The effect of Oceanic South Atlantic Convergence Zone episodes on regional SST anomalies: the roles of heat fluxes and upper-ocean dynamics

The South Atlantic Convergence Zone (SACZ) is an atmospheric system occurring in austral summer on the South America continent and sometimes extending over the adjacent South Atlantic. It is characterized by a persistent and very large, northwest-southeast-oriented, cloud band. Its presence over the...

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Published in:Climate dynamics 2022-10, Vol.59 (7-8), p.2041-2065
Main Authors: Pezzi, Luciano P., Quadro, Mario F. L., Lorenzzetti, João A., Miller, Arthur J., Rosa, Eliana B., Lima, Leonardo N., Sutil, Ueslei A.
Format: Article
Language:English
Subjects:
Advection
Anomalies
Atmospheric boundary layer
Atmospheric circulation
Atmospheric effects
Boundary layers
Climatology
Cloud bands
Cloud cover
Clouds
Convective activity
Convergence
Convergence zones
Cooling
Cyclonic vortexes
Dynamics
Earth and Environmental Science
Earth Sciences
Ekman transport
Environmental aspects
Fish
Fish larvae
Geophysics/Geodesy
Heat
Heat flux
Heat transfer
Heat transport
Larvae
Marine atmospheric boundary layer
Mixed layer
Ocean circulation
Ocean dynamics
Ocean mixed layer
Ocean surface
Ocean temperature
Ocean-atmosphere interaction
Oceanography
Oceans
Offshore
Planetary boundary layer
Pollutants
Radiation
Sea surface
Sea surface cooling
Sea surface temperature
Sea surface temperature anomalies
Short wave radiation
South Atlantic Convergence Zone (SACZ)
Surface circulation
Surface cooling
Surface temperature
Surface wind
Thermodynamics
Upwelling
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description The South Atlantic Convergence Zone (SACZ) is an atmospheric system occurring in austral summer on the South America continent and sometimes extending over the adjacent South Atlantic. It is characterized by a persistent and very large, northwest-southeast-oriented, cloud band. Its presence over the ocean causes sea surface cooling that some past studies indicated as being produced by a decrease of incoming solar heat flux induced by the extensive cloud cover. Here we investigate ocean–atmosphere interaction processes in the Southwestern Atlantic Ocean (SWA) during SACZ oceanic episodes, as well as the resulting modulations occurring in the oceanic mixed layer and their possible feedbacks on the marine atmospheric boundary layer. Our main interests and novel results are on verifying how the oceanic SACZ acts on dynamic and thermodynamic mechanisms and contributes to the sea surface thermal balance in that region. In our oceanic SACZ episodes simulations we confirm an ocean surface cooling. Model results indicate that surface atmospheric circulation and the presence of an extensive cloud cover band over the SWA promote sea surface cooling via a combined effect of dynamic and thermodynamic mechanisms, which are of the same order of magnitude. The sea surface temperature (SST) decreases in regions underneath oceanic SACZ positions, near Southeast Brazilian coast, in the South Brazil Bight (SBB) and offshore. This cooling is the result of a complex combination of factors caused by the decrease of solar shortwave radiation reaching the sea surface and the reduction of horizontal heat advection in the Brazil Current (BC) region. The weakened southward BC and adjacent offshore region heat advection seems to be associated with the surface atmospheric circulation caused by oceanic SACZ episodes, which rotate the surface wind and strengthen cyclonic oceanic mesoscale eddy. Another singular feature found in this study is the presence of an atmospheric cyclonic vortex Southwest of the SACZ (CVSS), both at the surface and aloft at 850 hPa near 24°S and 45°W. The CVSS induces an SST decrease southwestward from the SACZ position by inducing divergent Ekman transport and consequent offshore upwelling. This shows that the dynamical effects of atmospheric surface circulation associated with the oceanic SACZ are not restricted only to the region underneath the cloud band, but that they extend southwestward where the CVSS presence supports the oceanic SACZ convective activity
