Sea Surface Salinity

Generating improved calibrated global Sea Surface Salinity fields from all available satellite L-band radiometer measurements.

About

Generating improved calibrated global Sea Surface Salinity fields from all available satellite L-band radiometer measure

Sea Surface Salinity (SSS) is an Essential Climate Variable (ECV) that plays a fundamental role in the density-driven global ocean circulation, the water cycle and climate.

The satellite SSS observation from the Soil Moisture and Ocean Salinity (SMOS), Aquarius, and Soil Moisture Active Passive (SMAP) missions have provided an unprecedented opportunity to map SSS over the global ocean since 2010 at a 40-150km scale with a revisit every 2 to 3 days. This observation capability has no historical precedent and has brought new findings concerning the monitoring of SSS variations related to climate variabilities such as El Niño-Southern Oscillation, Indian Ocean Dipole, and Madden-Julian Oscillation, and the linkages of the ocean with different elements of the water cycle such as evaporation and precipitation and continental runoff. In addition, it has enhanced the understanding of various ocean processes such as tropical instability waves, Rossby waves, mesoscale eddies and related salt transport, salinity fronts, haline hurricane wake, river plume variability, and cross-shelf exchanges. There is also an emerging use of satellite SSS to study ocean biogeochemistry, e.g. linked to air-sea CO2 fluxes.

Following the success of the initial oceanographic studies implementing this new variable, the European Space Agency (ESA) funded a new Climate Change Initiative (CCI) Sea Surface Salinity (SSS) project (2018-2025). The CCI+SSS project aims to generate improved calibrated global SSS fields over sixteen years (2010-2025) from all available satellite L-band radiometer measurements, with regional extensions utilising C-band radiometer data. This initiative seeks to leverage the full potential of the ESA/Earth Explorer SMOS mission, in conjunction with the SMAP and AQUARIUS satellite missions, by assembling expert teams in earth observation, satellite data validation, and the study of climate variability.

CCI+SSS is dedicated to delivering data products adapted explicitly to climate applications (i.e. including information on accuracy and uncertainty within the data). Furthermore, this project will explore the need to improve the performance of current SSS algorithm retrievals and directly contribute to climate science studies submitted to the following International Panel on Climate Change (IPCC) Annual Review for Climate Change in 2020. This initiative underscores the indispensable role of SSS in our understanding of climate dynamics, offering valuable insights for academics, students, environmentalists, and policymakers engaged in climate change research.

Frequently Asked Questions

What is SSS?

SSS stands for Sea Surface Salinity. For more information, please refer to the Useful Links section above.

Where can I find SSS data?

The Data section above contains links to data provided by this project. The Related Links section contains alternative data sources.

What is CCI?

CCI stands for the Climate Change Initiative, a programme initiated by ESA. For more information, please refer to the CCI homepage.

What is ECV?

ECV stands for Essential Climate Variable. For more information, please refer to the ECV Inventory page.

What is ESA?

ESA stands for the European Space Agency. For more information, please visit the ESA website.

What is EO?

EO stands for Earth Observation.

Data

Data pertaining to the Sea Surface Salinity project is sourced by the CCI Open Data Portal and visual analysis of the data is provided through the CCI Toolbox.

Sea Surface Salinity (February 2010 - September 2020) (Version 3.21) - interactive glone

Key Documents

Insights and Methodologies of the CCI+SSS Initiative

Dokumentenname	Version	Ausgabedatum
[D1.1] User Requirement Document (URD)	3.1	21. März 2023
[D1.2] Product Specification Document (PSD) (*)	3.0	14. Oktober 2022
[D2.1] Product Validation and Algorithm Selection Report (PVASR) (*)	4.0	20. Juni 2023
[D2.2] Algorithm Theoretical Basis Document (ATBD) (*)	4.0	15. Juli 2023
[D2.3] End to End ECV Uncertainty Budget (E3UB) (*)	4.0	21. Juni 2023
[D2.4] Algorithm Development Plan (ADP)	4.1	7. November 2022
[D2.5] Product Validation Plan (PVP) (*)	2.0	19. Juni 2023
[D3.1] System Requirement Document (SRD) (*)	4.1	31. Mai 2023
[D4.1] Product Validation and Intercomparison Report (PVIR) (*)	4.0	21. Januar 2024
[D4.3] Product User Guide (PUG)	4.1	21. Januar 2024
[D5.1] Climate Assessment Report (CAR) (*)	4.1	29. November 2023

