Abstract
The oceanic kinetic energy cascade, the flux of kinetic energy between currents of different horizontal scales, shapes the structure of the global ocean circulation and the associated heat, salt, nutrient, and oxygen fluxes. Here, we show with a numerical ocean simulation that the surface geostrophic cascade can be estimated from satellite altimetry observations and present its regional distribution and seasonal cycle at scales of 40 to 150 km for large parts of the global ocean based on observations. The time-mean cascade is inverse (towards larger scales), strongest in large-scale current systems, and decreases with distance from these systems. In the open ocean, the inverse cascade is associated with a maximum in late winter at the smallest scales studied, which transitions to scales larger than 100 km within two to three months, consistent with the widespread absorption of mixed-layer eddies by mesoscale eddies in spring.
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Introduction
Ocean motions can be decomposed into movements at different horizontal scales ranging from large-scales (\({{{{{{{\mathscr{O}}}}}}}}\)(1000 km)) through mesoscales (\({{{{{{{\mathscr{O}}}}}}}}\)(100 km)) and submesoscales (\({{{{{{{\mathscr{O}}}}}}}}\)(100 m) - \({{{{{{{\mathscr{O}}}}}}}}\)(10 km)) to microscales (<\({{{{{{{\mathscr{O}}}}}}}}\)(100 m)). The flux of kinetic energy (KE) between ocean currents at different scales, the KE cascade, plays a key role in several aspects of global climate. First, in combination with the transformation of KE into available potential energy (and vice versa), the cascade mediates the balance between the oceans forcing by the atmosphere, primarily by wind at large scales, and the dissipation of KE into heat at molecular scales1. Second, the KE cascade controls the scale-distribution of KE including the strength of the subtropical gyre2, the strength and position of large-scale currents such as the Gulf Stream3,4, the strength of inter-ocean exchanges such as Agulhas leakage5, and the strength and distribution of ocean mesoscale eddies6,7,8 and thus the associated transports of heat, salt, nutrients, and oxygen. Third, through ocean-atmosphere interactions, the ocean and atmosphere KE cascades determine their response times to external forcing9. This induces a modulation of the atmospheric circulation by the oceanic KE cascade. In addition to being a key component of the climate system, understanding the KE cascade is critical for the validation and development of climate models, particularly regarding the parameterization of the sub-grid-scale energetic fluxes and dissipation.
For the large mesoscales, the KE flux was computed from gridded sea-surface height data that were interpolated from along-track satellite altimetry measurements on a regular 0.25∘ and daily grid (AVISO) assuming geostrophy and an f-plane6,10,11,12. The results showed an inverse cascade (from smaller to larger scales) at scales larger than about 75 km and a forward cascade (from larger to smaller scales) at smaller scales. While the forward cascade was later found to be an artifact of the filtering and interpolation technique onto the regular grid, the inverse cascade at larger scales was found to be robust to filtering11,12. At scales of the maximum inverse flux (about 200 km), the cascade has been shown to be orders of magnitude smaller in the open ocean compared to regions of strong current systems13. This is not surprising, as the inverse cascade is stopped at smaller scales in the open ocean, for example due to the Rhines effect14. Substantial inverse fluxes occur at these scales only in the large-scale current systems, where very large mesoscale eddies form as a consequence of large-scale instabilities and interact with the large-scale currents. Regional submesoscale-permitting simulations and regional observations have shown that the inverse cascade extends into the submesoscales to scales of the mixed-layer Rossby radius of deformation (about 15 km)12,15,16,17,18,19,20. Applying a filtering approach for computing the KE flux21,22,23,24 to submesoscale-permitting model data, it was found that the underlying process of the submesoscale inverse cascade is primarily the absorption of submesoscale mixed layer eddies by mesoscales eddies17. Consistently, the maximum of the submesoscale inverse flux has been found to occur immediately after the submesoscale season in late winter and to shift to larger scales in spring17. Based on observations, the existence of the submesoscale inverse KE cascade and its seasonality could only be demonstrated for small ocean regions16,18,19,20. Indirect evidence that this submesoscale inverse cascade is active in large parts of the global ocean has recently been provided by high-resolution satellite products25. Recent model studies have applied Helmholtz decomposition and principal strain coordinate transformation prior to the computation of the scale KE flux, and have shown that the inverse cascade is primarily driven by geostrophically balanced flows26,27. This confirms that it should be possible to analyze the near-surface inverse KE cascade on the basis of sea-surface height.
