Abstract
Abstract. The Labrador Sea in the North Atlantic Ocean is one of the few regions globally where oxygen from the atmosphere can reach the deep ocean directly. This is the result of wintertime deep convection, which homogenizes the water column to a depth of up to 2000 m and brings deep water undersaturated in oxygen into contact with the atmosphere. In this study, we analyze how the intense oxygen uptake during Labrador Sea Water (LSW) formation affects the properties of the outflowing deep western boundary current, which ultimately feeds the upper part of the North Atlantic Deep Water layer in much of the Atlantic Ocean. Seasonal cycles of oxygen concentration, temperature, and salinity from a 2-year time series collected by sensors moored at 600 m nominal depth in the outflowing boundary current at 53∘ N show a cooling, freshening, and increase in oxygen content of the water flowing out of the basin between March and August. Analysis of Argo float data suggests that this is preceded by an increased input of LSW into the boundary current about 1 month earlier. This input is the result of newly ventilated LSW entering from the interior, as well as LSW formed directly within the boundary current. Together, these results imply that the southward export of newly formed LSW primarily occurs in the months following the onset of deep convection, from March to August, and that this direct LSW export route controls the seasonal oxygen increase in the outflow at 600 m depth. During the rest of the year, properties of the boundary current measured at 53∘ N resemble those of Irminger Water, which enters the basin with the boundary current from the Irminger Sea. The input of newly ventilated LSW increases the oxygen concentration from 298 µmol L−1 in January to a maximum of 306 µmol L−1 in April. As a result of this LSW input, an estimated (1.60 ± 0.42) × 1012 mol yr−1 of oxygen are added to the outflowing boundary current, mostly during spring and summer, equivalent to 50 % of the wintertime uptake from the atmosphere in the interior of the basin. The export of oxygen from the subpolar gyre associated with this direct southward pathway of LSW is estimated to supply 42 %–71 % of the oxygen consumed annually in the upper North Atlantic Deep Water layer in the Atlantic Ocean between the Equator and 50∘ N. Our results show that the formation of LSW is important for replenishing oxygen to the deep oceans, meaning that possible changes in its formation rate and ventilation due to climate change could have wide-reaching impacts on marine life.
Highlights
Much of the global supply of oxygen to the deep ocean is concentrated in a few key regions where near-surface water sinks to great depth and spreads away from its source region (Talley, 2008; Gebbie and Huybers, 2011; Khatiwala et al, 2012)
The results put forth in this study show the effect of Labrador Sea Water formation and export on the oxygen concentration of the outflowing deep western boundary current
Properties measured at the 53◦ N array at about 600 m nominal depth are similar to those of Irminger Water, which enters the basin from the Irminger Sea
Summary
Much of the global supply of oxygen to the deep ocean is concentrated in a few key regions where near-surface water sinks to great depth and spreads away from its source region (Talley, 2008; Gebbie and Huybers, 2011; Khatiwala et al, 2012). During the convection season, which typically lasts from January to April, deep water masses that are low in oxygen are continuously incorporated into the progressively deepening mixed layer, which leads to a decrease in near-surface oxygen. This results in severe air–sea gradients in oxygen concentration, which, together with extreme atmospheric conditions, drive intense uptake of oxygen during winter (Koelling et al, 2017; Wolf et al, 2018; Atamanchuk et al, 2020)
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