Dokumentenname	Version	Ausgabedatum
[D1.1] User Requirement Document (URD)	2.0	20. März 2020
[D1.2] Product Specification Document (PSD)	2.3	19. September 2021
[D1.3] Data Access Requirement Document (DARD)	2.0	24. November 2021
[D2.1] Product Validation and Algorithm Selection Report (PVASR)	3.1	19. September 2021
[D2.2] Algorithm Theoretical Basis Document (ATBD)	3.1	2. September 2021
[D2.3] End to End ECV Uncertainty Budget (E3UB)	3.1	13. September 2021
[D2.4] Algorithm Development Plan (ADP)	3.1	14. September 2021
[D2.5] Product Validation Plan (PVP)	1.1	4. Dezember 2019
[D3.1] System Requirement Document (SRD)	1.1	6. Dezember 2019
[D3.2] System Specification Document (SSD)	3.1	15. September 2021
[D3.3] System Verificaiton Report (SVR)	2.2	22. Januar 2021
[D4.1] Product Validation and Intercomparison Report (PVIR)	3.0	15. September 2021
[D4.2] Climate Research Data Product (CRDP)	2.0	8. November 2021
[D4.3] Product User Guide (PUG)	3.1	28. Juli 2021
[D5.1] Climate Assessment Report (CAR)	3.2	8. November 2021

Team

The Sea Surface Salinity_cci project team comprises nine scientific and industrial partners from the UK, France, Spain, Germany and Luxembourg.

The following companies make up this consortium CCI+SSS Phase 2 (2022-2025):

ARGANS Ltd (United Kingdom)
Laboratoire d'Océanographie et du Climat (LOCEAN) (France)
Laboratoire d'Océanographie Physique et Spatiale (LOPS) (France)
Institut français de recherche pour l'exploitation de la mer (IFREMER) (France)
ACRI-ST (France)
AdwäisEO (Luxemburg)
Ocean Scope (France) (Spain)
National Oceanography Centre (NOC) (United Kingdom)
Laboratoire d'Etudes en Géophysique et Océanographie Spatiales (LEGOS) (France)
Nansen Environmental and Remote Sensing Center (Norway)
MetOffice (United Kingdom)
Mercator Ocean (France)

With additional support from the following external partners:

NASA's Jet Proplusion Laboratory (JPL) (USA)
NASA's Goddard Space Flight Center (GSFC) (USA)
Remote Sensing Systems (RSS) (USA)