In this study, we provide an observation-based estimate of the surface geostrophic KE cascade and its seasonal cycle at scales of 40–150 km in large parts of the global ocean. We use information on the dynamics in the respective scale-band from satellite along-track altimetry data measured by JASON-3 as well as from a submesoscale-permitting simulation of the Atlantic. The KE flux can not be computed directly from along-track sea-surface height. However, using the simulation, we prove that it is possible to estimate the KE flux from the simulated sea-surface height along the tracks of JASON-3 and apply the proposed estimation technique to the actual measurements.
Results
If the measured along-track absolute dynamic topography (η) is dominated by geostrophic flows, the across-track f-plane geostrophic flow component can be computed as \(u=-\frac{g}{f}{\eta }_{y}\), where g = 9.81 m s−2 is the gravitational acceleration, \(f=2\Omega \sin (2\pi \frac{\theta }{36{0}^{\circ }})\) is the Coriolis parameter with the Earth’s angular speed \(\Omega =\frac{2\pi }{86400}\,{{{{{{{{\rm{s}}}}}}}}}^{-1}\) and the latitude θ, and y is the along-track direction with increasing latitude. Partial derivatives of a with respect to b are written here and in the following as \(\frac{\partial a}{\partial b}={a}_{b}\). For this study, we use five years of tide-corrected and filtered measurements of η taken by the JASON-3 satellite along the tracks shown in Fig. 1a. From these, we estimate the surface geostrophic 5∘ × 5∘ domain-averaged scale-KE flux through a specific scale L as
where angle brackets indicate averages over 5∘ × 5∘ subdomains for each measurement cycle, C is an estimation coefficient identified from a numerical ocean simulation, and ρ0 = 1024 kg m−3 is the standard density. The overlines denote fields convoluted with a tophead kernel whose length is equal to that of the respective scale L and which is normalized so that it integrates to 1. The computation of C and the proof that the proposed estimation works is given in the “Methods” section.
If η is not dominated by geostrophic flows, the computation of geostrophic currents from the measurements fails. A lower bound for the scales at which the respective gradients of η can be used to derive geostrophic flows is provided by the transition scale from balanced to unbalanced flows T. T is estimated from the JASON-3 along-track data with a previously published method28 and is averaged over the same 5∘ × 5∘ grid on which we estimate the scale KE flux. T is associated with lower values in regions with strong balanced flows (large-scale currents and surface eddy pathways) and higher values in regions with weak balanced flows (weak eddy activity)28. Furthermore, T is associated with a seasonal cycle, with lower values in spring when there are more balanced submesoscale vortices, and higher values in summer and autumn when the surface signature of internal waves is amplified29. In Figs. 1 and 2 we highlight with black lines the regions, scales, and seasons where the results are partially corrupted by too strong imprints of unbalanced flows into the absolute dynamic topography measurements. Furthermore, we exclude the tropics between 15∘S and 15∘S from our analysis, because the baroclinic mode-1 and mode-2 diurnal tides significantly affect the SSH-spectrum30 there, and consequently T exceeds 75 km throughout the year31.
