High human influence on beach response to tropical cyclones in small islands: Saint-Martin Island, Lesser Antilles

Duvat, Virginie; Pillet, Valentin; Volto, Natacha; Krien, Yann; Cécé, Raphaël; Bernard, Didier

doi:10.1016/j.geomorph.2018.09.029

Cited by 27 publications

(25 citation statements)

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“…The improved numerical model is in close agreement with previous results [30,57] regarding sea states. With significant wave heights reaching about 9-10m offshore, at 15-20m depth these values are in agreement with operational forecasts issued by Météo-France (Figure 5d), and suggest that significant wave heights are essentially limited by wave breaking on the east coast.…”

Section: Storm Surge Numerical Modeling and Geomorphological Observatsupporting

confidence: 89%

“…The WRF ARW atmospheric model [29] is used at 280-m resolution with 3D Large Eddy turbulence in order to examine Irma gust effects over Saint-Martin. A part of these results was published by [30]. This previous simulation setup was improved in the present study with (1) a higher resolution linked with an upgraded land-use map combining the 300 m ESA CCI landcover map and OpenStreetMap data, (2) the use of the 3D Large Eddy turbulence, which is more appropriate for turbulent wind gusts, and (3) a proper hurricane vortex initialization method.…”

Section: Hurricane Characteristicsmentioning

confidence: 99%

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Coastal Processes and Influence on Damage to Urban Structures during Hurricane Irma (St-Martin & St-Barthélemy, French West Indies)

Rey

Leone

Candela

et al. 2019

JMSE

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This study aims to better understand coastal processes associated with extreme cyclonic events through the study of the coastal changes, flooding and damage that resulted from the passage of a category 5 hurricane (Irma) on 6 September 2017 over the islands of Saint-Martin and Saint-Barthélemy in the Lesser Antilles. Hurricane Irma was contextualized from tropical cyclone track data and local weather observations collected by Météo-France, as well as high-resolution numerical modelling. Field work involved the study of accretion coasts through qualitative observations, topo-morphological and sedimentary surveys, as well as image acquisition with Unmanned Aerial Vehicle (UAV) surveys during two trips that were made 2 and 8 months after the catastrophe. Wave propagation and flood numerical models are presented and compared to field data. Our field analysis also reports on the devastating impacts of storm surges and waves, which reached 4 and 10 meters height, respectively, especially along east-facing shores. The approaches reveal a variety of morpho-sedimentary responses over both natural and highly urbanized coasts. The analysis shows the effects of coastal structures and streets on flow channeling, on the amplification of some erosion types, and on water level increase. Positive spatial correlation is found between damage intensity and marine flood depth. The signatures of ocean-induced damage are clear and tend to validate the relevance of the intensity scale used in this study.

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Section: Storm Surge Numerical Modeling and Geomorphological Observatsupporting

confidence: 89%

Section: Hurricane Characteristicsmentioning

confidence: 99%

Coastal Processes and Influence on Damage to Urban Structures during Hurricane Irma (St-Martin & St-Barthélemy, French West Indies)

Rey

Leone

Candela

et al. 2019

JMSE

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“…For example, overwash processes led to the deposition of sand, coral debris and blocks over distances that reached up to 70 m from the pre-cyclone vegetation line on Tubuai and Reunion islands, respectively in 2010 (TC Oli; Etienne, 2012) and 2014 (TC Bejisa; . In natural settings, sand and coral debris deposited by TCs may thus contribute to an increase in the elevation of low-lying coastal areas (Duvat et al, 2017b;Duvat et al, 2019). In contrast, in highly-developed settings, these deposits are often quickly removed and used for construction (Bush, 1991), which annihilates the abovementioned positive effect of TCs.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast, in highly-developed settings, these deposits are often quickly removed and used for construction (Bush, 1991), which annihilates the abovementioned positive effect of TCs. Importantly, several studies emphasized the high spatial variability of cyclone-induced morphological changes on small islands' coasts over short distances, and even on the sediment cell scale (Cazes- Duvat, 2005;Etienne, 2012;Duvat et al, 2019). The nature (erosional vs. accretional) and severity of TC impacts are function of a variety of factors, including the cyclone track, island and shoreline exposure (which decreases with the presence of nearshore islets and of protruding headlands), the coastal system's geomorphic characteristics (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…Instead, the reflection of storm waves by these structures contributes to beach narrowing by increasing erosion (Bush, 1991;Fletcher et al, 1997), which eventually leads to beach loss (Schlacher et al, 2006;Cambers, 2009;Cooper and Pile, 2014). Additionally, the establishment of tourist amenities in coastal areas has led, in many cases, to the destruction and replacement of the native vegetation by introduced species, which decreases the resistance and the resilience of coastal systems to TC impacts (Cambers, 2009;Duvat et al, 2017b;Duvat et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Assessing the impacts of shoreline hardening on beach response to hurricanes: Saint-Barthélemy, Lesser Antilles

Pillet

Duvat

Krien

et al. 2019

Ocean & Coastal Management

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Coastal erosion and sediment reworking caused by hurricane Irma – implications for storm impact on low‐lying tropical islands

Spiske

Pilarczyk

Mitchell

et al. 2021

Earth Surf Processes Landf

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Hurricane Irma (September 2017) was one of the most devastating hurricanes in recent times. In January 2018, a post‐hurricane field survey was conducted on Anegada (British Virgin Islands) to report on the erosional and depositional evidence caused by Hurricane Irma's storm surge and waves. We document the type and extent of hurricane‐induced geomorphological changes, allowing for an improved risk assessment of hurricane‐related inundation on low‐lying islands and carbonate platforms. Anegada's north shore was most impacted by Hurricane Irma. The surge reached about 3.8 m above sea level and onshore flow depths ranged between 1.2 to 1.6 m. Storm wave action created 1 to 1.5 m high erosional scarps along the beaches, and the coastline locally retreated by 6 to 8 m. Onshore sand sheets reached up to 40 m inland, overlie a sharp erosive contact and have thicknesses of 7 to 35 cm along the north shore. In contrast, lobate overwash fans in the south are 2 to 10 cm thick and reach 10 to 30 m inland. Moreover, the hurricane reworked a pre‐existing coast‐parallel coral rubble ridge on the central north shore. The crest of the coral rubble ridge shifted up to 10 m inland due to the landward transport of cobbles and boulders (maximum size 0.5 m3) that were part of the pre‐hurricane ridge. A re‐survey, 18 months after the event, assessed the degree of the natural coastal recovery. The sand along the northern shoreline of Anegada that was eroded during the hurricane and stored in the shallow water, acted as a nearshore source for beach reconstruction which set in only days after the event. Beach recovery peaked in February 2018, when beaches accreted within hours during a nor'easter‐like storm that transported large volumes of nearshore sand back onto the beach.

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High human influence on beach response to tropical cyclones in small islands: Saint-Martin Island, Lesser Antilles

Cited by 27 publications

References 50 publications

Coastal Processes and Influence on Damage to Urban Structures during Hurricane Irma (St-Martin & St-Barthélemy, French West Indies)

Coastal Processes and Influence on Damage to Urban Structures during Hurricane Irma (St-Martin & St-Barthélemy, French West Indies)

Assessing the impacts of shoreline hardening on beach response to hurricanes: Saint-Barthélemy, Lesser Antilles

Coastal erosion and sediment reworking caused by hurricane Irma – implications for storm impact on low‐lying tropical islands

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