Characteristics of Storm Surge Events Along the North‐East Atlantic Coasts

Storm surges are often characterized in terms of magnitude, duration and frequency. Here, we propose a novel statistical method to help characterize the full dynamics of storm surge events. The method, called ECHAR, is based on techniques already successfully applied in astrophysics. Analysis of 20...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2023-04, Vol.128 (4), p.n/a
Main Authors: Pineau‐Guillou, Lucia, Delouis, Jean‐Marc, Chapron, Bertrand
Format: Article
Language:English
Subjects:
Amplitude
Amplitudes
Astrophysics
Atmospheric pressure
Coastal storms
Components
Gauges
Geophysics
Hurricanes
Sciences of the Universe
Sea level
Statistical methods
Storm surges
Storms
Strong winds
Tidal waves
Tide gauges
Tropical depressions
Tropical storms
Water levels
Wind stress
Winds
Winter
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Summary:Storm surges are often characterized in terms of magnitude, duration and frequency. Here, we propose a novel statistical method to help characterize the full dynamics of storm surge events. The method, called ECHAR, is based on techniques already successfully applied in astrophysics. Analysis of 20 tide gauges in the North‐East Atlantic consistently reveals that storm surge events display two distinctive components, a slow‐time background Gaussian structure and a fast‐time Laplace structure. Each of these structures can be reduced to its duration and amplitude. For large events, occurring 5 times per winter, the slow‐time structure lasts around 16 days, varying from 9 days in the South to 45 days in the North (Baltic Sea), with almost the same amplitude at all the stations (around 0.17 m). The fast‐time structure lasts around 1.7 days at all the stations, but its amplitude greatly varies, from 0.1 m in the South to 1.6 m in the North Sea. The wind stress contributes mostly to the fast‐time component of the storm surge event, whereas the atmospheric pressure contributes to both components. The proposed ECHAR method, helping to characterize extreme events, can be applied anywhere else in the global ocean, for example, where tropical storm surges occur. Plain Language Summary Storm surges are an increase of the sea level, due to low atmospheric pressure and strong winds during storms. We propose a new method, to characterize storm surge events in the North‐East Atlantic. We consider the largest events, that happen only 5 times per winter. A typical storm surge event is a gradual slow increase and then decrease of the water level, over a period of few days to few weeks, from 9 days in the South to 45 days in the North (Baltic Sea). In addition, when the storm is at its peak, the water level suddenly rises, due to the passage of strong winds. This rise occurs on a very short period, only few hours, and can be locally very large (more than 1 m in the North Sea). Key Points A new method ECHAR is proposed to characterize the dynamics of typical storm surge events Storm surge events display a slow‐time and a fast‐time component lasting about 16 and 1.7 days respectively The wind stress mostly contributes to the fast‐time component whereas the atmospheric pressure contributes to both
ISSN:2169-9275
2169-9291
DOI:10.1029/2022JC019493