The time-mean scale KE flux
The time-mean estimated fluxes at scales of 60, 140, and 200 km are shown in Fig. 1. The largest (inverse) fluxes occur at all scales in regions of very strong near-surface current systems, such as the Gulf-Stream - North-Atlantic-Current system, the Agulhas system, the Brazil-Malvinas-Confluence or the Kuroshio. The further away from the large-scale currents, the smaller the fluxes. Fluxes at 140 km and 200 km scales are very close to each other and have substantial amplitudes almost only in regions of large-scale current systems. At 200 km, the pattern is very similar to the one presented in a previous study based on gridded AVISO data13. At this scale, almost no time-mean fluxes are found in the open ocean. At 60 km, fluxes of about 10–20 mW km−1 m−3 occur in large parts of the mid-latitudes. This is consistent with wide-spread mixed-layer instabilities leading to the formation of submesoscale eddies, which are subsequently absorbed by the mesoscales17.
The seasonal cycle of the scale KE flux
The seasonal cycle of Πest and its scale distribution are shown in Fig. 2. At 60 km, the anomalies of the FMA-mean (Fig. 2a) and the ASO-mean (Fig. 2b) relative to the 2017–2021 mean flux show enhanced inverse fluxes in spring and reduced inverse fluxes in autumn for most open ocean regions. This is consistent with a previously published map of the seasonal difference in geostrophic KE computed from along-track altimetry25. In the open ocean, enhanced fluxes occur in winter and spring with a maximum in early spring (February in the Northern Hemisphere and July in the Southern Hemisphere) at 40 km scale (Fig. 2c, d). During the following three to four months, enhanced fluxes occur at increasingly larger scales. Deeper mixed-layer depths in winter allow for the accumulation of more available potential energy at mixed-layer fronts. Mixed-layer baroclinic instability of the fronts releases this potential energy into KE in the form of mixed-layer eddies25. These eddies have a diameter on the order of the mixed-layer Rossby deformation radius (about 15 km) and are stronger and more frequent in winter. Subsequently, these eddies grow and are absorbed by mesoscale eddies. The absorption process takes about 2–3 months, resulting in a shift of the maximum scale KE flux from late winter at 30 km to late spring at 140 km. This climatological scale-time pattern of the observation-based estimated inverse flux is consistent with that of the power-spectral density of KE computed from AVISO32 and along-track altimetry25. The same consistency was also found in a simulation of the open ocean near the Agulhas-system17. In regions of strong large-scale flows, in particular the Gulf Stream and Kuroshio extensions, the Brazil Malvinas Confluence, and the Agulhas region and Return Current, the estimated fluxes at 60 km mainly show an opposite seasonal cycle to that of the open ocean. This is consistent with results from a recent model study of the Gulf Stream, which found a stronger seasonal cycle of the balanced cascade outside of the Gulf Stream core, including a scale-shift of the maximum inverse flux and a reduced seasonality without a scale-shift of the maximum in a region that partially includes the Gulf Stream26. Furthermore, this is consistent with previously published results on along-track altimetry-based geostrophic KE levels, which revealed an opposite seasonal cycle within the strong current systems25. We speculate that the reason for this phenomenon is that other energetic submesoscale and mesoscale processes overcome the seasonal cycle of mixed-layer instabilities and the subsequent inverse cascade of the resulting mixed-layer eddies. In the future, these other processes need to be identified.
Particularly in summer, in regions of weak mesoscale activity at scales of 70 km and smaller, the measured absolute dynamic topography is not dominated by balanced flows and −Πest gives spuriously enhanced values. This manifests itself in a spurious reduction or reversal of the seasonal cycle at 60 km in regions such as the North East Pacific or the Central Atlantic, where the maximum T of the respective season is larger than 60 km (contours and hatches in Fig. 2a, b), as well as small secondary maxima of −Πest in summer (August in the Northern Hemisphere and February in the Southern Hemisphere) mainly at scales smaller than 70 km (Fig. 2c, d).
