Preface to the Special Section: Dense Water Formations in the Northwestern Mediterranean: From the Physical Forcings to the Biogeochemical Consequences

Preface to the Special Section: Dense Water Formations in the Northwestern Mediterranean: From the Physical Forcings to the Biogeochemical Consequences

The northwestern Mediterranean Sea is one of the few sites of open‐sea deep convection and dense water formation. The area is characterized by intense air‐sea exchanges favored by the succession of strong northerly and northwesterly winds during autumn and winter that eventually induce deep convecti...

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Veröffentlicht in:Journal of geophysical research. Oceans 2018-10, Vol.123 (10), p.6983-6995
Hauptverfasser: Conan, Pascal, Testor, Pierre, Estournel, Claude, D'Ortenzio, Fabrizio, Pujo‐Pay, Mireille, Durrieu de Madron, Xavier
Format: Artikel
Sprache:eng
Schlagworte:
Aircraft components
Atmosphere
Atmospheric circulation
Atmospheric dynamics
Atmospheric models
Balloons
Biogeochemistry
Biological properties
Blooms
Convection
Deep water
Dense water
Drifters
Dynamics
Earth Sciences
Ecological succession
Eddies
Floats
Fluxes
Geophysics
Gliders
Interannual variability
Meteorological balloons
Mineral nutrients
Modelling
Mooring
Ocean circulation
Ocean currents
Oceanography
Oceans
Physics
Phytoplankton
Phytoplankton bloom
Plankton
Sciences of the Universe
Seasonal variability
Seasonal variation
Seasonal variations
Ships
Surface fluxes
Temperature (air-sea)
Water circulation
Water masses
Water spreading
Winds
Winter
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Zusammenfassung:The northwestern Mediterranean Sea is one of the few sites of open‐sea deep convection and dense water formation. The area is characterized by intense air‐sea exchanges favored by the succession of strong northerly and northwesterly winds during autumn and winter that eventually induce deep convection episodes and the formation of the Western Mediterranean Deep Water. This region exhibits a significant spring phytoplankton bloom, which appears to be largely influenced in intensity and diversity by the winter mixing. To understand and resolve the interplay between the atmosphere and ocean, and the impact of ocean circulation and mixing on biogeochemistry, we carried out an unprecedented observational effort during a large experiment between July 2012 and July 2013. A multiplatform approach—combining aircraft, balloons, ships, moorings, floats, and gliders ‐ aimed both at characterizing the dynamics of the atmosphere and at quantifying the physical, biogeochemical, and biological properties of the water masses. Beyond a better understanding of the wind dynamics, the interannual variability of the deep convection, and the seasonal variability of the nutrient distribution and plankton structure in the pelagic ecosystem, the experiment provided a reference data set that was used as a benchmark for advancing the modeling of the surface fluxes, convective processes, dense water formation rates, and physical‐biogeochemical coupling processes. It also represented an opportunity for complementary investigations such as evaluating model parameterizations or studying the role of submesoscale eddies in dense water spreading and biogeochemistry. Key Points The results of the Dewex operation quantify and accurately describe the dynamics of dense water formations and their effects at subscale and mesoscale Advances concern physics but also biogeochemical budgets, planktonic biodiversity, and trophic levels functioning The special issue also deals with the potential evolution of mechanisms and their impacts on biogeochemistry in the context of global change
ISSN:2169-9275
2169-9291
DOI:10.1029/2018JC014301