Carregant...
Fitxers
Tipus de document
TesiVersió
Versió publicadaData de publicació
Llicència de publicació
Si us plau utilitzeu sempre aquest identificador per citar o enllaçar aquest document: https://hdl.handle.net/2445/204661
Transformations and pathways of Southern Ocean waters into the South Atlantic Ocean
Títol de la revista
Autors
ISSN de la revista
Títol del volum
Resum
[eng] The returning limb of Atlantic Meridional Overturning Circulation (AMOC) is partly supplied by the cold-fresh waters that enter through the Drake Passage. Up to the isoneutral 28.0 kg m−3, the mean water inflow through the Drake Passage to the Scotia Sea is 140.8 ± 7.4 Sv and the outflow through the Northern Passages is 115.9 ± 8.3 Sv. Below this isoneutral reference and down to 2000 m, an additional 23.4 Sv enters through the Drake Passage. The mean barotropic contribution always represents over half the total transports, with substantial seasonal and moderate interannual variability in the water transports. The water mean-residence time is about 6 - 8 months.
Combining the Argo floats data with other observational measurements, we apply a climatological high-resolution inverse model over the Scotia Sea boundaries up to the 28.0 kg m-3 isoneutral. The ACC enters 136.7 ± 1.0 Sv through the Drake Passage and exits 137.9 ± 1.0 Sv through the northern boundary, with the difference responding to the South Scotia Ridge and Philip Passages contributions. Along its northward path, the ACC waters lose heat but gain equatorward freshwater transport. Within the Scotia Sea, the surface-modal and modal-intermediate waters experience production in all biogeochemical variables. Finally, regarding anthropogenic DIC, the Scotia Sea stores
0.123 Pg C yr-1.
Then, the ROD method compares actual drifters' displacements with numerical trajectory predictions; the observed-predicted differences in final positions respond to diffusive motions not captured by the numerical models. The ROD method is applied in the western South Atlantic Ocean leading to maximum diffusivities of 4630 - 4980 m2 s-1 in the upper 200 m of the water column, presenting an inverse relationship with depth. The diffusivities near the surface are fairly constant in latitude but the diffusion coefficients at 1000 m decrease considerably south of the Southern Boundary.
With the horizontal diffusion coefficients obtained previously, we use the Lagrangian technique to determine the fraction of the upper-ocean transport that remains in the ACC flow as it crosses the South Atlantic Ocean and the fraction that contributes to the South Atlantic subtropical gyre. The mean results reveal that 94.8 Sv remains in the ACC, whereas a total of 15.1 Sv contributes directly to the AMOC. This AMOC transport takes a median of 14.3 years to arrive to the Brazilian Current from the Drake Passage. Furthermore, 78.1% of the particles that recirculate in the subtropical gyre perform one recirculation. The results confirm that the water masses entering the subtropical gyre through its eastern edge warm up substantially and lose density, partly transformed to surface waters.
Furthermore, the contributions at the eastern edge of the South Atlantic subtropical gyre from the warm-water and the cold-water routes are compared. We perform numerical simulations of Lagrangian trajectories to identify the multiple direct and indirect pathways of intermediate waters. The total cold-route contribution represents between 17.9 and 18.9%, substantially higher than the 7.1 to 12.3% warm- route contribution. Several individual pathways form both routes, but the direct path is the preferential pathway followed by 83.6 to 87.2% of the water parcels. The direct cold route is the one that undergoes a greater transformation of its water masses, and it is confirmed that also feeds the Agulhas Current, contributing similarly to that coming from the Indonesian Throughflow.
Descripció
Matèries
Matèries (anglès)
Citació
Citació
OLIVÉ ABELLÓ, Anna. Transformations and pathways of Southern Ocean waters into the South Atlantic Ocean. [consulta: 3 de desembre de 2025]. [Disponible a: https://hdl.handle.net/2445/204661]