The role of preconditioning for extreme storm surges in the western Baltic Sea

When natural hazards interact in compound events, they may reinforce each other. This is a concern today and in light of climate change. In the case of coastal flooding, sea-level variability due to tides, seasonal to inter-annual salinity and temperature variations, or larger–scale wind conditions...

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Bibliographic Details
Published in:Natural hazards and earth system sciences 2023-05, Vol.23 (5), p.1817-1834
Main Authors: Andrée, Elin, Su, Jian, Dahl Larsen, Morten Andreas, Drews, Martin, Stendel, Martin, Skovgaard Madsen, Kristine
Format: Article
Language:English
Subjects:
Analysis
Basin geometry
Boundary conditions
Climate adaptation
Climate change
Climate change adaptation
Climatic changes
Coastal flooding
Disaster management
Emergency preparedness
Extreme weather
Flooding
Floods
Hazard mitigation
Long waves
Numerical experiments
Ocean models
Preconditioning
Rain
Risk assessment
Risk management
Salinity
Sea level
Sea level variability
Seasonal variability
Simulation
Storm surges
Storms
Temperature variations
Tidal waves
Warning systems
Water level fluctuations
Water levels
Weather
Wind
Wind speed
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Summary:When natural hazards interact in compound events, they may reinforce each other. This is a concern today and in light of climate change. In the case of coastal flooding, sea-level variability due to tides, seasonal to inter-annual salinity and temperature variations, or larger–scale wind conditions modify the development and ramifications of extreme sea levels. Here, we explore how various prior conditions could have influenced peak water levels for the devastating coastal flooding event in the western Baltic Sea in 1872. We design numerical experiments by imposing a range of precondition circumstances as boundary conditions to numerical ocean model simulations. This allows us to quantify the changes in peak water levels that arise due to alternative preconditioning of the sea level before the storm surge. Our results show that certain preconditioning could have generated even more catastrophic impacts. As an example, a simulated increase in the water level of 36 cm compared to the 1872 event occurred in Køge just south of Copenhagen (Denmark) and surrounding areas – a region that was already severely impacted. The increased water levels caused by the alternative sea-level patterns propagate as long waves until encountering shallow and narrow straits, and after that, the effect vastly decreases. Adding artificial increases in wind speeds to each study point location reveals a near-linear relationship with peak water levels for all western Baltic locations, highlighting the need for good assessments of future wind extremes. Our research indicates that a more hybrid approach to analysing compound events and readjusting our present warning system to a more contextualised framework might provide a firmer foundation for climate adaptation and disaster risk management. In particular, accentuating the importance of compound preconditioning effects on the outcome of natural hazards may avoid under- or overestimation of the associated risks.
ISSN:1684-9981
1561-8633
1684-9981
DOI:10.5194/nhess-23-1817-2023