Numerical solutions of a non‐linear density current: A benchmark solution and comparisons

Straka, Jerry M.; Wilhelmson, Robert B.; Wicker, Louis J.; Anderson, John R.; Droegemeier, Kelvin K.

doi:10.1002/fld.1650170103

Cited by 180 publications

(304 citation statements)

References 25 publications

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“…'linear' regularization). The results from Figure 4 are in excellent agreement with the reference solutions provided in Straka et al (1993). Even the simulation with a low resolution of x = z = 200 m yields a reasonable approximation.…”

Section: Test Case 2 From the Standard Test Set: Density Currentsupporting

confidence: 74%

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A regularization approach for a vertical‐slice model and semi‐Lagrangian Störmer–Verlet time stepping

Hundertmark

Reich

2007

Quart J Royal Meteoro Soc

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ABSTRACT:In this paper, we provide a systematic derivation of regularized equations for a non-hydrostatic and compressible vertical-slice model of the dry atmosphere. The derivation is based on an analysis of a semi-implicit discretization of the equations of motion and a recent regularized formulation is obtained as a special case. An implementation of the regularized equations, using a recent second-order, centred-in-time, two-time-level semi-Lagrangian Störmer-Verlet method, is discussed and a series of numerical experiments is conducted.

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Section: Test Case 2 From the Standard Test Set: Density Currentsupporting

confidence: 74%

“…This test case has been very well documented by Straka et al (1993). We implemented the regularized equations with a constant (reference) potential temperature θ = 300 K, a constant speed of sound c s = 347 m s −1 , N = 0, and with (45) further simplified to…”

Section: Test Case 2 From the Standard Test Set: Density Currentmentioning

confidence: 99%

A regularization approach for a vertical‐slice model and semi‐Lagrangian Störmer–Verlet time stepping

Hundertmark

Reich

2007

Quart J Royal Meteoro Soc

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“…The first test case considered, a rising thermal bubble, gauges the cloud resolving capabilities of NUMA with regard to capturing fine-scale structures [14,13]. Mesoscale or limited-area modeling capabilities are tested using a density current problem first proposed by Straka et al [37]. Finally, global scale weather and climate simulation capabilities are tested with an acoustic wave propagation problem proposed in Tomita and Satoh [38].…”

Section: Test Casesmentioning

confidence: 99%

“…To test the mesoscale modeling capabilities of NUMA, we use the density current problem first proposed in [37]. This test case concerns the evolution of a cold bubble in a neutrally stratified atmosphere of constant potential temperature θ 0 .…”

Section: Density Currentmentioning

confidence: 99%

“…The implementations are validated with several examples that are representative of typical atmospheric dynamics. Cloud resolving capabilities are tested with a rising thermal bubble problem [14], mesoscale modeling capabilities with a density current problem [37,13] and a global scale capability is tested with an acoustic wave propagation problem run on the entire planet [38].…”

Section: Introductionmentioning

confidence: 99%

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Efficient construction of unified continuous and discontinuous Galerkin formulations for the 3D Euler equations

Abdi

Giraldo

2016

Journal of Computational Physics

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A unified approach for the numerical solution of the 3D hyperbolic Euler equations using high order methods, namely continuous Galerkin (CG) and discontinuous Galerkin (DG) methods, is presented. First, we examine how classical CG that uses a global storage scheme can be constructed within the DG framework using constraint imposition techniques commonly used in the finite element literature. Then, we implement and test a simplified version in the Non-hydrostatic Unified Model of the Atmosphere (NUMA) for the case of explicit time integration and a diagonal mass matrix. Constructing CG within the DG framework allows CG to benefit from the desirable properties of DG such as, easier hp-refinement, better stability etc. Moreover, this representation allows for regional mixing of CG and DG depending on the flow regime in an area. The different flavors of CG and DG in the unified implementation are then tested for accuracy and performance using a suite of benchmark problems representative of cloud-resolving scale, meso-scale and global-scale atmospheric dynamics. The value of our unified approach is that we are able to show how to carry both CG and DG methods within the same code and also offer a simple recipe for modifying an existing CG code to DG and vice versa.

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Cold pool dissipation

Grant

Heever

2016

JGR Atmospheres

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The mechanisms by which sensible heat fluxes (SHFs) alter cold pool characteristics and dissipation rates are investigated in this study using idealized two-dimensional numerical simulations and an environment representative of daytime, dry, continental conditions. Simulations are performed with no SHFs, SHFs calculated using a bulk formula, and constant SHFs for model resolutions with horizontal (vertical) grid spacings ranging from 50 m (25 m) to 400 m (200 m). In the highest resolution simulations, turbulent entrainment of environmental air into the cold pool is an important mechanism for dissipation in the absence of SHFs. Including SHFs enhances cold pool dissipation rates, but the processes responsible for the enhanced dissipation differ depending on the SHF formulation. The bulk SHFs increase the near-surface cold pool temperatures, but their effects on the overall cold pool characteristics are small, while the constant SHFs influence the near-surface environmental stability and the turbulent entrainment rates into the cold pool. The changes to the entrainment rates are found to be the most significant of the SHF effects on cold pool dissipation. SHFs may also influence the timing of cold pool-induced convective initiation by altering the environmental stability and the cold pool intensity. As the model resolution is coarsened, cold pool dissipation is found to be less sensitive to SHFs. Furthermore, the coarser resolution simulations not only poorly but sometimes wrongly represent the SHF impacts on the cold pools. Recommendations are made regarding simulating the interaction of cold pools with convection and the land surface in cloud-resolving models.Idealized modeling simulations have been instrumental in advancing our understanding of varying aspects of cold pool, or density current, characteristics. These modeling studies have examined the turbulent and dynamic characteristics of density currents and the impact of the environment, such as the background stability and shear, on the cold pool dynamics [e.g., Droegemeier and Wilhelmson, 1987, hereafter DW87;Xu, 1992; Liu and Moncrieff, 2000, hereafter LM00; Seigel and van den Heever, 2012, hereafter SvdH12; Bryan and Rotunno, 2014; Rooney, 2015]. Other studies have examined the role of microphysical processes and GRANT AND VAN DEN HEEVER COLD POOL DISSIPATION 1138

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Numerical solutions of a non‐linear density current: A benchmark solution and comparisons

Cited by 180 publications

References 25 publications

A regularization approach for a vertical‐slice model and semi‐Lagrangian Störmer–Verlet time stepping

A regularization approach for a vertical‐slice model and semi‐Lagrangian Störmer–Verlet time stepping

Efficient construction of unified continuous and discontinuous Galerkin formulations for the 3D Euler equations

Cold pool dissipation

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