Locations and mechanisms of ocean ventilation in the high-latitude North Atlantic in an eddy-permitting ocean model

A substantial fraction of the deep ocean is ventilated in the high-latitude North Atlantic. Consequently, the region plays a crucial role in transient climate change through the uptake of carbon dioxide and heat. However, owing to the Lagrangian nature of the process, many aspects of deep Atlantic O...

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Bibliographic Details
Published in:Journal of Climate
Main Authors: Macgilchrist, Graeme A., Johnson, Helen L., Marshall, David P., Lique, Camille, Thomas, Matthew, Jackson, Laura C., Wood, Richard A.
Format: Article in Journal/Newspaper
Language:English
Published: American Meteorological Society 2020
Subjects:
North Atlantic Ocean
Atmosphere-ocean interaction
Lagrangian circulation/transport
Ocean circulation
Boundary currents
Diapycnal mixing
Greenland
Iceland
Labrador Sea
NADW
North Atlantic
Online Access:https://archimer.ifremer.fr/doc/00646/75833/76825.pdf
https://doi.org/10.1175/JCLI-D-20-0191.1
https://archimer.ifremer.fr/doc/00646/75833/
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Summary:A substantial fraction of the deep ocean is ventilated in the high-latitude North Atlantic. Consequently, the region plays a crucial role in transient climate change through the uptake of carbon dioxide and heat. However, owing to the Lagrangian nature of the process, many aspects of deep Atlantic Ocean ventilation and its representation in climate simulations remain obscure. We investigate the nature of ventilation in the high latitude North Atlantic in an eddy-permitting numerical ocean circulation model using a comprehensive set of Lagrangian trajectory experiments. Backwards-in-time trajectories from a model-defined ‘North Atlantic DeepWater’ (NADW) reveal the locations of subduction from the surface mixed layer at high spatial resolution. The major fraction of NADW ventilation results from subduction in the Labrador Sea, predominantly within the boundary current (̴ 60% of ventilated NADW volume) and a smaller fraction arising from open ocean deep convection (̴ 25%). Subsurface transformations — due in part to the model’s parameterization of bottom-intensified mixing—facilitate NADWventilation, such that water subducted in the boundary current ventilates all of NADW, not just the lighter density classes. There is a notable absence of ventilation arising from subduction in the Greenland-Iceland-Norwegian Seas, due to the re-entrainment of those waters as they move southward. Taken together, our results emphasize an important distinction between ventilation and dense water formation in terms of the location where each takes place, and their concurrent sensitivities. These features of NADW ventilation are explored to understand how the representation of high-latitude processes impacts properties of the deep ocean in a state-of-the-science numerical simulation.

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