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Editorial Type:
Article
Article Type:
Research Article

Atmospheric General Circulation Simulations with the BMRC Global Spectral Model. The Impact of Revised Physical Parameterizations

Terry L. HartBureau of Meteorology Research Centre, Melbourne, Victoria, Australia

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William BourkeBureau of Meteorology Research Centre, Melbourne, Victoria, Australia

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Bryant J. McAvaneyBureau of Meteorology Research Centre, Melbourne, Victoria, Australia

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Bruce W. ForganBureau of Meteorology Research Centre, Melbourne, Victoria, Australia

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John L. McGregorCSIRO Division of Atmospheric Research, Mordialloc, Victoria, Australia

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Print Publication:
01 Apr 1990
DOI:
https://doi.org/10.1175/1520-0442(1990)003<0436:AGCSWT>2.0.CO;2
Page(s):
436–459
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Abstract

Results are presented for perpetual January and July general circulation simulations using the Australian Bureau of Meteorology Research Centre global spectral model. Particular emphasis is placed on the impact of changes in the physical parameterizations and horizontal resolution on the modeled fields. The results include variances and eddy transports as well as zonal means and geographical distributions. Of the experiments conducted the most satisfactory results were obtained using stability-dependent vertical diffusion and a combination of the Kuo scheme for deep convection and the Tiedtke shallow convection scheme.

The simulation of the polar night region of the stratosphere in January was much more realistic than in results obtained using an earlier version of the model. The improvement is attributed to the revised radiation code, supporting the conclusions of Ramanathan et al. on the sensitivity of simulations of this region of the atmosphere to the treatment of radiative processes.

Abstract

Results are presented for perpetual January and July general circulation simulations using the Australian Bureau of Meteorology Research Centre global spectral model. Particular emphasis is placed on the impact of changes in the physical parameterizations and horizontal resolution on the modeled fields. The results include variances and eddy transports as well as zonal means and geographical distributions. Of the experiments conducted the most satisfactory results were obtained using stability-dependent vertical diffusion and a combination of the Kuo scheme for deep convection and the Tiedtke shallow convection scheme.

The simulation of the polar night region of the stratosphere in January was much more realistic than in results obtained using an earlier version of the model. The improvement is attributed to the revised radiation code, supporting the conclusions of Ramanathan et al. on the sensitivity of simulations of this region of the atmosphere to the treatment of radiative processes.

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