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Dynamics of sea-surface temperature anomalies in the Southern Ocean diagnosed from a 2D mixed-layer model |
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| Authors: | Frédéric Vivier Daniele Iudicone Fabiano Busdraghi Young-Hyang Park |
| Institution: | 1. Laboratoire d’Océanographie et du Climat, Experimentation et Approches Numériques, Institut Pierre-Simon Laplace (LOCEAN-IPSL), Centre National de la Recherche Scientifique (CNRS), Université Pierre et Marie Curie, 4 place Jussieu, 75005, Paris, France 2. Stazione Zoologica di Napoli (SZN), Naples, Italy 3. LOCEAN-IPSL, Paris, France 4. LOCEAN-IPSL, Muséum National d’Histoire Naturelle, Paris, France |
| Abstract: | We analyze the processes responsible for the generation and evolution of sea-surface temperature anomalies observed in the Southern Ocean during a decade based on a 2D diagnostic mixed-layer model in which geostrophic advection is prescribed from altimetry. Anomalous air–sea heat flux is the dominant term of the heat budget over most of the domain, while anomalous Ekman heat fluxes account for 20–40% of the variance in the latitude band 40°?60°S. In the ACC pathway, lateral fluxes of heat associated with anomalous geostrophic currents are a major contributor, dominating downstream of several topographic features, reflecting the influence of eddies and frontal migrations. A significant fraction of the variability of large-scale SST anomalies is correlated with either ENSO or the SAM, each mode contributing roughly equally. The relation between the heat budget terms and these climate modes is investigated, showing in particular that anomalous Ekman and air–sea heat fluxes have a co-operating effect (with regional exceptions), hence the large SST response associated with each mode. It is further shown that ENSO- or SAM-locked anomalous geostrophic currents generate substantial heat fluxes in all three basins with magnitude comparable with that of atmospheric forcings for ENSO, and smaller for the SAM except for limited areas. ENSO-locked forcings generate SST anomalies along the ACC pathway, and advection by mean flows is found to be a non-negligible contribution to the heat budget, exhibiting a wavenumber two zonal structure, characteristic of the Antarctic Circumpolar Wave. By contrast SAM-related forcings are predominantly zonally uniform along the ACC, hence smaller zonal SST gradients and a lesser role of mean advection, except in the SouthWest Atlantic. While modeled SST anomalies are significantly correlated with observations over most of the Southern Ocean, the analysis of the data-model discrepancies suggests that vertical ocean physics may play a significant role in the nonseasonal heat budget, especially in some key regions for mode water formation. |
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