenced by the eddy. Vertical integration of $\text{ASA}\left(z\right)$ and $\text{AHA}\left(z\right)$ to the trapping depth yielded total values of 0.015 Tkg ($\mathrm{1}\mathrm{Tkg}={\mathrm{10}}^{\mathrm{12}}$ kg) and 6.550 EJ ($\mathrm{1}\mathrm{EJ}={\mathrm{10}}^{\mathrm{18}}$ J), respectively. These positive totals underscore the persistence and intensity of heat and salt anomalies, despite localized negative segments in $\text{ASA}\left(z\right)$.

During the eIMPACT2 campaign, the Bentayga eddy followed a west-southwestward trajectory at an average speed of 4.5 $\mathrm{km}{\mathrm{d}}^{-\mathrm{1}}$, consistent with the phase speed of nondispersive baroclinic Rossby waves . Using this translational speed ($c$), along with the eddy's geometric dimensions ($R_{\mathrm{c}}=\mathrm{23}$ km and $H=\mathrm{550}$ m), the eddy-driven volume transport ($V_{\mathrm{e}}$) was estimated at 1.31 Sv. This value closely matches the transport attributed to the PUMP eddy (1.38 Sv), computed using Eq. () and the parameters reported by , and aligns with the mean mesoscale transport of 1.3 Sv estimated for the CEC by . Compared to other eastern boundary upwelling systems (EBUSs), the eddy-driven volume fluxes in the Canary Eddy Corridor exceed the average values reported for the Peru–Chile Current System (PCCS) but remain below those observed in the eastern Indian Ocean . In terms of thermohaline transport, the Bentayga eddy contributed an eddy-driven heat flux ($Q_{\text{eh}}$) of 4.60 TW ($\mathrm{1}\mathrm{TW}={\mathrm{10}}^{\mathrm{12}}$ W), approximately 1 order of magnitude greater than average values reported for the PCCS and for both the western and eastern Indian Ocean . The eddy also transported salt at a rate of $Q_{\text{es}}\approx \mathrm{0.42}$ $\mathrm{Gkg}{\mathrm{s}}^{-\mathrm{1}}$ and freshwater at $Q_{\text{fw}}\approx -\mathrm{0.012}$ Sv. These fluxes are consistent with those estimated for the PCCS under comparable upper-ocean conditions, while remaining roughly an order of magnitude lower than the typical values reported in the Indian Ocean .