New 3D Analytical Solution for Modeling Transient Unsaturated Flow Due to Wetting and Drying
Publication: International Journal of Geomechanics
Volume 19, Issue 7
Abstract
This study presents a novel three-dimensional (3D) analytical solution to the Richards equation, which takes as a basis a linear unsaturated model that was previously proposed. Specifically, the partial differential equation governing the transient, unsaturated flow phenomenon could be solved when using specific constitutive hydraulic functions that linearize the problem. The new 3D analytical solution could also be simplified to two-dimensional (2D) and one-dimensional (1D) analytical solutions, which make possible the evaluation of water flow using the constraints relevant for field and experimental settings. Two general cases of transient moisture movement are simulated using the new analytical solutions. The first case involves a wetting process, in which the flow within the soil mass is triggered by the initial presence of a specific region within the domain that had been subjected to an increased volumetric water content (e.g., because of precipitation or irrigation). In this case, water flows under unsaturated conditions from the region of increased moisture to the surrounding soil mass. The second case involves the recovery of an unconfined soil mass (e.g., an aquifer) within which a limited region had been subjected to a decreased volumetric water content (e.g., because of a localized drying process). In this case, water flow occurs from the soil mass into the region characterized by an initially low moisture content. The solutions presented in the study can be implemented to address a broad range of applications, providing insight into the complex phenomenon of soil wetting and drying. In particular, the solutions highlight the relative impact of the advective and diffusive components of unsaturated flow processes in multidimensional transient problems.
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Acknowledgments
The authors acknowledge the support provided by the following institutions: the National Council for Scientific and Technological Development (CNPq Grant 304721/2017-4), the Support Research of the Federal District Foundation (FAP-DF Grants 0193.001563/2017 and 0193.002014/2017-68), the Coordination for the Improvement of Higher Level Personnel (CAPES), the National Science Foundation (CMMI Grant 1335456), the University of Brasilia, and the University of Texas at Austin for funding this research.
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© 2019 American Society of Civil Engineers.
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Received: May 14, 2018
Accepted: Jan 29, 2019
Published online: May 9, 2019
Published in print: Jul 1, 2019
Discussion open until: Oct 9, 2019
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