A Simple Parameterization of Land Surface Processes for Meteorological Models

A parameterization of land surface processes to be included in mesoscale and large-scale meteorological models is presented. The number of parameters has been reduced as much as possible, while attempting to preserve the representation of the physics which controls the energy and water budgets. The...

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Bibliographic Details
Published in:Monthly weather review 1989-03, Vol.117 (3), p.536-549
Main Authors: Noilhan, J., Planton, S.
Format: Article
Language:English
Online Access:Get full text
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Summary:A parameterization of land surface processes to be included in mesoscale and large-scale meteorological models is presented. The number of parameters has been reduced as much as possible, while attempting to preserve the representation of the physics which controls the energy and water budgets. The authors distinguish two main classes of parameters. The spatial distribution of primary parameters (the dominant types of soil and vegetation within each grid cell) can be specified from existing global data sets. The secondary parameters, describing the physical properties of each type of soil and vegetation, can be inferred from measurements or derived from numerical experiments. A single surface temperature is used to represent the surface energy balance of the land-cover system. The soil heat flux is linearly interpolated between its value over bare ground and a value of zero for complete shielding by the vegetation. The ground surface moisture equation includes the effect of gravity, and the thermohydric coefficients of the equations have been either calculated or calibrated by using textural dependent formulations. The calibration has been made by using the results of a detailed soil model forced by prescribed atmospheric mean conditions. The results show that the coefficients of the surface soil moisture equation are greatly dependent upon the textural class of the soil, as well as upon its moisture content. The new scheme has been included in a one-dimensional model that permits a complete interaction between the surface and the atmosphere. Several simulations have been performed by using data collected during HAPEX-MOBILHY. These first results show the ability of the parameterization to reproduce the components of the surface energy balance over a wide variety of surface conditions.
ISSN:0027-0644
1520-0493
DOI:10.1175/1520-0493(1989)117<0536:aspols>2.0.co;2