DCMIP2016: the splitting supercell test case

C. M. Zarzycki; C. Jablonowski; J. Kent; P. H. Lauritzen; R. Nair; K. A. Reed; P. A. Ullrich; D. M. Hall; M. A. Taylor; D. Dazlich; R. Heikes; C. Konor; D. Randall; X. Chen; L. Harris; M. Giorgetta; D. Reinert; C. Kühnlein; R. Walko; V. Lee; A. Qaddouri; M. Tanguay; H. Miura; T. Ohno; R. Yoshida; S.-H. Park; J. B. Klemp; W. C. Skamarock

doi:10.5194/gmd-12-879-2019

DCMIP2016: the splitting supercell test case

C. M. Zarzycki, C. Jablonowski, J. Kent, P. H. Lauritzen, R. Nair, K. A. Reed, P. A. Ullrich, D. M. Hall, M. A. Taylor, D. Dazlich, R. Heikes, C. Konor, D. Randall, X. Chen, L. Harris, M. Giorgetta, D. Reinert, C. Kühnlein, R. Walko, V. LeeA. Qaddouri, M. Tanguay, H. Miura, T. Ohno, R. Yoshida, S.-H. Park, J. B. Klemp, W. C. Skamarock

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Abstract

This paper describes the splitting supercell idealized test case used in the 2016 Dynamical Core Model Intercomparison Project (DCMIP2016). These storms are useful test beds for global atmospheric models because the horizontal scale of convective plumes is O(1 km), emphasizing non-hydrostatic dynamics. The test case simulates a supercell on a reduced-radius sphere with nominal resolutions ranging from 4 to 0.5 km and is based on the work of Klemp et al. (2015). Models are initialized with an atmospheric environment conducive to supercell formation and forced with a small thermal perturbation. A simplified Kessler microphysics scheme is coupled to the dynamical core to represent moist processes. Reference solutions for DCMIP2016 models are presented. Storm evolution is broadly similar between models, although differences in the final solution exist. These differences are hypothesized to result from different numerical discretizations, physics–dynamics coupling, and numerical diffusion. Intramodel solutions generally converge as models approach 0.5 km resolution, although exploratory simulations at 0.25 km imply some dynamical cores require more refinement to fully converge. These results can be used as a reference for future dynamical core evaluation, particularly with the development of non-hydrostatic global models intended to be used in convective-permitting regimes.

Original language	English
Pages (from-to)	879-892
Number of pages	14
Journal	Geoscientific Model Development
Volume	12
Issue number	3
DOIs	https://doi.org/10.5194/gmd-12-879-2019
Publication status	Published - 5 Mar 2019

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Zarzycki, C. M., Jablonowski, C., Kent, J., Lauritzen, P. H., Nair, R., Reed, K. A., Ullrich, P. A., Hall, D. M., Taylor, M. A., Dazlich, D., Heikes, R., Konor, C., Randall, D., Chen, X., Harris, L., Giorgetta, M., Reinert, D., Kühnlein, C., Walko, R., ... Skamarock, W. C. (2019). DCMIP2016: the splitting supercell test case. Geoscientific Model Development, 12(3), 879-892. https://doi.org/10.5194/gmd-12-879-2019

@article{ed3c1ea44a9848958d9102e44cff9d22,

title = "DCMIP2016: the splitting supercell test case",

abstract = "This paper describes the splitting supercell idealized test case used in the 2016 Dynamical Core Model Intercomparison Project (DCMIP2016). These storms are useful test beds for global atmospheric models because the horizontal scale of convective plumes is O(1 km), emphasizing non-hydrostatic dynamics. The test case simulates a supercell on a reduced-radius sphere with nominal resolutions ranging from 4 to 0.5 km and is based on the work of Klemp et al. (2015). Models are initialized with an atmospheric environment conducive to supercell formation and forced with a small thermal perturbation. A simplified Kessler microphysics scheme is coupled to the dynamical core to represent moist processes. Reference solutions for DCMIP2016 models are presented. Storm evolution is broadly similar between models, although differences in the final solution exist. These differences are hypothesized to result from different numerical discretizations, physics–dynamics coupling, and numerical diffusion. Intramodel solutions generally converge as models approach 0.5 km resolution, although exploratory simulations at 0.25 km imply some dynamical cores require more refinement to fully converge. These results can be used as a reference for future dynamical core evaluation, particularly with the development of non-hydrostatic global models intended to be used in convective-permitting regimes.",

author = "Zarzycki, {C. M.} and C. Jablonowski and J. Kent and Lauritzen, {P. H.} and R. Nair and Reed, {K. A.} and Ullrich, {P. A.} and Hall, {D. M.} and Taylor, {M. A.} and D. Dazlich and R. Heikes and C. Konor and D. Randall and X. Chen and L. Harris and M. Giorgetta and D. Reinert and C. K{\"u}hnlein and R. Walko and V. Lee and A. Qaddouri and M. Tanguay and H. Miura and T. Ohno and R. Yoshida and S.-H. Park and Klemp, {J. B.} and Skamarock, {W. C.}",

