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Zeitlin Truncation of a Shallow Water Quasi‐Geostrophic Model for Planetary Flow

Arnout Franken, Martino Caliaro, Paolo Cifani, Bernard J. Geurts

2024Journal of Advances in Modeling Earth Systems11 citationsDOIOpen Access PDF

Abstract

Abstract In this work, we consider a Shallow‐Water Quasi Geostrophic equation on the sphere, as a model for global large‐scale atmospheric dynamics. This equation, previously studied by Verkley (2009, https://doi.org/10.1175/2008jas2837.1 ) and Schubert et al. (2009, https://doi.org/10.3894/james.2009.1.2 ), possesses a rich geometric structure, called Lie‐Poisson, and admits an infinite number of conserved quantities, called Casimirs. In this paper, we develop a Casimir preserving numerical method for long‐time simulations of this equation. The method develops in two steps: first, we construct an N‐dimensional Lie‐Poisson system that converges to the continuous one in the limit N → ∞ ; second, we integrate in time the finite‐dimensional system using an isospectral time integrator, developed by Modin and Viviani (2020, https://doi.org/10.1017/jfm.2019.944 ). We demonstrate the efficacy of this computational method by simulating a flow on the entire sphere for different values of the Lamb parameter. We particularly focus on rotation‐induced effects, such as the formation of jets. In agreement with shallow water models of the atmosphere, we observe the formation of robust latitudinal jets and a decrease in the zonal wind amplitude with latitude. Furthermore, spectra of the kinetic energy are computed as a point of reference for future studies.

Topics & Concepts

Shallow water equationsPhysicsIsospectralTruncation (statistics)Waves and shallow waterTruncation errorGeostrophic windFlow (mathematics)Classical mechanicsMathematical analysisMathematicsMathematical physicsMechanicsStatisticsThermodynamicsMeteorological Phenomena and SimulationsFluid Dynamics and Turbulent FlowsClimate variability and models