Seven Years of SMOS Sea Surface Salinity at High Latitudes: Variability in Arctic and Sub-Arctic Regions

Olmedo, Estrella; Gabarró, Carolina; González-Gambau, Verónica; Martínez, Justino; Ballabrera-Poy, Joaquim; Turiel, Antonio; Portabella, Marcos; Fournier, Séverine; Lee, Tong

doi:10.3390/rs10111772

Cited by 57 publications

(64 citation statements)

References 43 publications

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“…With respect to its previous version, a systematic bias in the retrieved salinity is corrected by computing the SMOS climatology (the most probable value for a given lat-long, incidence angle and across-swath distance), which is substituted by a reference value from WOA13. In addition, a temporal bias correction has been refined in this version using near-surface Argo salinity to compute regional averages (see the details in Olmedo et al, 2018).…”

Section: The Bec Productmentioning

confidence: 99%

“…SSS is known to impact the oceanic upper mixing significantly (Latif et al, 2000;de Boyer Montegut et al, 2004;Maes et al, 2006;Furue et al, 2018) via its effect on the surface layer density (Johnson et al, 2012). The SSS also affects the decadal variability of hydrography in the upper waters of the North Atlantic (Reverdin et al, 1997). Using a coupled atmosphere-ocean model and an observed SSS climatology dataset, Mignot and Frankignoul (2003) attributed the interannual variability of the Atlantic SSS to two factors: anomalous Ekman advection and the freshwater flux.…”

Section: Introductionmentioning

confidence: 99%

“…These two SMOS products have successfully resolved the Agulhas salinity front (D'Addezio et al, 2016) and proven useful for estimating precipitation (Supply et al, 2018). The work of Olmedo et al (2018) quantitatively evaluates the accuracy of the SMOS Arctic and sub-Arctic SSS to less than 0.35 psu, but this evaluation against Argo data was limited by the lack of data in the Arctic proper. The present study thus investigates the accuracy of these two L3 SSS products from SMOS in the Arctic Ocean.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of Arctic Ocean surface salinities from the Soil Moisture and Ocean Salinity (SMOS) mission against a regional reanalysis and in situ data

Xie¹,

Raj

Bertino

et al. 2019

Ocean Sci.

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Abstract. Recently two gridded sea surface salinity (SSS) products that cover the Arctic Ocean have been derived from the European Space Agency (ESA)'s Soil Moisture and Ocean Salinity (SMOS) mission: one developed by the Barcelona Expert Centre (BEC) and the other developed by the Ocean Salinity Expertise Center of the Centre Aval de Traitement des Données SMOS at IFREMER (The French Research Institute for Exploitation of the Sea) (CEC). The uncertainties of these two SSS products are quantified during the period of 2011–2013 against other SSS products: one data assimilative regional reanalysis; one data-driven reprocessing in the framework of the Copernicus Marine Environment Monitoring Services (CMEMS); two climatologies – the 2013 World Ocean Atlas (WOA) and the Polar science center Hydrographic Climatology (PHC); and in situ datasets, both assimilated and independent. The CMEMS reanalysis comes from the TOPAZ4 system, which assimilates a large set of ocean and sea-ice observations using an ensemble Kalman filter (EnKF). Another CMEMS product is the Multi-OBservations reprocessing (MOB), a multivariate objective analysis combining in situ data with satellite SSS. The monthly root mean squared deviations (RMSD) of both SMOS products, compared to the TOPAZ4 reanalysis, reach 1.5 psu in the Arctic summer, while in the winter months the BEC SSS is closer to TOPAZ4 with a deviation of 0.5 psu. The comparison of CEC satellite SSS against in situ data shows Atlantic Water that is too fresh in the Barents Sea, the Nordic Seas, and in the northern North Atlantic Ocean, consistent with the abnormally fresh deviations from TOPAZ4. When compared to independent in situ data in the Beaufort Sea, the BEC product shows the smallest bias (< 0.1 psu) in summer and the smallest RMSD (1.8 psu). The results also show that all six SSS products share a common challenge: representing freshwater masses (< 24 psu) in the central Arctic. Along the Norwegian coast and at the southwestern coast of Greenland, the BEC SSS shows smaller errors than TOPAZ4 and indicates the potential value of assimilating the satellite-derived salinity in this system.

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Section: The Bec Productmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evaluation of Arctic Ocean surface salinities from the Soil Moisture and Ocean Salinity (SMOS) mission against a regional reanalysis and in situ data

Xie¹,

Raj

Bertino

et al. 2019

Ocean Sci.

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“…However, the precision degrades in cold water as the sensitivity of L-band radiometer signal to SSS decreases when SST decreases, even though this effect on temporally averaged maps is partly compensated by the increased number of satellite measurements at high latitude. A possibility of using SSS estimates in cold regions derived from L-Band radiometry was, however, demonstrated recently by several working groups (Tang et al (2018), Grodsky et al (2018), Olmedo et al (2018). However SMAP CAP/JPL or SMOS BEC L3 products are spatially averaged from 60 km to more than 100 km.…”

Section: Sea Surface Salinitymentioning

confidence: 99%

Surface waters properties in the Laptev and the East-Siberian Seas in summer 2018 from in situ and satellite data

Tarasenko

Supply

Kusse-Tiuz

et al. 2019

Preprint

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Abstract. Variability of surface water masses of the Laptev and the East-Siberian seas in August–September 2018 is studied using in situ and satellite data. In situ data was collected during ARKTIKA-2018 expedition and then completed with satellite estimates of sea surface temperature (SST) and salinity (SSS), sea surface height, satellite-derived wind speeds and sea ice concentrations. Derivation of SSS is still challenging in high latitude regions, and the quality of Soil Moisture and Ocean Salinity (SMOS) SSS retrieval was improved by applying a threshold on SSS weekly error. The validity of SST and SSS products is demonstrated using ARKTIKA-2018 continuous thermosalinograph measurements and CTD casts. The surface gradients and mixing of river and sea waters in the free of ice and ice covered areas is described with a special attention to the marginal ice zone. The Ekman transport was calculated to better understand the pathway of surface water displacement. T-S diagram using surface satellite estimates shows a possibility to investigate the surface water masses transformation in detail.

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“…The authors wish to make the following corrections to this paper [1]: The authors have detected an error in the program which computes the statistics with ARGO. The definition of some domains were wrong.…”

mentioning

confidence: 99%

Correction: Olmedo, E., et al. Seven Years of SMOS Sea Surface Salinity at High Latitudes: Variability in Arctic and Sub-Arctic Regions. Remote Sensing 2018, 10, 1772

et al. 2019

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Seven Years of SMOS Sea Surface Salinity at High Latitudes: Variability in Arctic and Sub-Arctic Regions

Cited by 57 publications

References 43 publications

Evaluation of Arctic Ocean surface salinities from the Soil Moisture and Ocean Salinity (SMOS) mission against a regional reanalysis and in situ data

Evaluation of Arctic Ocean surface salinities from the Soil Moisture and Ocean Salinity (SMOS) mission against a regional reanalysis and in situ data

Surface waters properties in the Laptev and the East-Siberian Seas in summer 2018 from in situ and satellite data

Correction: Olmedo, E., et al. Seven Years of SMOS Sea Surface Salinity at High Latitudes: Variability in Arctic and Sub-Arctic Regions. Remote Sensing 2018, 10, 1772

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