Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates

Peter H. Lauritzen; Julio T. Bacmeister; Thomas Dubos; Sébastien Lebonnois; Mark A. Taylor

doi:10.1002/2013MS000268

Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates

Peter H. Lauritzen
, Julio T. Bacmeister
, Thomas Dubos
, Sébastien Lebonnois
, Mark A. Taylor

Atmospheric Modeling and Predictability

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

18 Scopus citations

Abstract

In this paper, an analysis of the global AAM conservation properties of NCAR's Community Atmosphere Model Spectral Element (CAM-SE) dynamical core under Held-Suarez forcing is presented. It is shown that the spurious sources/sinks of AAM in CAM-SE are 3 orders of magnitude smaller than the parameterized (physical) sources/sinks. The effect on AAM conservation by changing various numerical aspects of the dynamical core (e.g., different vertical coordinates, reduced formal order of accuracy, increased dissipation, and decreased divergence damping) is investigated. In particular, it is noted that changing from Eulerian (hybrid-sigma) to floating Lagrangian vertical coordinates does not alter the global AAM conservation properties of CAM-SE. Key Points CAM-SE conserves global axial angular momentum (AAM) well Vertical coordinate/ polynomial order does not impact AAM properties CAM-SE dynamical core is well suited for Venus/Titan simulations

Original language	English
Pages (from-to)	129-140
Number of pages	12
Journal	Journal of Advances in Modeling Earth Systems
Volume	6
Issue number	1
DOIs	https://doi.org/10.1002/2013MS000268
State	Published - Mar 1 2014

Keywords

Galerkin methods
angular momentum
dynamical core
hyperviscosity
spectral elements
vertical discretization

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10.1002/2013MS000268

Cite this

Lauritzen, P. H., Bacmeister, J. T., Dubos, T., Lebonnois, S., & Taylor, M. A. (2014). Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates. Journal of Advances in Modeling Earth Systems, 6(1), 129-140. https://doi.org/10.1002/2013MS000268

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title = "Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates",

abstract = "In this paper, an analysis of the global AAM conservation properties of NCAR's Community Atmosphere Model Spectral Element (CAM-SE) dynamical core under Held-Suarez forcing is presented. It is shown that the spurious sources/sinks of AAM in CAM-SE are 3 orders of magnitude smaller than the parameterized (physical) sources/sinks. The effect on AAM conservation by changing various numerical aspects of the dynamical core (e.g., different vertical coordinates, reduced formal order of accuracy, increased dissipation, and decreased divergence damping) is investigated. In particular, it is noted that changing from Eulerian (hybrid-sigma) to floating Lagrangian vertical coordinates does not alter the global AAM conservation properties of CAM-SE. Key Points CAM-SE conserves global axial angular momentum (AAM) well Vertical coordinate/ polynomial order does not impact AAM properties CAM-SE dynamical core is well suited for Venus/Titan simulations",

keywords = "Galerkin methods, angular momentum, dynamical core, hyperviscosity, spectral elements, vertical discretization",

author = "Lauritzen, \{Peter H.\} and Bacmeister, \{Julio T.\} and Thomas Dubos and S{\'e}bastien Lebonnois and Taylor, \{Mark A.\}",

year = "2014",

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doi = "10.1002/2013MS000268",

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Lauritzen, PH , Bacmeister, JT, Dubos, T, Lebonnois, S & Taylor, MA 2014, 'Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates', Journal of Advances in Modeling Earth Systems, vol. 6, no. 1, pp. 129-140. https://doi.org/10.1002/2013MS000268

Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates. / Lauritzen, Peter H.; Bacmeister, Julio T.; Dubos, Thomas et al.
In: Journal of Advances in Modeling Earth Systems, Vol. 6, No. 1, 01.03.2014, p. 129-140.

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

TY - JOUR

T1 - Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core

T2 - A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates

AU - Lauritzen, Peter H.

AU - Bacmeister, Julio T.

AU - Dubos, Thomas

AU - Lebonnois, Sébastien

AU - Taylor, Mark A.

PY - 2014/3/1

Y1 - 2014/3/1

N2 - In this paper, an analysis of the global AAM conservation properties of NCAR's Community Atmosphere Model Spectral Element (CAM-SE) dynamical core under Held-Suarez forcing is presented. It is shown that the spurious sources/sinks of AAM in CAM-SE are 3 orders of magnitude smaller than the parameterized (physical) sources/sinks. The effect on AAM conservation by changing various numerical aspects of the dynamical core (e.g., different vertical coordinates, reduced formal order of accuracy, increased dissipation, and decreased divergence damping) is investigated. In particular, it is noted that changing from Eulerian (hybrid-sigma) to floating Lagrangian vertical coordinates does not alter the global AAM conservation properties of CAM-SE. Key Points CAM-SE conserves global axial angular momentum (AAM) well Vertical coordinate/ polynomial order does not impact AAM properties CAM-SE dynamical core is well suited for Venus/Titan simulations

AB - In this paper, an analysis of the global AAM conservation properties of NCAR's Community Atmosphere Model Spectral Element (CAM-SE) dynamical core under Held-Suarez forcing is presented. It is shown that the spurious sources/sinks of AAM in CAM-SE are 3 orders of magnitude smaller than the parameterized (physical) sources/sinks. The effect on AAM conservation by changing various numerical aspects of the dynamical core (e.g., different vertical coordinates, reduced formal order of accuracy, increased dissipation, and decreased divergence damping) is investigated. In particular, it is noted that changing from Eulerian (hybrid-sigma) to floating Lagrangian vertical coordinates does not alter the global AAM conservation properties of CAM-SE. Key Points CAM-SE conserves global axial angular momentum (AAM) well Vertical coordinate/ polynomial order does not impact AAM properties CAM-SE dynamical core is well suited for Venus/Titan simulations

KW - Galerkin methods

KW - angular momentum

KW - dynamical core

KW - hyperviscosity

KW - spectral elements

KW - vertical discretization

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SN - 1942-2466

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JO - Journal of Advances in Modeling Earth Systems

JF - Journal of Advances in Modeling Earth Systems

IS - 1

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Held-Suarez simulations with the Community Atmosphere Model Spectral Element (CAM-SE) dynamical core: A global axial angular momentum analysis using Eulerian and floating Lagrangian vertical coordinates

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