Dispersive tsunami waves in the ocean: Model equations and sensitivity to dispersion and Coriolis effects

► A derivation of a Boussinesq model is provided which examines the relative importance of dispersion and Coriolis effects. ► Each effect is illustrated by a set of idealized examples with varying co-seismic source width in a flat-bottomed ocean. ► The model’s utility is demonstrated using the 2011...

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Veröffentlicht in:	Ocean modelling (Oxford) 2013-02, Vol.62, p.39-55
Hauptverfasser:	Kirby, James T., Shi, Fengyan, Tehranirad, Babak, Harris, Jeffrey C., Grilli, Stephan T.
Format:	Artikel
Sprache:	eng
Schlagworte:	Boussinesq wave model Coriolis effect Dispersive effect Fluid mechanics Mechanics Physics Tsunami
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creator	Kirby, James T. Shi, Fengyan Tehranirad, Babak Harris, Jeffrey C. Grilli, Stephan T.
description	► A derivation of a Boussinesq model is provided which examines the relative importance of dispersion and Coriolis effects. ► Each effect is illustrated by a set of idealized examples with varying co-seismic source width in a flat-bottomed ocean. ► The model’s utility is demonstrated using the 2011 Tohoku tsunami. We derive fully nonlinear, weakly dispersive model equations for propagation of surface gravity waves in a shallow, homogeneous ocean of variable depth on the surface of a rotating sphere. A numerical model is developed for the weakly nonlinear version of the model based on a combined finite-volume and finite-difference method with a fourth-order MUSCL-TVD scheme in space and a third-order SSP Runge–Kutta scheme in time. In the context of tsunami generation and propagation over trans-oceanic distances, a scaling analysis reveals that the importance of frequency dispersion increases with a decrease of the source width, while the effect of the Coriolis force increases with an increase of the source width. A sensitivity analysis to dispersive and Coriolis effects is carried out using the numerical model in a series of numerical experiments in an idealized ocean using Gaussian and di-polar sources with different source sizes. A simulation of the Tohoku 2011 tsunami is used to illustrate the effects of dispersive and Coriolis effects at large distances from the source region.
doi_str_mv	10.1016/j.ocemod.2012.11.009
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We derive fully nonlinear, weakly dispersive model equations for propagation of surface gravity waves in a shallow, homogeneous ocean of variable depth on the surface of a rotating sphere. A numerical model is developed for the weakly nonlinear version of the model based on a combined finite-volume and finite-difference method with a fourth-order MUSCL-TVD scheme in space and a third-order SSP Runge–Kutta scheme in time. In the context of tsunami generation and propagation over trans-oceanic distances, a scaling analysis reveals that the importance of frequency dispersion increases with a decrease of the source width, while the effect of the Coriolis force increases with an increase of the source width. A sensitivity analysis to dispersive and Coriolis effects is carried out using the numerical model in a series of numerical experiments in an idealized ocean using Gaussian and di-polar sources with different source sizes. 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subjects	Boussinesq wave model Coriolis effect Dispersive effect Fluid mechanics Mechanics Physics Tsunami
title	Dispersive tsunami waves in the ocean: Model equations and sensitivity to dispersion and Coriolis effects
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