year = "2019",

month = mar,

day = "5",

doi = "10.5194/gmd-12-879-2019",

language = "English",

volume = "12",

pages = "879--892",

journal = "Geoscientific Model Development",

issn = "1991-959X",

publisher = "Copernicus Publications",

number = "3",

}

Zarzycki, CM, Jablonowski, C, Kent, J, Lauritzen, PH, Nair, R, Reed, KA, Ullrich, PA, Hall, DM, Taylor, MA, Dazlich, D, Heikes, R, Konor, C, Randall, D, Chen, X, Harris, L, Giorgetta, M, Reinert, D, Kühnlein, C, Walko, R, Lee, V, Qaddouri, A, Tanguay, M, Miura, H, Ohno, T, Yoshida, R, Park, S-H, Klemp, JB & Skamarock, WC 2019, 'DCMIP2016: the splitting supercell test case', Geoscientific Model Development, vol. 12, no. 3, pp. 879-892. https://doi.org/10.5194/gmd-12-879-2019

TY - JOUR

T1 - DCMIP2016: the splitting supercell test case

AU - Zarzycki, C. M.

AU - Jablonowski, C.

AU - Kent, J.

AU - Lauritzen, P. H.

AU - Nair, R.

AU - Reed, K. A.

AU - Ullrich, P. A.

AU - Hall, D. M.

AU - Taylor, M. A.

AU - Dazlich, D.

AU - Heikes, R.

AU - Konor, C.

AU - Randall, D.

AU - Chen, X.

AU - Harris, L.

AU - Giorgetta, M.

AU - Reinert, D.

AU - Kühnlein, C.

AU - Walko, R.

AU - Lee, V.

AU - Qaddouri, A.

AU - Tanguay, M.

AU - Miura, H.

AU - Ohno, T.

AU - Yoshida, R.

AU - Park, S.-H.

AU - Klemp, J. B.

AU - Skamarock, W. C.

PY - 2019/3/5

Y1 - 2019/3/5

N2 - This paper describes the splitting supercell idealized test case used in the 2016 Dynamical Core Model Intercomparison Project (DCMIP2016). These storms are useful test beds for global atmospheric models because the horizontal scale of convective plumes is O(1 km), emphasizing non-hydrostatic dynamics. The test case simulates a supercell on a reduced-radius sphere with nominal resolutions ranging from 4 to 0.5 km and is based on the work of Klemp et al. (2015). Models are initialized with an atmospheric environment conducive to supercell formation and forced with a small thermal perturbation. A simplified Kessler microphysics scheme is coupled to the dynamical core to represent moist processes. Reference solutions for DCMIP2016 models are presented. Storm evolution is broadly similar between models, although differences in the final solution exist. These differences are hypothesized to result from different numerical discretizations, physics–dynamics coupling, and numerical diffusion. Intramodel solutions generally converge as models approach 0.5 km resolution, although exploratory simulations at 0.25 km imply some dynamical cores require more refinement to fully converge. These results can be used as a reference for future dynamical core evaluation, particularly with the development of non-hydrostatic global models intended to be used in convective-permitting regimes.

AB - This paper describes the splitting supercell idealized test case used in the 2016 Dynamical Core Model Intercomparison Project (DCMIP2016). These storms are useful test beds for global atmospheric models because the horizontal scale of convective plumes is O(1 km), emphasizing non-hydrostatic dynamics. The test case simulates a supercell on a reduced-radius sphere with nominal resolutions ranging from 4 to 0.5 km and is based on the work of Klemp et al. (2015). Models are initialized with an atmospheric environment conducive to supercell formation and forced with a small thermal perturbation. A simplified Kessler microphysics scheme is coupled to the dynamical core to represent moist processes. Reference solutions for DCMIP2016 models are presented. Storm evolution is broadly similar between models, although differences in the final solution exist. These differences are hypothesized to result from different numerical discretizations, physics–dynamics coupling, and numerical diffusion. Intramodel solutions generally converge as models approach 0.5 km resolution, although exploratory simulations at 0.25 km imply some dynamical cores require more refinement to fully converge. These results can be used as a reference for future dynamical core evaluation, particularly with the development of non-hydrostatic global models intended to be used in convective-permitting regimes.

U2 - 10.5194/gmd-12-879-2019

DO - 10.5194/gmd-12-879-2019

M3 - Article

SN - 1991-959X

VL - 12

SP - 879

EP - 892

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 3

ER -

DCMIP2016: the splitting supercell test case

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