Theoretical investigation of the Atlantic Multidecadal Oscillation
Theoretical investigation of the Atlantic Multidecadal Oscillation
A weakly damped mode of variability, corresponding to the oceanic signature of the Atlantic Multidecadal Oscillation (AMO), was found through the linear stability analysis of a realistic ocean General Circulation Model. A simple 2-level model was proposed to rationalize both its period and damping rate. This model is extended here to 3-level to investigate how the mode can draw energy from the mean flow, as found in various ocean and coupled models. A linear stability analysis in this 3-level model shows that the positive growth rate of the oscillatory mode depends on the zonally-averaged isopycnal slope. This mode corresponds to a westward propagation of density anomalies in the pycnocline, typical of large-scale baroclinic Rossby waves. The most unstable mode corresponds to the largest scale one (at least for low isopycnal slope). The mode can be described in four phases composing a full oscillation cycle: (1) basin-scale warming of the North Atlantic (AMO positive phase), (2) decrease in upper ocean poleward transport (hence a reduction of the Atlantic Meridional Overturning Circulation, AMOC), (3) basin-scale cooling (negative AMO), (4) AMOC intensification. A criterion is developed to test, in oceanic datasets or numerical models, whether this multidecadal oscillation is an unstable oceanic internal mode of variability, or is stable and externally forced. Consistently with classical theory of baroclinic instability, this criterion depends on the vertical structure of the mode. If the upper pycnocline signature is in advance of the deeper pycnocline signature with respect to the westward propagation, the mode is unstable and could be described as an oceanic internal mode of variability.
Geographic location/entity, North Atlantic Ocean, Circulation/ Dynamics, Dynamics, Meridional overturning circulation, Atm/Ocean Structure/ Phenomena, Thermohaline circulation, Physical Meteorology and Climatology, Climate variability, Variability, Multidecadal variability
2189-2208
Sévellec, Florian
01569d6c-65b0-4270-af2a-35b0a77c9140
Huck, Thierry
3de8511b-db7b-4ed1-bc27-92d2bbc7c6b9
September 2015
Sévellec, Florian
01569d6c-65b0-4270-af2a-35b0a77c9140
Huck, Thierry
3de8511b-db7b-4ed1-bc27-92d2bbc7c6b9
Sévellec, Florian and Huck, Thierry
(2015)
Theoretical investigation of the Atlantic Multidecadal Oscillation.
Journal of Physical Oceanography, 45 (9), .
(doi:10.1175/JPO-D-14-0094.1).
Abstract
A weakly damped mode of variability, corresponding to the oceanic signature of the Atlantic Multidecadal Oscillation (AMO), was found through the linear stability analysis of a realistic ocean General Circulation Model. A simple 2-level model was proposed to rationalize both its period and damping rate. This model is extended here to 3-level to investigate how the mode can draw energy from the mean flow, as found in various ocean and coupled models. A linear stability analysis in this 3-level model shows that the positive growth rate of the oscillatory mode depends on the zonally-averaged isopycnal slope. This mode corresponds to a westward propagation of density anomalies in the pycnocline, typical of large-scale baroclinic Rossby waves. The most unstable mode corresponds to the largest scale one (at least for low isopycnal slope). The mode can be described in four phases composing a full oscillation cycle: (1) basin-scale warming of the North Atlantic (AMO positive phase), (2) decrease in upper ocean poleward transport (hence a reduction of the Atlantic Meridional Overturning Circulation, AMOC), (3) basin-scale cooling (negative AMO), (4) AMOC intensification. A criterion is developed to test, in oceanic datasets or numerical models, whether this multidecadal oscillation is an unstable oceanic internal mode of variability, or is stable and externally forced. Consistently with classical theory of baroclinic instability, this criterion depends on the vertical structure of the mode. If the upper pycnocline signature is in advance of the deeper pycnocline signature with respect to the westward propagation, the mode is unstable and could be described as an oceanic internal mode of variability.
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JPO-D-14-0094.1.pdf
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e-pub ahead of print date: July 2015
Published date: September 2015
Keywords:
Geographic location/entity, North Atlantic Ocean, Circulation/ Dynamics, Dynamics, Meridional overturning circulation, Atm/Ocean Structure/ Phenomena, Thermohaline circulation, Physical Meteorology and Climatology, Climate variability, Variability, Multidecadal variability
Organisations:
Physical Oceanography
Identifiers
Local EPrints ID: 378804
URI: http://eprints.soton.ac.uk/id/eprint/378804
ISSN: 0022-3670
PURE UUID: e8c3a9a0-3db5-4fc3-b8a7-49740f349764
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Date deposited: 07 Jul 2015 11:36
Last modified: 14 Mar 2024 20:29
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Author:
Thierry Huck
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