Hybrid Mass Coordinate in WRF-ARW and Its Impact on Upper-Level Turbulence Forecasting

Abstract Although a terrain-following vertical coordinate is well suited for the application of surface boundary conditions, it is well known that the influences of the terrain on the coordinate surfaces can contribute to increase numerical errors, particularly over steep topography. To reduce these...

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Bibliographic Details
Published inMonthly weather review Vol. 147; no. 3; pp. 971 - 985
Main Authors Park, Sang-Hun, Klemp, Joseph B., Kim, Jung-Hoon
Format Journal Article
LanguageEnglish
Published Washington American Meteorological Society 01.03.2019
Subjects
Accuracy
Advection
Aerodynamics
Boundary conditions
Computational fluid dynamics
Computer simulation
Energy spectra
Errors
Forecasting
Gravitational waves
Influence
Kinetic energy
Mathematical models
Pressure
Terrain following
Topography
Turbulence
Weather forecasting
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Summary:Abstract Although a terrain-following vertical coordinate is well suited for the application of surface boundary conditions, it is well known that the influences of the terrain on the coordinate surfaces can contribute to increase numerical errors, particularly over steep topography. To reduce these errors, a hybrid sigma–pressure coordinate is formulated in the Weather Research and Forecasting (WRF) Model, and its effects are illustrated for both an idealized test case and a real-data forecast for upper-level turbulence. The idealized test case confirms that with the basic sigma coordinate, significant upper-level disturbances can be produced due to numerical errors that arise as the advection of strong horizontal flow is computed along coordinate surfaces that are perturbed by smaller-scale terrain influences. With the hybrid coordinate, this artificial noise is largely eliminated as the mid- and upper-level coordinate surfaces correspond much more closely to constant pressure surfaces. In real-data simulations for upper-level turbulence forecasting, the WRF Model using the basic sigma coordinate tends to overpredict the strength of upper-air turbulence over mountainous regions because of numerical errors arising as a strong upper-level jet is advected along irregular coordinate surfaces. With the hybrid coordinate, these errors are reduced, resulting in an improved forecast of upper-level turbulence. Analysis of kinetic energy spectra for these simulations confirms that artificial amplitudes in the smaller scales at upper levels that arise with the basic sigma coordinate are effectively removed when the hybrid coordinate is used.
ISSN:0027-0644
1520-0493
DOI:10.1175/MWR-D-18-0334.1