Mass, nutrient and oxygen budgets for the northeastern Atlantic Ocean

Type Article
Date 2012
Language English
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Author(s) Maze GuillaumeORCID, Mercier HerleORCID, Thierry VirginieORCID, Memery Laurent, Morin P., Perez F.F.
Affiliation(s) IFREMER, Lab Phys Oceans, UMR6523,CNRS,IRD, Plouzane, France.
CNRS, Lab Sci Environm Marin, UMR6539,IRD, Plouzane, France.
UBO, CNRS, Chim Marine UMR7144, AD2M, F-29682 Roscoff, France.
Universite Pierre et Marie Curie Paris VI, Place Georges Teissier, 29682 Roscoff, France
CSIC, Inst Invest Marinas, Vigo, Spain.
Source Biogeosciences (1726-4170) (Copernicus Gesellschaft Mbh), 2012 , Vol. 9 , N. 10 , P. 4099-4113
DOI 10.5194/bg-9-4099-2012
WOS© Times Cited 12
Abstract The northeast Atlantic is a key horizontal and vertical crossroads region for the meridional overturning circulation, but basic nutrient and oxygen fluxes are still poorly constrained by observations in the region. A surface to bottom northeast Atlantic Ocean budget for mass, nutrients (nitrate and phosphate) and oxygen is determined using an optimization method based on three surveys of the OVIDE transect (from Greenland to Portugal) completed with the World Ocean Atlas 2009. Budgets are derived for two communicating boxes representing the northeastern European basin (NEEB) and the Irminger Sea.

For the NEEB (Irminger) box, it is found that 30% of the mass import (export) across the OVIDE section reach (originate from) the Nordic Seas, while 70% are redistributed between both boxes through the Reykjanes Ridge (9.3 ± 0.7 × 109 kg s−1).

Net biological source/sink terms of nitrate point to both the Irminger and NEEB boxes as net organic matter production sites (consuming nitrate at a rate of –7.8 ± 6.5 kmol s−1 and –8.4 ± 6.6 kmol s−1, respectively). Using a standard Redfield ratio of C : N = 106 : 16, nitrate consumption rates indicate that about 40 TgC yr−1 of carbon is fixed by organic matter production between the OVIDE transect and the Greenland–Scotland Ridge. Nutrient fluxes also induce a net biological production of oxygen of 73 ± 60 kmol s−1 and 79 ± 62 kmol s−1 in the Irminger and NEEB boxes, which points to the region as being autotrophic.

The abiotic air–sea oxygen flux leads to an oceanic oxygen uptake in the two regions (264 ± 66 kmol s−1 in the north and 443 ± 70 kmol s−1 in the south). The abiotic flux is partitioned into a mixing and a thermal component. It is found that the Irminger Sea oceanic oxygen uptake is driven by an air–sea heat flux cooling increasing the ocean surface oxygen solubility. Over the northeastern European basin the mixing component is about half the thermal flux, presumably because of the oxygen minimum in the subtropical thermocline.
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