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Here we investigate ocean–atmosphere interaction processes in the Southwestern Atlantic Ocean (SWA) during SACZ oceanic episodes, as well as the resulting modulations occurring in the oceanic mixed layer and their possible feedbacks on the marine atmospheric boundary layer. Our main interests and novel results are on verifying how the oceanic SACZ acts on dynamic and thermodynamic mechanisms and contributes to the sea surface thermal balance in that region. In our oceanic SACZ episodes simulations we confirm an ocean surface cooling. Model results indicate that surface atmospheric circulation and the presence of an extensive cloud cover band over the SWA promote sea surface cooling via a combined effect of dynamic and thermodynamic mechanisms, which are of the same order of magnitude. The sea surface temperature (SST) decreases in regions underneath oceanic SACZ positions, near Southeast Brazilian coast, in the South Brazil Bight (SBB) and offshore. 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Its presence over the ocean causes sea surface cooling that some past studies indicated as being produced by a decrease of incoming solar heat flux induced by the extensive cloud cover. Here we investigate ocean–atmosphere interaction processes in the Southwestern Atlantic Ocean (SWA) during SACZ oceanic episodes, as well as the resulting modulations occurring in the oceanic mixed layer and their possible feedbacks on the marine atmospheric boundary layer. Our main interests and novel results are on verifying how the oceanic SACZ acts on dynamic and thermodynamic mechanisms and contributes to the sea surface thermal balance in that region. In our oceanic SACZ episodes simulations we confirm an ocean surface cooling. Model results indicate that surface atmospheric circulation and the presence of an extensive cloud cover band over the SWA promote sea surface cooling via a combined effect of dynamic and thermodynamic mechanisms, which are of the same order of magnitude. The sea surface temperature (SST) decreases in regions underneath oceanic SACZ positions, near Southeast Brazilian coast, in the South Brazil Bight (SBB) and offshore. This cooling is the result of a complex combination of factors caused by the decrease of solar shortwave radiation reaching the sea surface and the reduction of horizontal heat advection in the Brazil Current (BC) region. The weakened southward BC and adjacent offshore region heat advection seems to be associated with the surface atmospheric circulation caused by oceanic SACZ episodes, which rotate the surface wind and strengthen cyclonic oceanic mesoscale eddy. Another singular feature found in this study is the presence of an atmospheric cyclonic vortex Southwest of the SACZ (CVSS), both at the surface and aloft at 850 hPa near 24°S and 45°W. The CVSS induces an SST decrease southwestward from the SACZ position by inducing divergent Ekman transport and consequent offshore upwelling. This shows that the dynamical effects of atmospheric surface circulation associated with the oceanic SACZ are not restricted only to the region underneath the cloud band, but that they extend southwestward where the CVSS presence supports the oceanic SACZ convective activity and concomitantly modifies the ocean dynamics. Therefore, the changes produced in the oceanic dynamics by these SACZ events may be important to many areas of scientific and applied climate research. For example, episodes of oceanic SACZ may influence the pathways of pollutants as well as fish larvae dispersion in the region.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><doi>10.1007/s00382-022-06195-3</doi><tpages>25</tpages><orcidid>https://orcid.org/0000-0001-6016-4320</orcidid><oa>free_for_read</oa></addata></record>
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ispartof Climate dynamics, 2022-10, Vol.59 (7-8), p.2041-2065
issn 0930-7575
1432-0894
language eng
recordid cdi_proquest_journals_2712093138
source Springer Link
subjects Advection
Anomalies
Atmospheric boundary layer
Atmospheric circulation
Atmospheric effects
Boundary layers
Climatology
Cloud bands
Cloud cover
Clouds
Convective activity
Convergence
Convergence zones
Cooling
Cyclonic vortexes
Dynamics
Earth and Environmental Science
Earth Sciences
Ekman transport
Environmental aspects
Fish
Fish larvae
Geophysics/Geodesy
Heat
Heat flux
Heat transfer
Heat transport
Larvae
Marine atmospheric boundary layer
Mixed layer
Ocean circulation
Ocean dynamics
Ocean mixed layer
Ocean surface
Ocean temperature
Ocean-atmosphere interaction
Oceanography
Oceans
Offshore
Planetary boundary layer
Pollutants
Radiation
Sea surface
Sea surface cooling
Sea surface temperature
Sea surface temperature anomalies
Short wave radiation
South Atlantic Convergence Zone (SACZ)
Surface circulation
Surface cooling
Surface temperature
Surface wind
Thermodynamics
Upwelling
title The effect of Oceanic South Atlantic Convergence Zone episodes on regional SST anomalies: the roles of heat fluxes and upper-ocean dynamics
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