Abstract
Water infiltration is simulated by obtaining the time infiltrated depth evolution and humidity profiles with the numerical solution of the two-dimensional Richards’ equation. The contact time hypothesis is accepted in this study and used to apply a unique form on time of the water depth evolution in the solution domain (furrow), as boundary condition. The specific form of such evolution in time was obtained from results reported in the literature based on the internal numerical full coupling of the Saint-Venant and Richards’ equations in border irrigation. Moreover, the equivalent hydraulic area between the border and the furrow was achieved by scaling the values of water depth. The analysis was made for three contrasting soil textures, and the comparison was done by computing the root mean square error (RMSE) indicator. The comparison was performed from the selection of five finite element meshes with different densities to discretize the solution domain of the two-dimensional Richards’ equation, combined with several time steps. Finally, a comparison was made between infiltrated depth evolution calculated with a constant water depth in the furrow to the one proposed in this work, finding important differences between both approaches. To expand the scope of this study and for a fuller exploration of the subject, the results were compared with results obtained by applying the HYDRUS-2D software. The results confirm that it is important to consider an internal full coupling of the Saint-Venant and Richards´ equations to improve furrow irrigation simulations.
Highlights
Richards’ equation [1] is used in most hydrological models to describe groundwater flow in porous media
Banti et al [8] developed a model for the simulation of furrow irrigation advance based on the Saint-Venant equations for one-dimensional surface flow and the two-dimensional Richards’
The irrigation advance model was based on an analytical solution of the zero-inertia surface flow equations and was iteratively coupled with the two-dimensional subsurface flow model HYDRUS-2D
Summary
Richards’ equation [1] is used in most hydrological models to describe groundwater flow in porous media. Studies on infiltration modeling in surface irrigation can be found; for example, Liu et al [2] proposed a coupled model in which surface water flow and solute transport are described using the zero-inertia equation and the average cross-sectional convection–dispersion equation, respectively, while the two-dimensional Richards’ equation and the convection–dispersion equation are used to simulate water flow and solute transport in soils, respectively. Banti et al [8] developed a model for the simulation of furrow irrigation advance based on the Saint-Venant equations for one-dimensional surface flow and the two-dimensional Richards’. The irrigation advance model was based on an analytical solution of the zero-inertia surface flow equations and was iteratively coupled with the two-dimensional subsurface flow model HYDRUS-2D. Phenomena taking place in the furrow cross-section, not along the furrow
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