Recent improvements in mesoscale characterization of the western Mediterranean Sea: synergy between satellite altimetry and other observational approaches

Pascual, Ananda; Bouffard, Jérôme; Ruiz, Simón; Nardelli, Bruno Buongiorno; Vidal-Vijande, Enrique; Escudier, Romain; Sayol, Juan Manuel; Orfila, Alejandro

doi:10.3989/scimar.03740.15a

Cited by 28 publications

(23 citation statements)

References 54 publications

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“…The SST pattern also shows two cold cores, one centered at 6 • E and the second at 7 • 30 E. The SMDT07 solution also shows a general cyclonic circulation with higher values along the coast, although the protrusions close to Gulf of Genova are less pronounced than in the SST field and only one of the two cores is present (at around 6 • E although the shape is quite different). Note also that there is a disruption of the circulation in the vicinity of Nice (at about 7 • E), with a gradient of ADT almost perpendicular to the slope, indicating that the associated surface geostrophic currents are towards the coast and not parallel as it is expected from the SST patterns and also from previous studies (e.g., Pascual et al, 2013). On the contrary, the SMDT-MED-2014 solution shows a remarkable agreement with the SST fields.…”

Section: Comparison To Sea Surface Temperaturementioning

confidence: 43%

Computation of a new mean dynamic topography for the Mediterranean Sea from model outputs, altimeter measurements and oceanographic in situ data

et al. 2014

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Abstract. The accurate knowledge of the ocean's mean dynamic topography (MDT) is a crucial issue for a number of oceanographic applications and, in some areas of the Mediterranean Sea, important limitations have been found pointing to the need of an upgrade. We present a new MDT that was computed for the Mediterranean Sea. It profits from improvements made possible by the use of extended data sets and refined processing. The updated data set spans the 1993-2012 period and consists of drifter velocities, altimetry data, hydrological profiles and model data. The methodology is similar to the previous MDT by Rio et al. (2007). However, in Rio et al. (2007) no hydrological profiles had been taken into account. This required the development of dedicated processing. A number of sensitivity studies have been carried out to obtain the most accurate MDT as possible. The main results from these sensitivity studies are the following: moderate impact to the choice of correlation scales but almost negligible sensitivity to the choice of the first guess (model solution). A systematic external validation to independent data has been made to evaluate the performance of the new MDT. Compared to previous versions, SMDT-MED-2014 (Synthetic Mean Dynamic Topography of the MEDiterranean sea) features shorter-scale structures, which results in an altimeter velocity variance closer to the observed velocity variance and, at the same time, gives better Taylor skills.

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Section: Comparison To Sea Surface Temperaturementioning

confidence: 43%

Computation of a new mean dynamic topography for the Mediterranean Sea from model outputs, altimeter measurements and oceanographic in situ data

et al. 2014

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“…Bouffard et al (2010) developed innovative approaches to characterize horizontal ocean flows, specifically in terms of current velocity associated with filaments, eddies or shelf-slope flow modifications close to the coast. The methodologies were applied to a series of ocean glider missions colocalized along altimeter tracks, as part of an observational program initiated to validate, intercalibrate and improve multi-platform data dedicated to coastal ocean studies in the Western Mediterranean (Ruiz et al, 2009;Pascual et al, 2010;Pascual et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Assessing SARAL/AltiKa Data in the Coastal Zone: Comparisons with HF Radar Observations

et al. 2015

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We present an initial assessment of SARAL/AltiKa data in the coastal band. The study focuses on the Ibiza Channel where the north-south water exchanges play a key role in controlling the circulation variability in the Western Mediterranean. In this area, the track 16 of SARAL/AltiKa Downloaded by [New York University] at 03:55 27 May 2015 ACCEPTED MANUSCRIPT ACCEPTED MANUSCRIPT2 intercepts the domain covered by a coastal high-frequency (HF) radar system, which provides surface currents with a range up to 60 km. We evaluate the performance of the SARAL/AltiKa Ssalto/Duacs delayed-time along-track products when compared to the HF radar surface velocity fields. SARAL/AltiKa data are retrieved at a distance of only 7 km from the coast putting in evidence the emerging capabilities of new altimeter.The derived velocities resolved the general features of the seasonal mesoscale variability with reasonable agreement with HF radar fields (significant correlations of 0.54), However, some discrepancies appear, which might be caused by ageostrophic velocities as well as inaccurate corrections and editing in the altimeter data.Root mean square (rms) differences between the estimated SARAL/AltiKa and the HF radar velocities are of about 13 cm/s. These results are consistent with recent studies in other parts of the ocean applying similar approaches to Topex/Poseidon and Jason-1 missions and using coastal altimeter corrections.

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“…[29]. The needs to properly access the mesoscales, and more generally the oceanic small scales, have motivated a number of studies dedicated to the reconstruction of higher-resolution SSH fields using other strategies and multi-platform studies [4,20]. In this respect, several studies [12,15,16] rationalize and demonstrate that SST fields can become an active tracer leading to strong correlations with SSH fields.…”

Section: Introduction and Related Workmentioning

confidence: 99%

Improving Mesoscale Altimetric Data From a Multitracer Convolutional Processing of Standard Satellite-Derived Products

Fablet

Verron

Mourre

et al. 2018

IEEE Trans. Geosci. Remote Sensing

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Résumé-Multi-satellite measurements of altimeter-derived Sea Surface Height (SSH) have provided a wealth of information on the ocean. Yet, horizontal scales below 100km remain scarcely resolved. Especially, in the Mediterranean Sea, an important fraction of the mesoscale range, characterized by a small Rossby radius of deformation of 15-20 km, is not properly retrieved by altimeter-derived gridded products. Here, we investigate a novel retreatment of AVISO products with a view to resolving the horizontal scales sensed by current along-track altimeter data. The key feature of our framework is the use of linear convolutional operators to model the fine-scale Sea Surface Height (SSH) detail as a function of different sea surface fields, especially optimally-interpolated SSH and Sea Surface Temperature (SST). The proposed model embeds the Surface Quasi-Geostrophic SST-SSH synergy as a special case. Using an observing system simulation experiment with simulated SSH data from model outputs in the Western Mediterranean Sea, we show that the proposed approach has the potential for improving current optimal interpolations of L4 altimeter-derived SSH fields by more than 20% in terms of relative SSH and kinetic energy mean square error, as well as in terms of spectral signatures for horizontal scales ranging from 30km to 100km. Our results also suggest that SST-SSH relationship may only play a secondary role compared to the inter-scale SSH cascade. We further discuss the relevance of the proposed approach in the context of future altimetric satellite missions.

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Recent improvements in mesoscale characterization of the western Mediterranean Sea: synergy between satellite altimetry and other observational approaches

Cited by 28 publications

References 54 publications

Computation of a new mean dynamic topography for the Mediterranean Sea from model outputs, altimeter measurements and oceanographic in situ data

Computation of a new mean dynamic topography for the Mediterranean Sea from model outputs, altimeter measurements and oceanographic in situ data

Assessing SARAL/AltiKa Data in the Coastal Zone: Comparisons with HF Radar Observations

Improving Mesoscale Altimetric Data From a Multitracer Convolutional Processing of Standard Satellite-Derived Products

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