Investigating the predictability of North Atlantic sea surface height
Investigating the predictability of North Atlantic sea surface height
Interannual sea surface height (SSH) forecasts are subject to several sources of uncertainty. Methods relying on statistical forecasts have proven useful in assessing predictability and associated uncertainty due to both initial conditions and boundary conditions. In this study, the interannual predictability of SSH dynamics in the North Atlantic is investigated using the output from a 150 year long control simulation based on HadGEM3, a coupled climate model at eddy-permitting resolution. Linear inverse modeling (LIM) is used to create a statistical model for the evolution of monthly-mean SSH anomalies. The forecasts based on the LIM model demonstrate skill on interannanual timescales OO(1–2 years). Forecast skill is found to be largest in both the subtropical and subpolar gyres, with decreased skill in the Gulf Stream extension region. The SSH initial conditions involving a tripolar anomaly off Cape Hatteras lead to a maximum growth in SSH about 20 months later. At this time, there is a meridional shift in the 0 m-SSH contour on the order of 0.5∘0.5∘–1.5∘1.5∘-latitude, coupled with a change in SSH along the US East Coast. To complement the LIM-based study, interannual SSH predictability is also quantified using the system’s average predictability time (APT). The APT analysis extracted large-scale SSH patterns which displayed predictability on timescales longer than 2 years. These patterns are responsible for changes in SSH on the order of 10 cm along the US East Coast, driven by variations in Ekman velocity. Our results shed light on the timescales of SSH predictability in the North Atlantic. In addition, the diagnosed optimal initial conditions and predictable patterns could improve interannual forecasts of the Gulf Stream’s characteristics and coastal SSH.
2175-2195
Fraser, Robert
8bdf0213-8daf-4f30-add5-adc891ff96ac
Palmer, Matthew
2742e7b3-dc9a-4c4b-b373-42415e026a62
Roberts, Christopher
4f3eb6ea-2941-481b-a3fc-ac5ce444167d
Wilson, Chris
fadc83b7-f240-485b-8734-51099d02775a
Copsey, Dan
49a34d2a-90d0-4b25-b67b-2364b3120548
Zanna, Laure
a2ae4fab-2c45-4aa7-a53f-ea83f8d16cb2
11 June 2019
Fraser, Robert
8bdf0213-8daf-4f30-add5-adc891ff96ac
Palmer, Matthew
2742e7b3-dc9a-4c4b-b373-42415e026a62
Roberts, Christopher
4f3eb6ea-2941-481b-a3fc-ac5ce444167d
Wilson, Chris
fadc83b7-f240-485b-8734-51099d02775a
Copsey, Dan
49a34d2a-90d0-4b25-b67b-2364b3120548
Zanna, Laure
a2ae4fab-2c45-4aa7-a53f-ea83f8d16cb2
Fraser, Robert, Palmer, Matthew, Roberts, Christopher, Wilson, Chris, Copsey, Dan and Zanna, Laure
(2019)
Investigating the predictability of North Atlantic sea surface height.
Climate Dynamics, 53 (3-4), .
(doi:10.1007/s00382-019-04814-0).
Abstract
Interannual sea surface height (SSH) forecasts are subject to several sources of uncertainty. Methods relying on statistical forecasts have proven useful in assessing predictability and associated uncertainty due to both initial conditions and boundary conditions. In this study, the interannual predictability of SSH dynamics in the North Atlantic is investigated using the output from a 150 year long control simulation based on HadGEM3, a coupled climate model at eddy-permitting resolution. Linear inverse modeling (LIM) is used to create a statistical model for the evolution of monthly-mean SSH anomalies. The forecasts based on the LIM model demonstrate skill on interannanual timescales OO(1–2 years). Forecast skill is found to be largest in both the subtropical and subpolar gyres, with decreased skill in the Gulf Stream extension region. The SSH initial conditions involving a tripolar anomaly off Cape Hatteras lead to a maximum growth in SSH about 20 months later. At this time, there is a meridional shift in the 0 m-SSH contour on the order of 0.5∘0.5∘–1.5∘1.5∘-latitude, coupled with a change in SSH along the US East Coast. To complement the LIM-based study, interannual SSH predictability is also quantified using the system’s average predictability time (APT). The APT analysis extracted large-scale SSH patterns which displayed predictability on timescales longer than 2 years. These patterns are responsible for changes in SSH on the order of 10 cm along the US East Coast, driven by variations in Ekman velocity. Our results shed light on the timescales of SSH predictability in the North Atlantic. In addition, the diagnosed optimal initial conditions and predictable patterns could improve interannual forecasts of the Gulf Stream’s characteristics and coastal SSH.
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Fraser2019_Article_InvestigatingThePredictability
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Accepted/In Press date: 8 May 2019
Published date: 11 June 2019
Identifiers
Local EPrints ID: 435605
URI: http://eprints.soton.ac.uk/id/eprint/435605
ISSN: 0930-7575
PURE UUID: f218b16b-e6b7-47ee-9719-75cda102d292
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Date deposited: 14 Nov 2019 17:30
Last modified: 16 Mar 2024 05:16
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Author:
Robert Fraser
Author:
Matthew Palmer
Author:
Christopher Roberts
Author:
Chris Wilson
Author:
Dan Copsey
Author:
Laure Zanna
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