Methods
JASON-3 satellite along-track altimetry data
JASON-3 measures the absolute dynamic topography η, the sum of the sea-level anomaly and the mean dynamic topography, between 66∘S and 66∘N with an along-track resolution of about 6 km at 1 Hz and a repeated measurement of each track every 10th day. Below scales of 25–35 km, JASON-class data are associated with noise33,34. This noise is associated with a seasonal cycle that is similar, but not identical, to that of the submesoscale KE level34 (at least north of 40∘S35): higher noise and submesoscale KE in winter and lower in summer. The sea-level anomaly is available in an original (unfiltered) and a low-pass “filtered” version. Fourier analysis shows that the seasonal cycle of power spectral density of the unfiltered η has deviations from 20 km on all scales larger than 30 km (Fig. 3e), indicating that the seasonal cycle at these scales is not corrupted by measurement noise. Furthermore, for this study, we use the tide-corrected data, where the barotropic tides and the coherent part of the baroclinic tides for modes M2, K1, O1, and S2 have been removed from the data. Note, however, that there is a residual effect of tides that cannot be corrected. Note also that η is the sea-surface height (SSH) corrected by the geoid. Since the geoid is associated with very large scales, this correction is not relevant for the analysis presented in this study. Therefore, η is also referred to as SSH in the following.
GIGATL1 simulation
The GIGATL1 simulation36 used here has been performed with the Coastal and Regional Ocean COmmunity model (CROCO, 10.5281/zenodo.7415055), which is based on the Regional Ocean Modeling System (ROMS37). The integration is performed on an Arakawa C-grid38 using 100 vertical terrain-following sigma-levels where the bathymetry is taken from the SRTM30plus dataset. Vertical mixing is parameterized with the k-epsilon turbulence closure scheme with applied Canuto A stability function. No explicit lateral diffusivities and viscosities are used. The effect of bottom friction is parameterized with a logarithmic law using a roughness length of 0.01 m. The GIGATL1 grid is orthogonal based on an oblique Mercator projection and designed to have nearly uniform spacing in both horizontal dimensions. The grid spacing varies from 1 km at the central longitude of the grid to 735 m at the west and east extremes of the grid. A simulation with a grid-spacing three times as large as the one of GIGATL1, “GIGATL3”, has been initialized in January 2004. Initialization fields and boundary conditions are from Simple Ocean Data Assimilation (SODA39). GIGATL1 is initialized from the restarts of GIGATL3 in July 2007 and integrated twice, one experiment with simulated tides and one experiment without simulated tides. All simulations are forced by hourly atmospheric forcing data from the Climate Forecast System Reanalysis (CFSR) with a bulk formulation and a stress correction approach to parameterize the surface ocean current feedback to the atmosphere40. Barotropic tidal forcing at the boundaries and tidal potential and self attraction from TPXO7.2 and GOT99.2b are applied to GIGATL3 and GIGATL1 with tides. In this study, we analyze snapshots every fifth day over the period April 2008 to March 2009 for both simulations.
Model validation
The temporal standard deviation of SSH, computed from daily averages during Apr 2008–Mar 2009 averaged onto the AVISO grid, shows similar large-scale patterns for GIGATL1 without simulated tides and AVISO (Fig. 3a, b). The largest values occur in the region of the Gulf Stream, North Atlantic Current, and Brazil Malvinas Confluence systems, moderate values in the surrounding ocean, as well as in the Agulhas ring path, the Azores Current, and the North Equatorial Counter Current, and low values above the shelves and in the central subtropical gyres. The simulated SSH variabilities are smaller than in the observations in the Gulf Stream extension, the Brazil Current extension, and the Agulhas Ring Path, and larger north of 50∘N. The standard deviation of SSH in the Northwest-Corner and the North Atlantic Current are in remarkably good agreement. The too low simulated SSH variability in the Agulhas ring path is a result of the monthly boundary conditions applied at the southern boundary of the domain, which are not frequent enough to resolve the full variability of the energetic eddies drifting out of the Agulhas region into the Atlantic.
