S. Dubey scite author profile

Abstract. The design of the icosahedral dynamical core DY-NAMICO is presented. DYNAMICO solves the multi-layer rotating shallow-water equations, a compressible variant of the same equivalent to a discretization of the hydrostatic primitive equations in a Lagrangian vertical coordinate, and the primitive equations in a hybrid mass-based vertical coordinate. The common Hamiltonian structure of these sets of equations is exploited to formulate energy-conserving spatial discretizations in a unified way.The horizontal mesh is a quasi-uniform icosahedral C-grid obtained by subdivision of a regular icosahedron. Control volumes for mass, tracers and entropy/potential temperature are the hexagonal cells of the Voronoi mesh to avoid the fast numerical modes of the triangular C-grid. The horizontal discretization is that of Ringler et al. (2010), whose discrete quasi-Hamiltonian structure is identified. The prognostic variables are arranged vertically on a Lorenz grid with all thermodynamical variables collocated with mass. The vertical discretization is obtained from the three-dimensional Hamiltonian formulation. Tracers are transported using a second-order finite-volume scheme with slope limiting for positivity. Explicit Runge-Kutta time integration is used for dynamics, and forward-in-time integration with horizontal/vertical splitting is used for tracers. Most of the model code is common to the three sets of equations solved, making it easier to develop and validate each piece of the model separately.Representative three-dimensional test cases are run and analyzed, showing correctness of the model. The design permits to consider several extensions in the near future, from higher-order transport to more general dynamics, especially deep-atmosphere and non-hydrostatic equations.

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A standard test case suite for two-dimensional linear transport on the sphere: results from a collection of state-of-the-art schemes

Lauritzen

Ullrich

Jablonowski

et al. 2014

Geosci. Model Dev.

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Recently, a standard test case suite for 2-D linear transport on the sphere was proposed to assess important aspects of accuracy in geophysical fluid dynamics with a "minimal" set of idealized model configurations/runs/diagnostics. Here we present results from 19 stateof-the-art transport scheme formulations based on finitedifference/finite-volume methods as well as emerging (in the context of atmospheric/oceanographic sciences) Galerkin methods. Discretization grids range from traditional regular latitude-longitude grids to more isotropic domain discretizations such as icosahedral and cubed-sphere tessellations of the sphere. The schemes are evaluated using a wide range of diagnostics in idealized flow environments. Accuracy is assessed in single-and two-tracer configurations using conventional error norms as well as novel diagnostics designed for climate and climate-chemistry applications. In addition, algorithmic considerations that may be important for computational efficiency are reported on. The latter is inevitably computing platform dependent.The ensemble of results from a wide variety of schemes presented here helps shed light on the ability of the test case suite diagnostics and flow settings to discriminate between algorithms and provide insights into accuracy in the context of global atmospheric/ocean modeling. A library of benchmark results is provided to facilitate scheme intercomparison and model development. Simple software and data sets are made available to facilitate the process of model evaluation and scheme intercomparison.

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A standard test case suite for two-dimensional linear transport on the sphere: results from a collection of state-of-the-art schemes

Lauritzen¹,

Ullrich²,

Jablonowski³

et al. 2013

Preprint

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Recently, a standard test case suite for 2-D linear transport on the sphere was proposed to assess important aspects of accuracy in geophysical fluid dynamics with a "minimal" set of idealized model configurations/runs/diagnostics. Here we present results from 19 state-of-the-art transport scheme formulations based on finite-difference/finite-volume methods as well as emerging (in the context of atmospheric/oceanographic sciences) Galerkin methods. Discretization grids range from traditional regular latitude-longitude grids to more isotropic domain discretizations such as icosahedral and cubed-sphere tessellations of the sphere. The schemes are evaluated using a wide range of diagnostics in idealized flow environments. Accuracy is assessed in single- and two-tracer configurations using conventional error norms as well as novel diagnostics designed for climate and climate-chemistry applications. In addition, algorithmic considerations that may be important for computational efficiency are reported on. The latter is inevitably computing platform dependent,

