Observations and 3D hydrodynamics-based modeling of decadal-scale shoreline change along the Outer Banks, North Carolina

Safak, Ilgar; List, Jeffrey H.; Warner, John C.; Kumar, Nirnimesh

doi:10.1016/j.coastaleng.2016.11.014

Cited by 7 publications

(4 citation statements)

References 66 publications

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“…Therefore, smoothing was performed on the nearshore bathymetry between the coast and the 8 m isobath, gradually decreasing from the 6 m isobath to 8 m isobath where no smoothing is done so that the SFCR field is completely preserved in the bathymetry. Further details of the smoothing procedure are given by Safak et al ().…”

Section: Modelingmentioning

confidence: 99%

Persistent Shoreline Shape Induced From Offshore Geologic Framework: Effects of Shoreface Connected Ridges

et al. 2017

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Mechanisms relating offshore geologic framework to shoreline evolution are determined through geologic investigations, oceanographic deployments, and numerical modeling. Analysis of shoreline positions from the past 50 years along Fire Island, New York, a 50 km long barrier island, demonstrates a persistent undulating shape along the western half of the island. The shelf offshore of these persistent undulations is characterized with shoreface‐connected sand ridges (SFCR) of a similar alongshore length scale, leading to a hypothesis that the ridges control the shoreline shape through the modification of flow. To evaluate this, a hydrodynamic model was configured to start with the US East Coast and scale down to resolve the Fire Island nearshore. The model was validated using observations along western Fire Island and buoy data, and used to compute waves, currents and sediment fluxes. To isolate the influence of the SFCR on the generation of the persistent shoreline shape, simulations were performed with a linearized nearshore bathymetry to remove alongshore transport gradients associated with shoreline shape. The model accurately predicts the scale and variation of the alongshore transport that would generate the persistent shoreline undulations. In one location, however, the ridge crest connects to the nearshore and leads to an offshore‐directed transport that produces a difference in the shoreline shape. This qualitatively supports the hypothesized effect of cross‐shore fluxes on coastal evolution. Alongshore flows in the nearshore during a representative storm are driven by wave breaking, vortex force, advection and pressure gradient, all of which are affected by the SFCR.

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Section: Modelingmentioning

confidence: 99%

Persistent Shoreline Shape Induced From Offshore Geologic Framework: Effects of Shoreface Connected Ridges

et al. 2017

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“…The overall shoreline along the northern Outer Banks primarily faces northeast, with the orientation of beach segments ranging 15 to 30 degrees west of north from Corolla to Kitty Hawk (Figure 2-4). Net longshore transport is from north to south due to the high frequency and duration of extratropical storms from the northeast (i.e., nor'easters) (Dolan et al 1988;Safak et al 2017). Beach width is highly variable across the survey region but generally ranges from 20 to 30 m and fluctuates seasonally.…”

Section: Data Coverage 251 Outer Banks Regional Settingmentioning

confidence: 99%

“…Across all of Duck, from 1996 to 2012, the shoreline eroded at -0.45 m/year (CPE 2016). To the south, higher erosion rates exceeding -1.5 m/year have been measured at longterm erosional hotspots in Kitty Hawk and Kill Devil Hills, which have been associated with the presence of paleochannels and associated shoreoblique bars offshore (Miselis and McNinch 2006;Safak et al 2017).…”

Section: Data Coverage 251 Outer Banks Regional Settingmentioning

confidence: 99%

Coastal Lidar and Radar Imaging System (CLARIS) lidar data report : 2011 - 2017

Spore¹,

Renaud²,

Conery³

et al. 2019

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Coastal Lidar and Radar Imaging System between 2011 and 2017 along the northern Outer Banks of North Carolina near the CHL Field Research Facility. The report briefly describes the system and study site as well as the survey data extents, collection dates, and environmental context and data access information for the point cloud and digital elevation model products. Initial morphology data products and initial analyses are presented including calculations of shoreline change, dune volume, beach volume, beach slope, and cumulative elevation change over the 6-year study period. Follow-on reports will update the description of the available data repository moving forward. DISCLAIMER: The contents of this report are not to be used for advertising, publication, or promotional purposes. Citation of trade names does not constitute an official endorsement or approval of the use of such commercial products. All product names and trademarks cited are the property of their respective owners. The findings of this report are not to be construed as an official Department of the Army position unless so designated by other authorized documents.

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“…In recent years, three-dimensional hydrodynamic models based on the assumption of hydrostatic pressure distribution have become popular in the study of water motion and material transport in rivers, lakes, and open seas [1][2][3]. Among these models, the three-dimensional discontinuous Galerkin (3D DG) hydrodynamic model is receiving increasing attention [4][5][6] due to its advantages of mesh flexibility, high precision, and local conservation.…”

Section: Introductionmentioning

confidence: 99%

A Wetting and Drying Approach for a Mode-Nonsplit Discontinuous Galerkin Hydrodynamic Model with Application to Laizhou Bay

Chen,

Zhang,

Ran

et al. 2024

JMSE

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A wetting and drying treatment for a three-dimensional discontinuous Galerkin hydrodynamic model without mode splitting (external and internal modes) was developed. In this approach, computing elements are classified into wet, dry, and semidry elements, which are treated differently. In a Runge–Kutta time step, the reconstruction of the semidry elements and the combined utilization of two- and three-dimensional limiters help the model maintain stability. Numerical results show that the wetting and drying method can achieve a well-balanced property under the condition of still-water equilibrium and can reasonably describe the variation process of wetting and drying regions during a long wave run-up on a uniform slope and a tidal cycle in a basin with a variable slope. Analysis of the role of the limiters in the model indicated that the robustness of the three-dimensional hydrodynamic model can be effectively maintained when the two- and three-dimensional limiters are jointly applied for wetting and drying process simulation. A three-dimensional discontinuous Galerkin hydrodynamic model was applied with the presented wetting and drying method to simulate the tidal current evolution of a spring tidal cycle in southwestern Laizhou Bay in the Bohai Sea, in November 2003, and the simulated results of the water surface elevation and vertical layered current velocities agreed well with the measured data.

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Observations and 3D hydrodynamics-based modeling of decadal-scale shoreline change along the Outer Banks, North Carolina

Cited by 7 publications

References 66 publications

Persistent Shoreline Shape Induced From Offshore Geologic Framework: Effects of Shoreface Connected Ridges

Persistent Shoreline Shape Induced From Offshore Geologic Framework: Effects of Shoreface Connected Ridges

Coastal Lidar and Radar Imaging System (CLARIS) lidar data report : 2011 - 2017

A Wetting and Drying Approach for a Mode-Nonsplit Discontinuous Galerkin Hydrodynamic Model with Application to Laizhou Bay

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