Andrew Lapetina scite author profile

[1] Significant buffering of storm surges by vegetation canopies has been suggested by limited observations and simple numerical studies, particularly following recent Hurricanes Katrina, Rita, and Wilma. Here we simulate storm surge and inundation over idealized topographies using a threedimensional vegetation-resolving storm surge model coupled to a shallow water wave model and show that a sufficiently wide and tall vegetation canopy reduces inundation on land by 5 to 40 percent, depending upon various storm and canopy parameters. Effectiveness of the vegetation in dissipating storm surge and inundation depends on the intensity and forward speed of the hurricane, as well as the density, height, and width of the vegetation canopy. Reducing the threat to coastal vegetation from development, sea level rise, and other anthropogenic factors would help to protect many coastal regions against storm surges. Citation: Sheng, Y. P., A. Lapetina, and G. Ma (2012), The reduction of storm surge by vegetation canopies: Three-dimensional simulations, Geophys. Res.

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Three-Dimensional Modeling of Storm Surge and Inundation Including the Effects of Coastal Vegetation

Lapetina

Sheng

2014

Estuaries and Coasts

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Simulating complex storm surge dynamics: Three‐dimensionality, vegetation effect, and onshore sediment transport

Lapetina

Sheng

2015

JGR Oceans

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The 3‐D hydrodynamics of storm surge events, including the effects of vegetation and impact on onshore transport of marine sediment, have important consequences for coastal communities. Here, complex storm surge dynamics during Hurricane Ike are investigated using a three‐dimensional (3‐D), vegetation‐resolving storm surge‐wave model (CH3D‐SWAN) which includes such effects of vegetation as profile drag, skin friction, and production, dissipation, and transport of turbulence. This vegetation‐resolving 3‐D model features a turbulent kinetic energy (TKE) closure model, which uses momentum equations with vegetation‐induced profile and skin friction drags, a dynamic q2 equation including turbulence production and dissipation by vegetation, as well as vegetation‐dependent algebraic length‐scale equations, and a Smagorinsky‐type horizontal turbulence model. This vegetation model has been verified using extensive laboratory tests, but this study is a comparison of 2‐D and 3‐D simulations of complex storm surge dynamics during Hurricane Ike. We examine the value of 3‐D storm surge models relative to 2‐D models for simulating coastal currents, effects of vegetation on surge, and sediment transport during storm events. Comparisons are made between results obtained using simple 2‐D formulations for bottom friction, the Manning coefficient (MC) approach, and physics‐based 3‐D vegetation‐modeling (VM) approach. Last, the role that the 3‐D hydrodynamics on onshore transport and deposition of marine sediments during the storm is investigated. While both the 3‐D and 2‐D results simulated the water level dynamics, results of the physics‐based 3‐D VM approach, as compared to the 2‐D MC approach, more accurately captures the complex storm surge dynamics.

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Andrew Lapetina

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

Three-Dimensional Modeling of Storm Surge and Inundation Including the Effects of Coastal Vegetation

Simulating complex storm surge dynamics: Three‐dimensionality, vegetation effect, and onshore sediment transport

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