Abstract
Water infiltration in soil is a complex process that still requires appreciation of interactions among three phases (soil particles, water and air) to enable accurate estimation of water transport rates. To simulate this process, the Green–Ampt (GA) model and the Modified Green-Ampt (MGA) model introduced in the paper “A new method to estimate soil water infiltration based on a modified Green–Ampt model” have been widely used. The GA model is based on the hypothesis that the advance of the wetting front in soil under matric suction can be treated as a rectangular piston flow that is instantaneously transformed after passage of the infiltration front, and the MGA model does not contain the influence of pore size change. This cannot accurately reflect the soil moisture change process from unsaturation to saturation. Due to soil stratification and other inhomogeneity, predictions produced with these models often differ widely from observations. To quickly obtain the soil moisture distribution after passage of the wetting front for horizontal infiltration, an improved modified Green–Ampt (IMGA) model is presented, which estimates the soil moisture profile along a horizontal column in a piecewise manner with three functions. A logarithmic function is used to describe the gradual soil saturation process in the transmission zone, and two linear functions are used to represent the wetting zone. The algorithm of the IMGA model for estimating the water infiltration rate and cumulative infiltration is configured. To verify the effectiveness of IMGA model, a lab model test was performed, and a numerical model was built to solve the horizontal one-dimensional Richards equation using the finite–element method. The results show that the IMGA model is more accurate than the GA and MGA models. The horizontal soil moisture profiles obtained by the IMGA model are closer to the measured data than the numerical simulation results. The relative errors of the MGA and IMGA models decrease with an increase in infiltration time, whereas that of the GA model first decreases and then increases with infiltration time. The primary novelty of this study is nonlinear description of soil moisture content distribution, and derivation of unit transfer coefficient.
Highlights
The unsaturated zone of the earth’s surface is an important link between the atmosphere and deeper soil profiles
Equations (13)–(15) are the relationships between the infiltration rate and the elapsed times profile function connected with wetting front (WF) in the wetting zone (m3/m3), xbi is advancement distance of the estimated by the improved modified Green–Ampt (IMGA), Modified Green-Ampt (MGA), and GA models, respectively
The horizontal infiltration tests were performed in a polyvinyl chloride (PVC) pipe
Summary
The unsaturated zone of the earth’s surface is an important link between the atmosphere and deeper soil profiles. The results of laboratory experiments performed by Mao et al [35] show that the soil moisture profiles in the TZ do not satisfy Prevedello’s hypothesis They discovered that the moisture in the TZ changes throughout the entire infiltration process, gradually moving from unsaturated to a saturated state. To reflect this gradual change, Mao et al [35] proposed a modified GA model (MGA) that uses two linear functions to piecewise fit the soil moisture profiles during the horizontal infiltration process. The IMGA, MGA, and GA models, the validity of the IMGA model was assessed
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