The sensitivity of Southeast Pacific heat distribution to local and remote changes in ocean properties
The sensitivity of Southeast Pacific heat distribution to local and remote changes in ocean properties
The Southern Ocean features regionally varying ventilation pathways that transport heat and carbon from the surface ocean to the interior thermocline on timescales of decades to centuries, but the factors that control the distribution of heat along these pathways are not well understood. In this study, we use a global ocean state estimate (ECCOv4) to (1) define the recently ventilated interior Pacific (RVP) using numerical passive tracer experiments over a 10‐year period and (2) use an adjoint approach to calculate the sensitivities of the RVP heat content (RVPh) to changes in net heat flux and wind stress. We find that RVPh is most sensitive to local heat flux and wind stress anomalies north of the sea surface height contours that delineate the Antarctic Circumpolar Current, with especially high sensitivities over the South Pacific Gyre. Surprisingly, RVPh is not especially sensitive to changes at higher latitudes. We perform a set of step response experiments over the South Pacific Gyre, the subduction region, and the high‐latitude Southern Ocean. In consistency with the adjoint sensitivity fields, RVPh is most sensitive to wind stress curl over the subtropical gyre, which alter isopycnal heave, and it is only weakly sensitive to changes at higher latitudes. Our results suggest that despite the localized nature of mode water subduction hot spots, changes in basin‐scale pressure gradients are an important controlling factor on RVPh. Because basin‐scale wind stress is expected to change in the coming decades to centuries, our results may have implications for climate, via the atmosphere/ocean partitioning of heat.
773-790
Jones, Daniel C.
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Boland, Emma
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Meijers, Andrew J.s.
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Forget, Gael
37d75db7-5e43-41d9-8ef6-459c3c784526
Josey, Simon
2252ab7f-5cd2-49fd-a951-aece44553d93
Sallee, Jean-Baptiste
03e71997-fff9-4769-a3c7-a72f2e8d5a1c
Shuckburgh, Emily
2c719aeb-3e35-46bc-8430-378ab7396eeb
March 2020
Jones, Daniel C.
44fc07b3-5fb7-4bf5-9cec-78c78022613a
Boland, Emma
40c79826-4254-421c-9d7f-9db6d88fad1f
Meijers, Andrew J.s.
747ecd45-cdbe-47be-b952-4b724096f9d5
Forget, Gael
37d75db7-5e43-41d9-8ef6-459c3c784526
Josey, Simon
2252ab7f-5cd2-49fd-a951-aece44553d93
Sallee, Jean-Baptiste
03e71997-fff9-4769-a3c7-a72f2e8d5a1c
Shuckburgh, Emily
2c719aeb-3e35-46bc-8430-378ab7396eeb
Jones, Daniel C., Boland, Emma, Meijers, Andrew J.s., Forget, Gael, Josey, Simon, Sallee, Jean-Baptiste and Shuckburgh, Emily
(2020)
The sensitivity of Southeast Pacific heat distribution to local and remote changes in ocean properties.
Journal of Physical Oceanography, 50 (3), .
(doi:10.1175/JPO-D-19-0155.1).
Abstract
The Southern Ocean features regionally varying ventilation pathways that transport heat and carbon from the surface ocean to the interior thermocline on timescales of decades to centuries, but the factors that control the distribution of heat along these pathways are not well understood. In this study, we use a global ocean state estimate (ECCOv4) to (1) define the recently ventilated interior Pacific (RVP) using numerical passive tracer experiments over a 10‐year period and (2) use an adjoint approach to calculate the sensitivities of the RVP heat content (RVPh) to changes in net heat flux and wind stress. We find that RVPh is most sensitive to local heat flux and wind stress anomalies north of the sea surface height contours that delineate the Antarctic Circumpolar Current, with especially high sensitivities over the South Pacific Gyre. Surprisingly, RVPh is not especially sensitive to changes at higher latitudes. We perform a set of step response experiments over the South Pacific Gyre, the subduction region, and the high‐latitude Southern Ocean. In consistency with the adjoint sensitivity fields, RVPh is most sensitive to wind stress curl over the subtropical gyre, which alter isopycnal heave, and it is only weakly sensitive to changes at higher latitudes. Our results suggest that despite the localized nature of mode water subduction hot spots, changes in basin‐scale pressure gradients are an important controlling factor on RVPh. Because basin‐scale wind stress is expected to change in the coming decades to centuries, our results may have implications for climate, via the atmosphere/ocean partitioning of heat.
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jpo-d-19-0155.1
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e-pub ahead of print date: 28 January 2020
Published date: March 2020
Identifiers
Local EPrints ID: 437958
URI: http://eprints.soton.ac.uk/id/eprint/437958
ISSN: 0022-3670
PURE UUID: b4e3f28f-92dd-4f9f-a95f-afbfbacaf3d2
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Date deposited: 24 Feb 2020 17:31
Last modified: 16 Mar 2024 06:33
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Contributors
Author:
Daniel C. Jones
Author:
Emma Boland
Author:
Andrew J.s. Meijers
Author:
Gael Forget
Author:
Simon Josey
Author:
Jean-Baptiste Sallee
Author:
Emily Shuckburgh
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