Time-mean horizontal wavenumber spectra computed from SSH at JASON-3 tracks in a 20∘ × 20∘ domain in the open ocean show similar results for JASON-3 and GIGATL1 without simulated tides (Fig. 3c). For comparison, the GIGATL1 SSH is extracted at the measurement locations of JASON-3 from model snapshots every fifth day. The SSH-spectra from GIGATL1 without tides and the unfiltered, tide-corrected JASON-3 data show a very good agreement at scales larger than 60 km. At scales smaller than 60 km, the spectrum of the observations shows higher values compared to the simulation, which could be due to observational noise or unresolved processes. The spectrum of the filtered JASON-3 SSH follows that of the unfiltered down to 45 km, but with a shallower slope between 60 km and 45 km than in the simulation, which shows a k−4 slope down to 30 km.
Hovmöller plots of the monthly climatology of the SSH-spectrum for both the simulation and the observations (Fig. 3d and e) show maxima that shift from winter at scales of \({{{{{{{\mathscr{O}}}}}}}}(10\,km)\) to summer at scales of \({{{{{{{\mathscr{O}}}}}}}}(100\,km)\) similar to the maximum inverse cascade estimated from JASON-3 (Fig. 2c). This shift is consistent with previous results from AVISO and simulations17,32, as well as with a maximum of submesoscale activity in winter and spring and a subsequent inverse cascade involving the growth of submesoscale eddies and their absorption by mesoscale eddies17. For the simulation, the Hovmöller plot is more patchy and shows the shift to larger scales one to two months later than in the observations. This can be due to the specific conditions in the single simulated year, which is compared here to a five-year average from the observations.
The scale KE flux
With the filtering approach, the scale KE flux can be computed as
where u and v are the total horizontal velocity components in perpendicular directions x and y21,22,23,24. The overlines denote fields convoluted with a two-dimensional top-head kernel whose diameter is equal to that of the respective scale L and which is normalized by the respective enclosed area so that it integrates to 1. Π is only computed if the full kernel area is filled with data. To reduce the memory requirement for convolutions in the computation of Π, which increases exponentially with the respective scale, u and v are first averaged within 5 × 5 grid-cell boxes. This has almost no effect on the results, as the variations of the simulated values on the near-grid-scale are very small. Due to limits in computational time and storage, the computations were only feasible for snapshots every fifth day. While this does not affect the results for area averages, the results for time averages may contain aliasing effects.
Large amplitudes of surface time-mean Π occur mainly in regions of strong current systems. While the Gulf Stream - North Atlantic Current and Brazil Malvinas Confluence systems show time-mean fluxes of both signs at 60 km scales, the equatorial current system is associated with a time-mean forward cascade (Fig. 4a). The area-mean flux for a large region in the North Atlantic, shows a dominant forward cascade in summer and autumn (JJASON) and a dominant inverse cascade in winter and spring (DJFMAM) (lower panel in Fig. 4a). The maximum inverse cascade shifts by a few months with increasing scale. This is consistent with the absorption of the winter-time submesoscale vortices by the mesoscales which takes this time17, and with the seasonal cycle of the SSH spectrum in the North Atlantic Current (Fig. 3d).