The ensemble of results from a wide variety of schemes presented here helps shed light on the ability of the test case suite diagnostics and flow settings to discriminate between algorithms and provide insights into accuracy in the context of global atmospheric/ocean modeling. A library of benchmark results is provided to facilitate scheme intercomparison and model development. Simple software and data-sets are made available to facilitate the process of model evaluation and scheme intercomparison

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DYNAMICO, an icosahedral hydrostatic dynamical core designed for consistency and versatility

Dubos¹,

Dubey²,

Tort³

et al. 2015

Preprint

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Abstract. The design of the icosahedral dynamical core DYNAMICO is presented. DYNAMICO solves the multi-layer rotating shallow-water equations, a compressible variant of the same equivalent to a discretization of the hydrostatic primitive equations in a Lagrangian vertical coordinate, and the primitive equations in a hybrid mass-based vertical coordinate. The common Hamiltonian structure of these sets of equations is exploited to formulate energy-conserving spatial discretizations in a unified way. The horizontal mesh is a quasi-uniform icosahedral C-grid obtained by subdivision of a regular icosahedron. Control volumes for mass, tracers and entropy/potential temperature are the hexagonal cells of the Voronoi mesh to avoid the fast numerical modes of the triangular C-grid. The horizontal discretization is that of Ringler et al. (2010), whose discrete quasi-Hamiltonian structure is identified. The prognostic variables are arranged vertically on a Lorenz grid with all thermodynamical variables collocated with mass. The vertical discretization is obtained from the three-dimensional Hamiltonian formulation. Tracers are transported using a second-order finite volume scheme with slope limiting for positivity. Explicit Runge–Kutta time integration is used for dynamics and forward-in-time integration with horizontal/vertical splitting is used for tracers. Most of the model code is common to the three sets of equations solved, making it easier to develop and validate each piece of the model separately. Representative three-dimensional test cases are run and analyzed, showing correctness of the model. The design permits to consider several extensions in the near future, from higher-order transport to more general dynamics, especially deep-atmosphere and non-hydrostatic equations.

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Scale interaction during an extreme rain event over southeast India

Krishnamurti

Dubey

Kumar

et al. 2017

Quart J Royal Meteoro Soc

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The major rains and floods over southeast India (during October through to December 2015) are addressed in the context of atmospheric scale interactions in the frequency domain. Some of the salient observational features of this period include: (i) the major El Niño of 2015, (ii) the stretch of lower tropospheric easterlies from the region of the warm sea‐surface temperature anomalies westwards to the east coast of India, (iii) presence of shear flow instability, in the presence of convection, along a long stretch of the easterly wind belt from the eastern Pacific Ocean to the eastern Bay of Bengal, (iv) large conversions of horizontal shear vorticity to curvature vorticity along this stretch of easterly trades, where these rain‐producing storms were forming, (v) an active IntraSeasonal Oscillation (ISO) time‐scale oscillation in the wind field that alternated between cyclonic and anticyclonic phases over southeast India during this period of heavy rains, and (vi) an active quasi‐biweekly oscillation that provides alternating onshore and offshore winds during this same period. The ISO and the quasi‐biweekly components contribute to the enhancement of the moisture supply from the Bay of Bengal during the extreme rain events. The synoptic scale receives its energy largely from organized convection within these disturbances on horizontal scales of the order of 2500 km. Other aspects such as the role of the sea‐surface temperatures of the Bay of Bengal and the role of Gill's antisymmetric heat source of the El Niño are also examined in this study.

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S. Dubey

DYNAMICO-1.0, an icosahedral hydrostatic dynamical core designed for consistency and versatility

A standard test case suite for two-dimensional linear transport on the sphere: results from a collection of state-of-the-art schemes

A standard test case suite for two-dimensional linear transport on the sphere: results from a collection of state-of-the-art schemes

DYNAMICO, an icosahedral hydrostatic dynamical core designed for consistency and versatility

Scale interaction during an extreme rain event over southeast India

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