Reinitialised versus continuous regional climate simulations using ALARO-0 coupled to the land surface model SURFEXv5

Dynamical downscaling in a continuous approach using initial and boundary conditions from a reanalysis or a global climate model is a common method for simulating the regional climate. The simulation potential can be improved by applying an alternative approach of reinitialising the atmosphere, comb...

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Bibliographic Details
Published in:Geoscientific Model Development 2017-01, Vol.10 (1), p.223-238
Main Authors: Berckmans, Julie, Giot, Olivier, De Troch, Rozemien, Hamdi, Rafiq, Ceulemans, Reinhart, Termonia, Piet
Format: Article
Language:English
Subjects:
Atmosphere
Boundary conditions
Climate
Climate models
Comparative analysis
Computer simulation
Daily precipitation
Design
Energy
Fluxes
Global climate
Global climate models
Land surface models
Mediterranean climate
Precipitation
Regional climate models
Regional climates
Seasonal variation
Short term
Simulation
Summer
Summer climates
Surface energy
Surface properties
Temperate climates
Temperature
Weather forecasting
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Summary:Dynamical downscaling in a continuous approach using initial and boundary conditions from a reanalysis or a global climate model is a common method for simulating the regional climate. The simulation potential can be improved by applying an alternative approach of reinitialising the atmosphere, combined with either a daily reinitialised or a continuous land surface. We evaluated the dependence of the simulation potential on the running mode of the regional climate model ALARO coupled to the land surface model Météo-France SURFace EXternalisée (SURFEX), and driven by the ERA-Interim reanalysis. Three types of downscaling simulations were carried out for a 10-year period from 1991 to 2000, over a western European domain at 20 km horizontal resolution: (1) a continuous simulation of both the atmosphere and the land surface, (2) a simulation with daily reinitialisations for both the atmosphere and the land surface and (3) a simulation with daily reinitialisations of the atmosphere while the land surface is kept continuous. The results showed that the daily reinitialisation of the atmosphere improved the simulation of the 2 m temperature for all seasons. It revealed a neutral impact on the daily precipitation totals during winter, but the results were improved for the summer when the land surface was kept continuous. The behaviour of the three model configurations varied among different climatic regimes. Their seasonal cycle for the 2 m temperature and daily precipitation totals was very similar for a Mediterranean climate, but more variable for temperate and continental climate regimes. Commonly, the summer climate is characterised by strong interactions between the atmosphere and the land surface. The results for summer demonstrated that the use of a daily reinitialised atmosphere improved the representation of the partitioning of the surface energy fluxes. Therefore, we recommend using the alternative approach of the daily reinitialisation of the atmosphere for the simulation of the regional climate.
ISSN:1991-9603
1991-959X
1991-962X
1991-9603
1991-962X
DOI:10.5194/gmd-10-223-2017