Publications

Advancing Climate Science: Peer-Reviewed Publications from the CCI+SSS Project

Akhil, V. P., J. Vialard et al. Bay of Bengal Sea surface salinity variability using a decade of improved SMOS re-processing. Remote Sensing of Environment. 2020. https://doi.org/10.1016/j.rse.2020.111964
Boutin, J., J.L. Vergely, E. Dinnat, P. Waldteufel, F. D’Amico, N. Reul, A. Supply, C. Thouvenin-Masson. Correcting Sea Surface Temperature Spurious Effects in Salinity Retrieved From Spaceborne L-Band Radiometer Measurements. IEEE Transactions on Geoscience and Remote Sensing. 2020.
Boutin, J., S. Yueh, R. Bindlish, S. Chan, D. Entekhabi, Y. Kerr, N. Kolodziejczyk, T. Lee, N. Reul, M. Zribi. Soil Moisture and Sea Surface Salinity, review papersubmitted to Surveys in Geophysics. special issue Oceanography, Hydrology and Glaciology from Space. 2022.
Boutin, J., N. Reul, J. Koehler, A. Martin, R. Catany, S. Guimbard, F. Rouffi, et al.. Satellite-Based Sea Surface Salinity Designed for Ocean and Climate Studies. Journal of Geophysical Research. 2021. https://doi.org/10.1029/2021JC017676
Boutin, J. , Yueh, S., Bindlish, R. , Chan, S., Entekhabi, D., Kerr, Y., Kolodziejczyk, N., Lee, T. , Reul, N. & Zribi, M.. Soil Moisture and Sea Surface Salinity Derived from Satellite-Borne Sensors. Surv Geophys. 2023. https://doi.org/10.1007/s10712-023-09798-5
Gévaudan, M., Durand, F., & Jouanno, J.. Influence of the Amazon-Orinoco discharge interannual variability on the western tropical Atlantic salinity and temperature. Journal of Geophysical Research: Oceans. 2022. https://doi.org/10.1029/2022JC018495
Gibert, F., Boutin, J., Dierking, W., Granados, A., Li, Y., Makhoul, E., . ... Zhang, X.. Results of the Dragon 4 Project on New Ocean Remote Sensing Data for Operational. Remote Sensing. 2021.
Olivier, L. , G. Reverdin, J. Boutin, R. Laxenaire, D. Iudicone , S. Pesant , Paulo H.R. Calil, J. Horstmann, D. Couet, J. M. Erta, P. Huber, H. Sarmento, A. Freire, A. Koch-Larrouy, J.-L. Vergely, P. Rousselot, S. Speich,. Late summer northwestward Amazon plume pathway under the action of the North Brazil Current rings. JGR-Oceans. 2022.
Olivier, L.; Boutin, J.; Reverdin, G.; Lefèvre, N.; Landschützer, P.; Speich, S.; Karstensen, J.; Labaste, M.; Noisel, C.; Ritschel, M.; et al.. Wintertime process study of the North Brazil Current rings reveals the region as a larger sink for CO2 than expected. Biogeosciences 2022. Copernicus Publications on behalf of the European Geosciences Union. 2022. https://doi.org/10.5194/bg-19-2969-2022
Olivier, L., Reverdin, G., Hasson, A. & Boutin, J.. Tropical instability waves in the Atlantic ocean: Investigating the relative role of sea surface salinity and temperature from 2010 to 2018. Journal of Geophysical Research: Oceans. 2020. https://doi.org/10.1029/2020JC016641
Montero, M. Reul, Nicolas; Vialard, Jérôme; Brachet, Sidonie; Guimbard, Sebastien; Vandermark, Douglas; Torunadre, Jean. SSS estimates from AMSR-E radiometer in the Bay of Bengal: algorithm principles and limits. IEEE Transactions on Geoscience and Remote Sensing. 2022. https://ieeexplore.ieee.org/document/10217008
Popp, T., et al.. Consistency of satellite climate data records for Earth system monitoring. Meteor. Soc.. 2020. https://doi.org/10.1175/BAMS-D-19-0127.1
Reul, N. et al.. Sea Surface Salinity estimates from Spaceborne L-band radiometers: an overview of the first decade of observation (2010-2019). Remote Sensing of Environment. 2020. https://doi.org/10.1016/j.rse.2020.111769
Reverdin, G., et al.. Formation and Evolution of a Freshwater Plume in the Northwestern Tropical Atlantic in February 2020. Progress in Oceanography. 2021. https://doi.org/10.1029/2020JC016981
Stammer, D., M. S. Martins, J. Köhler, and A. Köhl. How well do we know ocean salinity and its changes?. Progress in Oceanography. 2021. https://doi.org/10.1016/j.pocean.2020.102478
Supply, A., Boutin, J., Kolodziejczyk, N., Reverdin, G., Lique, C., Vergely, J.-L., & Perrot, X.. Meltwater lenses over the Chukchi and the Beaufort seas during summer 2019: From in situ to synoptic view. Journal of Geophysical Research: Oceans. 2022. https://doi.org/10.1029/2021JC018388
Thouvenin-Masson, C.; Boutin, J.; Vergely, J.-L.; Reverdin, G.; Martin, A.C.H.; Guimbard, S.; Reul, N.; Sabia, R.; Catany, R.; Hembise Fanton-d’Andon, O.. Satellite and In Situ Sampling Mismatches: Consequences for the Estimation of Satellite Sea Surface Salinity Uncertainties. Remote Sensing. 2022. https://doi.org/10.3390/rs14081878