Adaptive wavelet simulation of global ocean dynamics using a new Brinkman volume penalization

N. K.R. Kevlahan; T. Dubos; M. Aechtner

doi:10.5194/gmd-8-3891-2015

Adaptive wavelet simulation of global ocean dynamics using a new Brinkman volume penalization

N. K.R. Kevlahan
, T. Dubos
, M. Aechtner

McMaster University

Research output: Contribution to journal › Article › peer-review

Abstract

In order to easily enforce solid-wall boundary conditions in the presence of complex coastlines, we propose a new mass and energy conserving Brinkman penalization for the rotating shallow water equations. This penalization does not lead to higher wave speeds in the solid region. The error estimates for the penalization are derived analytically and verified numerically for linearized one-dimensional equations. The penalization is implemented in a conservative dynamically adaptive wavelet method for the rotating shallow water equations on the sphere with bathymetry and coastline data from NOAA's ETOPO1 database. This code could form the dynamical core for a future global ocean model. The potential of the dynamically adaptive ocean model is illustrated by using it to simulate the 2004 Indonesian tsunami and wind-driven gyres.

Original language	English
Pages (from-to)	3891-3909
Number of pages	19
Journal	Geoscientific Model Development
Volume	8
Issue number	12
DOIs	https://doi.org/10.5194/gmd-8-3891-2015
Publication status	Published - 9 Dec 2015

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title = "Adaptive wavelet simulation of global ocean dynamics using a new Brinkman volume penalization",

abstract = "In order to easily enforce solid-wall boundary conditions in the presence of complex coastlines, we propose a new mass and energy conserving Brinkman penalization for the rotating shallow water equations. This penalization does not lead to higher wave speeds in the solid region. The error estimates for the penalization are derived analytically and verified numerically for linearized one-dimensional equations. The penalization is implemented in a conservative dynamically adaptive wavelet method for the rotating shallow water equations on the sphere with bathymetry and coastline data from NOAA's ETOPO1 database. This code could form the dynamical core for a future global ocean model. The potential of the dynamically adaptive ocean model is illustrated by using it to simulate the 2004 Indonesian tsunami and wind-driven gyres.",

author = "Kevlahan, \{N. K.R.\} and T. Dubos and M. Aechtner",

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AU - Kevlahan, N. K.R.

AU - Dubos, T.

AU - Aechtner, M.

PY - 2015/12/9

Y1 - 2015/12/9

N2 - In order to easily enforce solid-wall boundary conditions in the presence of complex coastlines, we propose a new mass and energy conserving Brinkman penalization for the rotating shallow water equations. This penalization does not lead to higher wave speeds in the solid region. The error estimates for the penalization are derived analytically and verified numerically for linearized one-dimensional equations. The penalization is implemented in a conservative dynamically adaptive wavelet method for the rotating shallow water equations on the sphere with bathymetry and coastline data from NOAA's ETOPO1 database. This code could form the dynamical core for a future global ocean model. The potential of the dynamically adaptive ocean model is illustrated by using it to simulate the 2004 Indonesian tsunami and wind-driven gyres.

AB - In order to easily enforce solid-wall boundary conditions in the presence of complex coastlines, we propose a new mass and energy conserving Brinkman penalization for the rotating shallow water equations. This penalization does not lead to higher wave speeds in the solid region. The error estimates for the penalization are derived analytically and verified numerically for linearized one-dimensional equations. The penalization is implemented in a conservative dynamically adaptive wavelet method for the rotating shallow water equations on the sphere with bathymetry and coastline data from NOAA's ETOPO1 database. This code could form the dynamical core for a future global ocean model. The potential of the dynamically adaptive ocean model is illustrated by using it to simulate the 2004 Indonesian tsunami and wind-driven gyres.

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JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 12

ER -

Adaptive wavelet simulation of global ocean dynamics using a new Brinkman volume penalization

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