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Ocean impact on decadal Atlantic climate variability revealed by sea-level observations

Ocean impact on decadal Atlantic climate variability revealed by sea-level observations
Ocean impact on decadal Atlantic climate variability revealed by sea-level observations
Decadal variability is a notable feature of the Atlantic Ocean and the climate of the regions it influences. Prominently, this is manifested in the Atlantic Multidecadal Oscillation (AMO) in sea surface temperatures. Positive (negative) phases of the AMO coincide with warmer (colder) North Atlantic sea surface temperatures. The AMO is linked with decadal climate fluctuations, such as Indian and Sahel rainfall1, European summer precipitation2, Atlantic hurricanes3 and variations in global temperatures4. It is widely believed that ocean circulation drives the phase changes of the AMO by controlling ocean heat content5. However, there are no direct observations of ocean circulation of sufficient length to support this, leading to questions about whether the AMO is controlled from another source6. Here we provide observational evidence of the widely hypothesized link between ocean circulation and the AMO. We take a new approach, using sea level along the east coast of the United States to estimate ocean circulation on decadal timescales. We show that ocean circulation responds to the first mode of Atlantic atmospheric forcing, the North Atlantic Oscillation, through circulation changes between the subtropical and subpolar gyres—the intergyre region7. These circulation changes affect the decadal evolution of North Atlantic heat content and, consequently, the phases of the AMO. The Atlantic overturning circulation is declining8 and the AMO is moving to a negative phase. This may offer a brief respite from the persistent rise of global temperatures4, but in the coupled system we describe, there are compensating effects. In this case, the negative AMO is associated with a continued acceleration of sea-level rise along the northeast coast of the United States9, 10.
0028-0836
508-510
McCarthy, Gerard D.
99241bcb-5667-469d-b7ae-4d308d516bd6
Haigh, Ivan D.
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Hirschi, Joël J.-M.
c8a45006-a6e3-4319-b5f5-648e8ef98906
Grist, Jeremy P.
ffea99af-f811-436f-9bac-5b02ba6dc00f
Smeed, David A.
79eece5a-c870-47f9-bba0-0a4ef0369490
McCarthy, Gerard D.
99241bcb-5667-469d-b7ae-4d308d516bd6
Haigh, Ivan D.
945ff20a-589c-47b7-b06f-61804367eb2d
Hirschi, Joël J.-M.
c8a45006-a6e3-4319-b5f5-648e8ef98906
Grist, Jeremy P.
ffea99af-f811-436f-9bac-5b02ba6dc00f
Smeed, David A.
79eece5a-c870-47f9-bba0-0a4ef0369490

McCarthy, Gerard D., Haigh, Ivan D., Hirschi, Joël J.-M., Grist, Jeremy P. and Smeed, David A. (2015) Ocean impact on decadal Atlantic climate variability revealed by sea-level observations. Nature, 521 (7553), 508-510. (doi:10.1038/nature14491).

Record type: Article

Abstract

Decadal variability is a notable feature of the Atlantic Ocean and the climate of the regions it influences. Prominently, this is manifested in the Atlantic Multidecadal Oscillation (AMO) in sea surface temperatures. Positive (negative) phases of the AMO coincide with warmer (colder) North Atlantic sea surface temperatures. The AMO is linked with decadal climate fluctuations, such as Indian and Sahel rainfall1, European summer precipitation2, Atlantic hurricanes3 and variations in global temperatures4. It is widely believed that ocean circulation drives the phase changes of the AMO by controlling ocean heat content5. However, there are no direct observations of ocean circulation of sufficient length to support this, leading to questions about whether the AMO is controlled from another source6. Here we provide observational evidence of the widely hypothesized link between ocean circulation and the AMO. We take a new approach, using sea level along the east coast of the United States to estimate ocean circulation on decadal timescales. We show that ocean circulation responds to the first mode of Atlantic atmospheric forcing, the North Atlantic Oscillation, through circulation changes between the subtropical and subpolar gyres—the intergyre region7. These circulation changes affect the decadal evolution of North Atlantic heat content and, consequently, the phases of the AMO. The Atlantic overturning circulation is declining8 and the AMO is moving to a negative phase. This may offer a brief respite from the persistent rise of global temperatures4, but in the coupled system we describe, there are compensating effects. In this case, the negative AMO is associated with a continued acceleration of sea-level rise along the northeast coast of the United States9, 10.

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Accepted/In Press date: 8 April 2015
e-pub ahead of print date: 27 May 2015
Published date: 27 May 2015
Organisations: Marine Systems Modelling, Physical Oceanography, Marine Physics and Ocean Climate

Identifiers

Local EPrints ID: 377731
URI: http://eprints.soton.ac.uk/id/eprint/377731
ISSN: 0028-0836
PURE UUID: 1ff0647d-ffb0-4daf-b885-6c10e22eea54
ORCID for Ivan D. Haigh: ORCID iD orcid.org/0000-0002-9722-3061

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Date deposited: 03 Jun 2015 15:53
Last modified: 15 Mar 2024 03:26

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Contributors

Author: Gerard D. McCarthy
Author: Ivan D. Haigh ORCID iD
Author: Joël J.-M. Hirschi
Author: Jeremy P. Grist
Author: David A. Smeed

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