A spatial model for soil-atmosphere interaction: Model construction and linear stability analysis

Amilcare Michele M. Porporato; Paolo D'Odorico; Luca Ridolfi; Ignacio Rodriguez-Iturbe

doi:10.1175/1525-7541(2000)001<0061:ASMFSA>2.0.CO;2

A spatial model for soil-atmosphere interaction: Model construction and linear stability analysis

Amilcare Michele M. Porporato, Paolo D'Odorico, Luca Ridolfi, Ignacio Rodriguez-Iturbe

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Abstract

A simple model is developed to investigate the role of spatial dynamics in the soil-atmosphere system. The model is constructed by considering the mass and energy balance equations for soil and atmosphere, closed with a two-dimensional, corrected quasigeostrophic approximation for large-scale atmospheric motions, and a suitable model for rainfall occurrence. The main result presented concerns the linear stability analyses of the homogenous equilibrium solutions for dry and wet climates. In the first case (desert) the system is stable and no spatial perturbation internal to the system can produce spatial heterogeneities. In the second case (wet climate) the dynamics can produce spatial instabilities of several scales, resulting in likely patterns of wet and dry zones. A key role in triggering this instability is played by the sensible heat flux to the atmosphere, which in turn is linked to soil moisture.

Original language	English (US)
Pages (from-to)	61-74
Number of pages	14
Journal	Journal of Hydrometeorology
Volume	1
Issue number	1
DOIs	https://doi.org/10.1175/1525-7541(2000)001<0061:ASMFSA>2.0.CO;2
State	Published - Feb 2000

All Science Journal Classification (ASJC) codes

Atmospheric Science

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10.1175/1525-7541(2000)001<0061:ASMFSA>2.0.CO;2

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abstract = "A simple model is developed to investigate the role of spatial dynamics in the soil-atmosphere system. The model is constructed by considering the mass and energy balance equations for soil and atmosphere, closed with a two-dimensional, corrected quasigeostrophic approximation for large-scale atmospheric motions, and a suitable model for rainfall occurrence. The main result presented concerns the linear stability analyses of the homogenous equilibrium solutions for dry and wet climates. In the first case (desert) the system is stable and no spatial perturbation internal to the system can produce spatial heterogeneities. In the second case (wet climate) the dynamics can produce spatial instabilities of several scales, resulting in likely patterns of wet and dry zones. A key role in triggering this instability is played by the sensible heat flux to the atmosphere, which in turn is linked to soil moisture.",

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T2 - Model construction and linear stability analysis

AU - Porporato, Amilcare Michele M.

AU - D'Odorico, Paolo

AU - Ridolfi, Luca

AU - Rodriguez-Iturbe, Ignacio

PY - 2000/2

Y1 - 2000/2

N2 - A simple model is developed to investigate the role of spatial dynamics in the soil-atmosphere system. The model is constructed by considering the mass and energy balance equations for soil and atmosphere, closed with a two-dimensional, corrected quasigeostrophic approximation for large-scale atmospheric motions, and a suitable model for rainfall occurrence. The main result presented concerns the linear stability analyses of the homogenous equilibrium solutions for dry and wet climates. In the first case (desert) the system is stable and no spatial perturbation internal to the system can produce spatial heterogeneities. In the second case (wet climate) the dynamics can produce spatial instabilities of several scales, resulting in likely patterns of wet and dry zones. A key role in triggering this instability is played by the sensible heat flux to the atmosphere, which in turn is linked to soil moisture.

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A spatial model for soil-atmosphere interaction: Model construction and linear stability analysis

Abstract

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