2018
DOI: 10.1038/s41467-018-04101-2
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The southern ocean meridional overturning in the sea-ice sector is driven by freshwater fluxes

Abstract: The oceans are traversed by a large-scale overturning circulation, essential for the climate system as it sets the rate at which the deep ocean interacts with the atmosphere. The main region where deep waters reach the surface is in the Southern Ocean, where they are transformed by interactions with the atmosphere and sea-ice. Here, we present an observation-based estimate of the rate of overturning sustained by surface buoyancy fluxes in the Southern Ocean sea-ice sector. In this region, the seasonal growth a… Show more

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Cited by 98 publications
(140 citation statements)
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“…Once in the surface layer, the upwelled UCDW is exposed to surface fluxes and can participate in the general wind-driven transport of water toward the Polar Front. This diapycnal upwelling occurs at a rate of about 2×10 −12 Sv/m 2 (assuming that the surface mixed layer deepens by 25 m over 150 days); this rate agrees well with an estimate of the transformation rate for the Ross Gyre region by Pellichero et al (2018).…”
Section: Discussionsupporting
confidence: 81%
“…Once in the surface layer, the upwelled UCDW is exposed to surface fluxes and can participate in the general wind-driven transport of water toward the Polar Front. This diapycnal upwelling occurs at a rate of about 2×10 −12 Sv/m 2 (assuming that the surface mixed layer deepens by 25 m over 150 days); this rate agrees well with an estimate of the transformation rate for the Ross Gyre region by Pellichero et al (2018).…”
Section: Discussionsupporting
confidence: 81%
“…WMT rates resulting from applying a globally constant freshwater flux of 5 times the difference between their imbalance 5 × 10 −9 m/s result is very small WMT rates (Figure 2a, Wijffels, 2001). We note that both OA and CORE freshwater fluxes have no or limited implementation of the effects of seasonal ice melt and refreezing on WMT, which may be significant for both products at higher densities ( n > 27 kg/m 3 ; Pellichero et al, 2018). In conclusion, to obtain physical realistic amount of WMT, an (almost) balanced air-sea flux product is required, which is why we continue this study using CORE.…”
Section: Choosing Air-sea Flux Product For Wmt Analysismentioning
confidence: 95%
“…The net buoyancy flux is dominated by the freshwater component. Data shown in panels (d)–(f) are taken from and described by Pellichero et al (). The bars over the top panels show the ASC classifications as in Figures and .…”
Section: Structure and Regional Variations Of The Ascmentioning
confidence: 99%
“…The influence of surface buoyancy fluxes on the structure of the ASF is less clear. Averaged over the Antarctic margins, freshwater fluxes have a larger impact on water transformation than heat fluxes (Abernathey et al, ; Pellichero et al, ; Figures 5d–5f). Dense water formed over the continental shelf, and eventually exported as AABW, is largely related to sea ice formation and the associated brine rejection in coastal polynyas (Tamura et al, ), located shoreward of the ASC (Figure e).…”
Section: Structure and Regional Variations Of The Ascmentioning
confidence: 99%