The geostrophic scale KE flux can be computed by using (2), with the geostrophic velocity. Noisy large-amplitude time-mean geostrophic fluxes occur on the shelf, as well as in the tropics (Fig. 4b). Away from these regions, the time-mean geostrophic flux is inverse almost everywhere. When averaged over 5∘ × 5∘ regions, the instantaneous geostrophic flux is only very rarely forward. In the time-mean, only a few regions near the coast or near the boundary of the domain show time-mean forward fluxes (Fig. 4c). Geostrophic fluxes averaged over the North Atlantic box show a dominant inverse cascade at all times and scales as well (bottom panels in Fig. 4b and c). The inverse cascade is maximum at the smallest investigated scales in February, March, and April, which shifts to April and May at scales of 100 km and larger. The similar timing and amplitude of the inverse cascade from the total velocity (Fig. 4a) support that balanced flows are primarily responsible for the inverse cascade, as shown in previous studies26,27. Furthermore, this confirms that the near-surface winter and spring inverse cascade can be studied using SSH. However, for the interpretation of the geostrophic flux, one needs to be aware that the ageostrophic (net forward) cascade reduces the geostrophic (net inverse) cascade mainly at scales smaller than 40 km throughout the year (Fig. 4a). Note that the results presented here for the surface cascade from total velocities correspond to an extreme case, as forward fluxes are surface intensified and restricted to the very upper ocean, while the inverse cascade driven by the balanced flows extends deep into the ocean17,27. The estimate of the geostrophic flux presented in the “Results” section is therefore more representative of the cascade over the depth-range of surface intensified balanced flows than of the cascade directly at the surface.
Estimating the scale KE flux from along-track data
In order to access the smallest scales observed by satellite altimetry, we must use the non-gridded along-track SSH product. However, it is not possible to compute the geostrophic Π directly from along-track SSH, as one can only compute the across-track geostrophic velocity component. This implies that, of all the terms in (2), only the Leonard stress \(\overline{{u}^{2}}-{\overline{u}}^{2}\), and the along-track derivative \({\overline{u}}_{y}\) are computable. For this study, we propose to estimate the flux with equation (1), which includes the product of these two terms giving the correct unit of a scale KE flux. Since \(\overline{{u}^{2}}-{\overline{u}}^{2}\) is always positive, using the absolute value of \({\overline{u}}_{y}\) along with the minus sign means that the estimated geostrophic flux is globally inverse, consistent with what we found for the time- and area-averaged geostrophic fluxes in the simulations (Fig. 4c), with AVISO based observational studies at larger scales6,11, and with theoretical studies that showed that the balanced flows are associated with inverse fluxes26,27. However, in some shelf regions, 5∘ × 5∘ averaged forward geostrophic fluxes do occur in our simulations, which implies that the estimated fluxes from JASON-3 need to be interpreted with care on the shelf. Trying to estimate the sign of the geostrophic flux directly, for example by using \({\overline{u}}_{y}\) without taking its absolute value and removing the minus sign in equation (1), has not been successful.
We average both subterms in equation (1) over 5∘ × 5∘ boxes, as the estimation works better the larger this region is, and as they are large enough to cover reasonable amounts of along-track data (which have a track-to-track distance of several degrees for ascending and descending tracks (Fig. 1a). This technique is associated with the inclusion of information from both horizontal directions, as the angle between ascending and descending tracks is large (Fig. 1a), and thus reduces the effect of the isotropy assumption that is necessarily made when one-dimensional data is cut from a two-dimensional field and then used to make a statement about that field.
The estimation coefficient C is identified from the simulations for each chosen scale by area- and time-averaging the term \(\langle \Pi \rangle /(-{\rho }_{0}\langle {\tau }_{uu}\rangle \langle | {\overline{u}}_{y}| \rangle )\), where 〈Π〉 is computed from the 5 × 5 grid-cell averaged SSH field and the divisor terms from the SSH extracted from the simulation along the JASON-3 tracks. For the final area-averaging of the term, regions near the coast and boundary of the simulation, where the respective 5∘ × 5∘ domain includes only a small ocean area are excluded (shown hatched in Fig. 4c), as well as regions and times where L < T. For scales of [30,40,50,60,70,80,90,100,120,140,160,180,200] km, C is computed to be [0.32,0.26,0.23,0.22,0.20,0.19,0.18,0.17,0.15,0.14,0.13,0.12,0.11] and thus shows an exponential decay with larger scales. Computing C from a parallel simulation with simulated tides, gives similar values (see Supplementary Note 1 and Supplementary Fig. 1).
