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Mean sea level variability in the North Sea: Processes and implications

Mean sea level variability in the North Sea: Processes and implications
Mean sea level variability in the North Sea: Processes and implications
Mean sea level (MSL) variations across a range of time scales are examined for the North Sea under the consideration of different forcing factors since the late 19th century. We use multiple linear regression models, which are validated for the second half of the 20th century against the output of a tide+surge model, to determine the barotropic response of the ocean to fluctuations in atmospheric forcing. We find that local atmospheric forcing mainly initiates MSL variability on time scales up to a few years, with the inverted barometric effect dominating the variability along the UK and Norwegian coastlines and wind controlling the MSL variability in the south from Belgium up to Denmark. On decadal time scales, MSL variability mainly reflects steric changes, which are largely forced remotely. A spatial correlation analysis of altimetry observations and gridded steric heights suggests evidence for a coherent signal extending from the Norwegian shelf down to the Canary Islands. This fits with the theory of longshore wind forcing along the eastern boundary of the North Atlantic causing coastally trapped waves to propagate over thousands of kilometers along the continental slope. Implications of these findings are assessed with statistical Monte-Carlo experiments. It is demonstrated that the removal of known variability increases the signal to noise ratio with the result that: (i) linear trends can be estimated more accurately; (ii) possible accelerations (as expected, e.g., due to anthropogenic climate change) can be detected much earlier. Such information is of crucial importance for anticipatory coastal management, engineering, and planning.
regional mean sea level, North Sea, tide gauge, atmospheric forcing
2169-9275
6821-6841
Dangendorf, Sönke
ba1c5cbe-a385-41dc-8a46-da8cd36cf19d
Calafat, Francisco M.
f97617bd-0238-48e6-b693-7d409ac30c47
Arns, Arne
2c3fd31d-325c-4e21-b02c-b530b9c26840
Wahl, Thomas
6506794a-1f35-4803-b7f7-98702e57e667
Haigh, Ivan D.
945ff20a-589c-47b7-b06f-61804367eb2d
Jensen, Jürgen
5188f969-c5e8-47e2-9e27-771067712095
Dangendorf, Sönke
ba1c5cbe-a385-41dc-8a46-da8cd36cf19d
Calafat, Francisco M.
f97617bd-0238-48e6-b693-7d409ac30c47
Arns, Arne
2c3fd31d-325c-4e21-b02c-b530b9c26840
Wahl, Thomas
6506794a-1f35-4803-b7f7-98702e57e667
Haigh, Ivan D.
945ff20a-589c-47b7-b06f-61804367eb2d
Jensen, Jürgen
5188f969-c5e8-47e2-9e27-771067712095

Dangendorf, Sönke, Calafat, Francisco M., Arns, Arne, Wahl, Thomas, Haigh, Ivan D. and Jensen, Jürgen (2014) Mean sea level variability in the North Sea: Processes and implications. Journal of Geophysical Research: Oceans, 119 (10), 6821-6841. (doi:10.1002/2014JC009901).

Record type: Article

Abstract

Mean sea level (MSL) variations across a range of time scales are examined for the North Sea under the consideration of different forcing factors since the late 19th century. We use multiple linear regression models, which are validated for the second half of the 20th century against the output of a tide+surge model, to determine the barotropic response of the ocean to fluctuations in atmospheric forcing. We find that local atmospheric forcing mainly initiates MSL variability on time scales up to a few years, with the inverted barometric effect dominating the variability along the UK and Norwegian coastlines and wind controlling the MSL variability in the south from Belgium up to Denmark. On decadal time scales, MSL variability mainly reflects steric changes, which are largely forced remotely. A spatial correlation analysis of altimetry observations and gridded steric heights suggests evidence for a coherent signal extending from the Norwegian shelf down to the Canary Islands. This fits with the theory of longshore wind forcing along the eastern boundary of the North Atlantic causing coastally trapped waves to propagate over thousands of kilometers along the continental slope. Implications of these findings are assessed with statistical Monte-Carlo experiments. It is demonstrated that the removal of known variability increases the signal to noise ratio with the result that: (i) linear trends can be estimated more accurately; (ii) possible accelerations (as expected, e.g., due to anthropogenic climate change) can be detected much earlier. Such information is of crucial importance for anticipatory coastal management, engineering, and planning.

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e-pub ahead of print date: October 2014
Published date: October 2014
Keywords: regional mean sea level, North Sea, tide gauge, atmospheric forcing
Organisations: Physical Oceanography, Energy & Climate Change Group

Identifiers

Local EPrints ID: 370133
URI: http://eprints.soton.ac.uk/id/eprint/370133
ISSN: 2169-9275
PURE UUID: a19f037b-e92e-4db4-a54f-2f0a796f0473
ORCID for Ivan D. Haigh: ORCID iD orcid.org/0000-0002-9722-3061

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Date deposited: 16 Oct 2014 09:57
Last modified: 15 Mar 2024 03:26

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Contributors

Author: Sönke Dangendorf
Author: Francisco M. Calafat
Author: Arne Arns
Author: Thomas Wahl
Author: Ivan D. Haigh ORCID iD
Author: Jürgen Jensen

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