Estimation of Return Levels for Extreme Skew Surge Coastal Flooding Events in the Delaware and Chesapeake Bays for 1980–2019

Callahan, John A.; Leathers, Daniel J.

doi:10.3389/fclim.2021.684834

Cited by 4 publications

(2 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Most of the studies undertaken so far have used hourly time series from tide gauges (see e.g. Calafat et al 2009;Tsimplis and Shaw 2010;Callahan and Leathers 2021), mainly because few long records with a higher frequency sampling were available. However, the situation has changed in the recent years, and nowadays it is possible to find tide gauge datasets covering several years with a 1-min resolution (e.g.…”

Section: Introductionmentioning

confidence: 99%

Quantifying the Contributors to Extreme Sea Level Events in the Western Mediterranean at High Spatio-temporal Resolution

Ramos-Alcántara,

Agulles,

Gomis

et al. 2024

Preprint

View full text Add to dashboard Cite

A comprehensive characterisation of extreme sea levels at different spatio-temporal scales is presented for the Western Mediterranean. The classical view of extreme sea levels as a consequence of the concurrence of storm events and high tides may lead to an incomplete picture for the Mediterranean coasts, where the tidal regime is small and processes operating at high frequencies can contribute significantly to extreme levels. Our approach bases on the analysis of tide gauge records with a high sampling frequency (1 minute), in order to consider other contributors beyond storm surges and tides. To have a basin-scale view, we first analyse the tide gauges operated by Puertos del Estado, which are distributed over all the Spanish Mediterranean coasts and cover at least from 2010 to 2022. Next, we focus on a more reduced domain to take advantage of the unprecedented spatio-temporal resolution of the VENOM tide gauge network, operating since 2020 in the Balearic archipelago. Last, we analyse the role of waves in local extreme sea level events by propagating waves towards the coast in the Bay of Palma. The wave run-up estimates are calculated considering the type of coastal protection and are used to simulate the potential flooding that could occur in the future under an unfavourable climate change scenario. Our results highlight the importance of high-frequency sea level records to study extreme events, and the key role of processes such as meteotsunamis and waves in the occurrence of extreme sea levels.

show abstract

Section: Introductionmentioning

confidence: 99%

Quantifying the Contributors to Extreme Sea Level Events in the Western Mediterranean at High Spatio-temporal Resolution

Ramos-Alcántara,

Agulles,

Gomis

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…This is a matter of concern for the U.S. mid-Atlantic region that covers two of the largest estuaries in the U.S.: the Delaware and Chesapeake Bays. These estuarine regions house ∼ 27 million inhabitants, a large density of metropolitan areas, natural ecosystems (e.g., salt marshes and freshwater wetlands), transportation networks, and industrial ports (Callahan and Leathers, 2021). The hurricane landfall trend in this area certainly raises interest in the associated storm surge hazard that might help develop flood risk assessment tools for federal, state, and local agencies.…”

Section: Introductionmentioning

confidence: 99%

Estuarine hurricane wind can intensify surge-dominated extreme water level in shallow and converging coastal systems

Deb,

Benedict,

Sun

et al. 2023

Preprint

View full text Add to dashboard Cite

Abstract. Based on the projected increase in hurricane landfall frequency on the middle to lower U.S. East Coast, we examined the crucial role of the estuarine wind field in exacerbating coastal flooding. A regionally refined atmospheric and two high-resolution hydrology and ocean models are integrated to provide plausible and physically-consistent ensembles of hurricane events and the associated flooding inside the Delaware Bay and River, a U.S. mid-Atlantic estuary. Model results show that the hurricane propagation direction, estuarine geometry, remote surge from the open ocean, and direct nearshore upwind stress could magnify the flood magnitude. More specifically, inland-bound tracks that make landfall before reaching the mid-Atlantic coast produce a more significant surge within Delaware Bay than the shore-parallel tracks, where the estuarine wind direction plays the primary role in surge amplification. Ultimately, this study emphasized the need for integrated models to capture the nonlinear dynamics and interactions in flood hazard modeling.

show abstract

Comparison of Extreme Coastal Flooding Events Between Tropical and Mid-Latitude Weather Systems in the Delaware and Chesapeake Bays for 1980 – 2019

2022

Journal of Applied Meteorology and Climatology

View full text Add to dashboard Cite

Coastal flooding is one of the most costly and deadly natural hazards facing the US Mid-Atlantic region today. Impacts in this heavily populated and economically significant region are caused by a combination of the location’s exposure and natural forcing from storms and sea-level rise. Tropical cyclones (TCs) and mid-latitude (ML) weather systems each have caused extreme coastal flooding in the region. Skew surge was computed over each tidal cycle for the past 40 years (1980 – 2019) at several tide gauges in the Delaware and Chesapeake Bays to compare the meteorological component of surge for each weather type. Although TCs cause higher mean surges, ML weather systems can produce surges just as severe and occur much more frequently, peaking in the cold season (November – March). Of the top 10 largest surge events, TCs account for 30-45% in the Delaware and upper Chesapeake Bays and 40–45% in the lower Chesapeake Bay. This percentage drops to 10-15% for larger numbers of events in all regions. Mean sea-level pressure and 500 hPa geopotential height (GPH) fields of the top 10 surge events from ML weather systems show a low-pressure center west-southwest of Delmarva and a semi-stationary high-pressure center to the northeast prior to maximum surge, producing strong easterly winds. Low-pressure centers intensify under upper-level divergence as they travel eastward, and the high-pressure centers are near the GPH ridges. During lower bay events, the low-pressure centers develop further south, intensifying over warmer coastal waters, with a south-shifted GPH pattern compared to upper bay events.

show abstract

Estimation of Return Levels for Extreme Skew Surge Coastal Flooding Events in the Delaware and Chesapeake Bays for 1980–2019

Cited by 4 publications

References 60 publications

Quantifying the Contributors to Extreme Sea Level Events in the Western Mediterranean at High Spatio-temporal Resolution

Quantifying the Contributors to Extreme Sea Level Events in the Western Mediterranean at High Spatio-temporal Resolution

Estuarine hurricane wind can intensify surge-dominated extreme water level in shallow and converging coastal systems

Comparison of Extreme Coastal Flooding Events Between Tropical and Mid-Latitude Weather Systems in the Delaware and Chesapeake Bays for 1980 – 2019

Contact Info

Product

Resources

About