Boussinesq Modeling of Wave Transformation, Breaking, and Runup. I: 1D

Chen, Qin; Kirby, James T.; Dalrymple, Robert A.; Kennedy, Andrew; Chawla, Arun

doi:10.1061/(asce)0733-950x(2000)126:1(39)

Cited by 588 publications

(518 citation statements)

References 33 publications

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“…To accurately model these effects it was determined that a grid spacing of 5 m and the fully nonlinear (FNL-EXT) equations were needed. Energy dissipation from wave breaking is employed using an eddy viscosity scheme (Kennedy et al, 2000), though because this is a 1D simulation, the attenuating effect of geometric spreading is not included. Runup was computed at mean sea level, noting that the tidal stage at the time of a tsunami will also influence runup and inundation (Mofjeld et al, 2007).…”

Section: High-resolution 1d Modelingmentioning

confidence: 99%

Hydrodynamic modeling of tsunamis from the Currituck landslide

2009

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Keywords: tsunami landslide hydrodynamic runup numerical model sensitivity analysis Tsunami generation from the Currituck landslide offshore North Carolina and propagation of waves toward the U.S. coastline are modeled based on recent geotechnical analysis of slide movement. A long and intermediate wave modeling package (COULWAVE) based on the non-linear Boussinesq equations are used to simulate the tsunami. This model includes procedures to incorporate bottom friction, wave breaking, and overland flow during runup. Potential tsunamis generated from the Currituck landslide are analyzed using four approaches: (1) tsunami wave history is calculated from several different scenarios indicated by geotechnical stability and mobility analyses; (2) a sensitivity analysis is conducted to determine the effects of both landslide failure duration during generation and bottom friction along the continental shelf during propagation; (3) wave history is calculated over a regional area to determine the propagation of energy oblique to the slide axis; and (4) a high-resolution 1D model is developed to accurately model wave breaking and the combined influence of nonlinearity and dispersion during nearshore propagation and runup. The primary source parameter that affects tsunami severity for this case study is landslide volume, with failure duration having a secondary influence. Bottom friction during propagation across the continental shelf has a strong influence on the attenuation of the tsunami during propagation. The high-resolution 1D model also indicates that the tsunami undergoes nonlinear fission prior to wave breaking, generating independent, short-period waves. Wave breaking occurs approximately 40-50 km offshore where a tsunami bore is formed that persists during runup. These analyses illustrate the complex nature of landslide tsunamis, necessitating the use of detailed landslide stability/mobility models and higher-order hydrodynamic models to determine their hazard.Published by Elsevier B.V.

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Section: High-resolution 1d Modelingmentioning

confidence: 99%

Hydrodynamic modeling of tsunamis from the Currituck landslide

2009

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“…The wave propagation model is fully nonlinear and able to simulate a wide range of wavelengths not limited to long waves . FUNWAVE is designed to model the physics of breaking waves and runup Kennedy et al, 2000). Geowave takes the tsunami source from TOPICS and inputs this as an initial condition into FUNWAVE at time t o after the landslide begins accelerating.…”

Section: Tsunami Propagation and Inundation Simulationmentioning

confidence: 99%

Submarine landslides in the Santa Barbara Channel as potential tsunami sources

Greene

Murai

Watts³

et al. 2006

Nat. Hazards Earth Syst. Sci.

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“…To simulate the effects of wave breaking, the eddy viscosity model (Zelt, 1991;Kennedy et al, 2000) is used here. Readers are directed to Kennedy et al (2000) for a thorough description and validation of the breaking model, and the coefficients and thresholds given therein are used for all the simulations presented in this paper.…”

Section: Model Equations and Numerical Schemementioning

confidence: 99%

“…Their derivation makes use of the NLSW equations, and thus for consistency the dispersive (l 2 ) terms will be ignored in the numerical simulations for this comparison. The wave and slope parameters for this test case are identical to those used by Madsen et al (1997) and Kennedy et al (2000). A wave train with height 0.006 m and period of 10 s travels in a onedimensional channel with a depth of 0.5 m and a slope of 1:25.…”

Section: Sine Wave Runupmentioning

confidence: 99%

Modeling wave runup with depth-integrated equations

Lynett

Liu

2002

Coastal Engineering

359

212

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In this paper, a moving boundary technique is developed to investigate wave runup and rundown with depth-integrated equations. Highly nonlinear and weakly dispersive equations are solved using a high-order finite difference scheme. An eddy viscosity model is adopted for wave breaking so as to investigate breaking wave runup. The moving boundary technique utilizes linear extrapolation through the wet -dry boundary and into the dry region. Nonbreaking and breaking solitary wave runup is accurately predicted by the proposed model, yielding a validation of both the wave breaking parameterization and the moving boundary technique. Two-dimensional wave runup in a parabolic basin and around a conical island is investigated, and agreement with published data is excellent. Finally, the propagation and runup of a solitary wave in a trapezoidal channel is examined. D

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Boussinesq Modeling of Wave Transformation, Breaking, and Runup. I: 1D

Cited by 588 publications

References 33 publications

Hydrodynamic modeling of tsunamis from the Currituck landslide

Hydrodynamic modeling of tsunamis from the Currituck landslide

Submarine landslides in the Santa Barbara Channel as potential tsunami sources

Modeling wave runup with depth-integrated equations

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