The reduction of storm surge by vegetation canopies: Three‐dimensional simulations

Sheng, Y. Peter; Lapetina, Andrew; Ma, Gangfeng

doi:10.1029/2012gl053577

Cited by 74 publications

(81 citation statements)

References 21 publications

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“…Costanza et al, 2008;Das and Vincent, 2009;Kraus et al, 2009;Gedan et al, 2011) and hydrodynamic modelling studies (e.g. Wamsley et al, 2010;Temmerman et al, 2012;Zhang et al, 2012;Sheng et al, 2012;Liu et al, 2013;Hu et al, 2015). All these studies focussed on the attenuation of storm surges that propagate through coastal wetlands, which we call here within-wetland attenuation, while to our knowledge few scientific studies exist on the effects of intertidal wetland properties on storm tide attenuation along estuaries, a mechanism we call here along-estuary attenuation (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Lovelace, 1994;McGee et al, 2006;Krauss et al, 2009;Wamsley et al, 2010) and on hydrodynamic model simulations (e.g. Resio and Westerink, 2008;Loder et al, 2009;Wamsley et al, 2009Wamsley et al, , 2010Zhang et al, 2012;Temmerman et al, 2012;Sheng et al, 2012;Liu et al, 2013;Hu et al, 2015). These studies reported that peak water levels can be reduced by 5 to 50 cm km −1 when storm surges travel through tidal marshes or mangroves, causing flood wave energy loss due to increased bottom friction.…”

Section: Introductionmentioning

confidence: 96%

“…Model studies have demonstrated that the degree of within-wetland attenuation is dependent on wetland properties, such as the size, elevation and vegetation type (e.g. Loder et al, 2009;Wamsley et al, 2009Wamsley et al, , 2010Zhang et al, 2012;Temmerman et al, 2012;Sheng et al, 2012;Hu et al, 2015), as well as properties of the storm, such as the strength, duration, forward speed and track of the storm (e.g. Resio and Westerink, 2008;Loder et al, 2009;Wamsley et al, 2010;Sheng et al, 2012;Liu et al, 2013;Hu et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Role of intertidal wetlands for tidal and storm tide attenuation along a confined estuary: a model study

Smolders

Plancke

Ides

et al. 2015

Nat. Hazards Earth Syst. Sci.

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Abstract. Coastal lowlands and estuaries are subjected to increasing flood risks during storm surges due to global and regional changes. Tidal wetlands are increasingly valued as effective natural buffers for storm surges by dissipating wave energy and providing flood water storage. While previous studies focused on flood wave attenuation within and behind wetlands, this study focuses on the effects of estuarine wetland properties on the attenuation of a storm tide that propagates along the length of an estuary. Wetland properties including elevation, surface area, and location within the estuary were investigated using a numerical model of the Scheldt estuary (Belgium, SW Netherlands). For a spring tide lower wetland elevations result in more attenuation of high water levels along the estuary, while for a higher storm tide higher elevations provide more attenuation compared to lower wetland elevations. For spring and storm tide a larger wetland surface area results in a better attenuation along the estuary up to a threshold wetland size for which larger wetlands do not further contribute to more attenuation. Finally a wetland of the same size and elevation, but located more upstream in the estuary, can store a larger proportion of the local flood volume and therefore has a larger attenuating effect on upstream high water levels. With this paper we aim to contribute towards a better understanding and wider implementation of ecosystem-based adaptation to increasing estuarine flood risks associated with storms.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Role of intertidal wetlands for tidal and storm tide attenuation along a confined estuary: a model study

Smolders

Plancke

Ides

et al. 2015

Nat. Hazards Earth Syst. Sci.

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“…Sheng et al [52,53] developed a vegetation model which incorporates the effects of vegetation on mean flow and turbulence in the water column. The vegetation resolving model showed that, during hurricanes, total inundation volume can be reduced by up to 40% due to the presence of vegetation.…”

Section: Discussion and Future Workmentioning

confidence: 99%

Towards the Development of an Operational Forecast System for the Florida Coast

Paramygin

Sheng

Davis

2017

JMSE

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A nowcasting and forecasting system for storm surge, inundation, waves, and baroclinic flow for the Florida coast has been developed. The system is based on dynamically coupled CH3D and SWAN models and can use a variety of modules to provide different input forcing, boundary and initial conditions. The system is completely automated and operates unattended at pre-scheduled intervals as well as in event-triggered mode in response to Atlantic-basin tropical cyclone advisories issued by the National Hurricane Center. The system provides up to 72-h forecasts forward depending on the input dataset duration. Spatially, the system spans the entire Florida coastline by employing four high-resolution domains with resolutions as fine as 10-30 m in the near-shore and overland to allow the system to resolve fine estuarine details such as in the Intracoastal Waterway and minor tributaries. The system has been validated in both hindcast and nowcast/forecast modes using water level and salinity data from a variety of sources and has been found to run robustly during the test periods. Low level products (e.g., raw output datasets) are disseminated using THREDDS while a custom defined web-based graphical user interface (GUI) was developed for high level access.

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“…Meanwhile, mangroves provide habitat for fisheries and are green infrastructures that can protect coastal communities from flooding due to tropical cyclones (e.g., Krauss et al, 2009;Mcivor et al, 2012;Sheng et al, 2012) and tsunamis (Alongi, 2008). Nowadays, the creation and restoration of coastal ecosystems, including mangrove forests, coral reefs, and salt marshes, are being considered by many as a more sustainable, cost-effective and ecologically sound alternative instead of hard infrastructure for the mitigation of future coastal hazards (Feagin, 2008;Gedan et al, 2011;Duarte et al, 2013;Temmerman et al, 2013;Spalding et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Assessing the role of mangrove forest in reducing coastal inundation during major hurricanes

Sheng

Zou

2017

Hydrobiologia

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A vegetation-resolving CH3D-SWAN surge-wave modeling system is used to examine the role of mangroves and salt marshes along the shore of Biscayne Bay in buffering surge, wave, and inundation in Southeast Florida during Hurricane Andrew (1992). First, the 3D vegetation-resolving model is validated by comparing the simulated and measured high water marks from post-hurricane field survey, debris lines, and time series of water level at the Haulover Pier. The simulated water levels and magnitude and extent of maximum inundation agree well with the observed data, whereas the removal of vegetation from the model leads to massive flooding with increased total inundation volume and total inundation area in the highly populated low-lying area behind the Biscayne Bay. Additional simulations show that the surgewave-inundation buffering capacity of the mangrove forest depends on the vertical structure of the wetted leaf area index, A w and the frontal leaf area index, A f . The study demonstrates the capability of CH3D-SWAN in quantifying the role of mangroves in buffering storm surge, wave, and inundation, and demonstrates its potential application for assessing the effectiveness of coastal wetland restoration projects. Meanwhile, the accurate representation of vegetation's vertical structure can enhance the numerical modeling of flow-vegetation interaction processes.

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The reduction of storm surge by vegetation canopies: Three‐dimensional simulations

Cited by 74 publications

References 21 publications

Role of intertidal wetlands for tidal and storm tide attenuation along a confined estuary: a model study

Role of intertidal wetlands for tidal and storm tide attenuation along a confined estuary: a model study

Towards the Development of an Operational Forecast System for the Florida Coast

Assessing the role of mangrove forest in reducing coastal inundation during major hurricanes

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