Comparisons of the original and estimated time-mean fluxes at a scale of 60 km and their area-mean in the North Atlantic box show that the estimation reproduces the horizontal and temporal patterns and their amplitudes reasonably well (Fig. 4c, d). Large differences only show up in the Gulf Stream extension, where the flux is overestimated, and in a few shelf regions where the original flux is forward and thus cannot be estimated correctly with equation (1). The former may be due to the extreme non-isotropy of the core Gulf Stream extension and indicates that the fluxes are overestimated in similar energetic non-isotropic flows, such as the western Kuroshio or the Agulhas retroflection. Outside of these regions and small parts of the shelf, the estimation works very well. The pattern and amplitude of the estimated fluxes from GIGATL1 without simulated tides are very close to those estimated from JASON-3 data (Fig. 1). However, for the observations, higher fluxes are estimated in the Gulf Stream extension, the northern Brazil Malvinas Confluence, and the Agulhas ring path, which is consistent with higher mesoscale eddy activity in the observations (Fig. 3a, b). The largest differences between the area-averaged original and estimated geostrophic Π occur in April, where the maximum flux event is a bit overestimated (bottom panels Fig. 4c and d). Furthermore, the weak summer inverse cascade is slightly overestimated. This contributes to a slightly reduced amplitude of the seasonal cycle of the estimated flux compared to the original flux.
The horizontal scale of a SSH feature in the two-dimensional field may differ from that identified from the SSH along a track that cuts through the same feature. For example, if waves do not propagate in the direction of the track, they will appear to be associated with a larger wavelength along the track. Or if a track cuts through a circular eddy and does not cross its center, the eddy will appear to be smaller from the track information. The fact that the flux estimated from the one-dimensional SSH data agrees with that from the two-dimensional original shows that the estimation procedure corrects for this issue. We hypothesize that, on average, shorter scale features erroneously imprint at larger scales, and that the decreasing C with increasing scale corrects for this by reducing the pre-estimate (Eq. (1) without C) more at larger scales. Future research needs to address the question, why the estimation works.
Data availability
The data to reproduce the figures of the present paper can be accessed at https://doi.org/10.17882/96675. Furthermore, with the same link, the transition scale from balanced to unbalanced flows as well as the estimated scale kinetic energy flux can be accessed. The ocean model output used for this study is too large for an online upload. The full JASON-3 data used for this study is available at https://data.marine.copernicus.eu/product/SEALEVEL_GLO_PHY_L3_MY_008_062/services. The coastline shown in the Figures has been taken from www.naturalearthdata.com/downloads/110m-physical-vectors/.
Code availability
All the code to reproduce the study is available at https://doi.org/10.17882/96675. The scale kinetic energy flux computations based on the two-dimensional model data has thereby been performed with a modified version of the code published at https://doi.org/10.5281/zenodo.4486265.
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Acknowledgements
The authors gratefully acknowledge support from the French National Agency for Research (ANR) through the project DEEPER (ANR-19-CE01-0002-01). J.G. further gratefully acknowledges support from ISblue “Interdisciplinary graduate school for the blue planet” (ANR-17- EURE-0015) and O.V. from the French Space Agency (CNES) via the French SWOT TOSCA program. This work was performed using HPC/AI resources from GENCI-TGCC (Grant 2023-A0090112051) and from DATARMOR at Ifremer, Brest, France.
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R.S. and J.G. designed the study. J.G. performed the numerical model simulations. O.V. computed the monthly climatology of the transition scale from balanced to unbalanced flows. R.S. developed and executed all other analysis, produced the figures and wrote the text. J.G. and O.V. contributed to the discussion of the results and the writing of the manuscript.
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Schubert, R., Vergara, O. & Gula, J. The open ocean kinetic energy cascade is strongest in late winter and spring. Commun Earth Environ 4, 450 (2023). https://doi.org/10.1038/s43247-023-01111-x
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DOI: https://doi.org/10.1038/s43247-023-01111-x
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