Impacts of land cover heterogeneity and land surface parameterizations on turbulent characteristics and mesoscale simulations

Impacts of land cover heterogeneity and land surface parameterizations on turbulent characteristics and mesoscale simulations

The impacts of surface heterogeneity and land surface parameterization on the mesoscale processes were studied. Experiments were conducted using the Weather Research and Forecasting (WRF) model coupled with a simple (slab) land surface model (LSM), a relatively complex Noah LSM, and a land data assi...

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Bibliographic Details
Published in:Meteorology and atmospheric physics 2021-06, Vol.133 (3), p.589-610
Main Authors: Zheng, Yue, Brunsell, Nathaniel A., Alfieri, Joseph G., Niyogi, Dev
Format: Article
Language:eng
Subjects:
Aquatic Pollution
Atmospheric Sciences
Data assimilation
Data collection
Earth and Environmental Science
Earth Sciences
Eddies
Energy spectra
Fluxes
Heterogeneity
Land cover
Land surface models
Land use
Length
Math. Appl. in Environmental Science
Mesoscale phenomena
Mesoscale processes
Meteorology
Original Paper
Parameterization
Patchiness
Simulation
Soil moisture
Spatial heterogeneity
Spectra
Surface fluxes
Terrestrial Pollution
Turbulence
Waste Water Technology
Water Management
Water Pollution Control
Weather forecasting
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Summary:The impacts of surface heterogeneity and land surface parameterization on the mesoscale processes were studied. Experiments were conducted using the Weather Research and Forecasting (WRF) model coupled with a simple (slab) land surface model (LSM), a relatively complex Noah LSM, and a land data assimilation system (LDAS) with detailed surface fields. Three heterogeneity length scales: 1, 3, and 9 km, were employed to alter land cover and land use. A series of simulations were performed over the U.S. Southern Great Plains during the summer when the soil moisture was abundant. Results indicate that both the land surface parameterizations and fine-scale surface heterogeneity affect the model simulations; and the impact of land surface parameterization is found to be more important, particularly for low frequency ( f < 10 - 4 hz ) eddies and mesoscale circulations. Substantial variations in turbulent spectra were also noted, and the energy spectra respond nonlinearly to the changes in the heterogeneous length scales. Three important conclusions emerge: (i) more detailed land surface representation reduces uncertainty in simulations of surface fluxes via improved turbulence characterization over a heterogeneous land surface, which helps improve simulations of land–atmosphere feedbacks; (ii) the impact of land surface heterogeneity on atmospheric feedbacks can be detected in the mesoscale circulations that are roughly four times of the spatial heterogeneity scale ; and (iii) the land surface heterogeneity that can influence mesoscale circulations would be a function of grid spacing in the model.
ISSN:0177-7971
1436-5065