Publications des scientifiques de l'IRD

Boutin J., Chao Y., Asher W. E., Delcroix Thierry, Drucker R., Drushka K., Kolodziejczyk N., Lee T., Reul N., Reverdin G., Schanze J., Soloviev A., Yu L., Anderson J., Brucker L., Dinnat E., Santos-Garcia A., Jones W. L., Maes Christophe, Meissner T., Tang W., Vinogradova N., Ward B. (2016). Satellite and in situ salinity : understanding near-surface stratification and subfootprint variability. Bulletin of the American Meteorological Society, 97 (8), p. 1391-1407. ISSN 0003-0007.

Titre du document
Satellite and in situ salinity : understanding near-surface stratification and subfootprint variability
Année de publication
2016
Type de document
Article référencé dans le Web of Science WOS:000382430700011
Auteurs
Boutin J., Chao Y., Asher W. E., Delcroix Thierry, Drucker R., Drushka K., Kolodziejczyk N., Lee T., Reul N., Reverdin G., Schanze J., Soloviev A., Yu L., Anderson J., Brucker L., Dinnat E., Santos-Garcia A., Jones W. L., Maes Christophe, Meissner T., Tang W., Vinogradova N., Ward B.
Source
Bulletin of the American Meteorological Society, 2016, 97 (8), p. 1391-1407 ISSN 0003-0007
Remote sensing of salinity using satellite-mounted microwave radiometers provides new perspectives for studying ocean dynamics and the global hydrological cycle. Calibration and validation of these measurements is challenging because satellite and in situ methods measure salinity differently. Microwave radiometers measure the salinity in the top few centimeters of the ocean, whereas most in situ observations are reported below a depth of a few meters. Additionally, satellites measure salinity as a spatial average over an area of about 100 x 100 km(2). In contrast, in situ sensors provide pointwise measurements at the location of the sensor. Thus, the presence of vertical gradients in, and horizontal variability of, sea surface salinity complicates comparison of satellite and in situ measurements. This paper synthesizes present knowledge of the magnitude and the processes that contribute to the formation and evolution of vertical and horizontal variability in near surface salinity. Rainfall, freshwater plumes, and evaporation can generate vertical gradients of salinity, and in some cases these gradients can be large enough to affect validation of satellite measurements. Similarly, mesoscale to submesoscale processes can lead to horizontal variability that can also affect comparisons of satellite data to in situ data. Comparisons between satellite and in situ salinity measurements must take into account both vertical stratification and horizontal variability.
Plan de classement
Limnologie physique / Océanographie physique [032] ; Télédétection [126]
Localisation
Fonds IRD [F B010068111]
Identifiant IRD
fdi:010068111
Contact