4.6 Article

Study on Spatiotemporal Transport Characteristics of Soil Moisture in Layered Heterogeneous Vadose Zone Based on HYDRAS-3D

Journal

WATER
Volume 15, Issue 20, Pages -

Publisher

MDPI
DOI: 10.3390/w15203550

Keywords

layered heterogeneity; soil water movement in the vadose zone; soil water potential; HYDRAS-3D; numerical simulation

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This paper studies the law of soil water transport in the vadose zone under heterogeneous media conditions, especially the three-dimensional transport mechanism. By constructing a three-dimensional model of water transport and analyzing the vertical distribution and variability of soil water content, it is found that the heterogeneity of layered soils has a significant impact on water transport. The research results can provide scientific reference for the rational planning of water resources in the Yinchuan Plain.
The heterogeneity of layered soils affects the transport processes of water in the vadose zone. However, the mechanism of soil moisture transport in the vadose zone under heterogeneous media conditions, especially the three-dimensional transport mechanism, is a frontier problem to be studied. In order to reveal the law of soil water transport in the vadose zone under heterogeneous media, this paper constructs a three-dimensional model of water transport using HYDRAS-3D (V 2.x) software through in situ tests of water transport in 3 x 3 x 4 m sample and verifies and analyzes the model. The vertical distribution and variability of soil water content and the temporal and spatial rules of soil water transversal transport at the soil-layer interface were analyzed. The results indicate that after adjusting the parameters in the HYDRAS-3D model using measured values, the simulation results are reasonable, and the model has high reliability. To represent the water content variability characteristics of the test tube profile, water movement in the vadose zone was classified as follows: (I) steady period (April-September, less affected by rainfall), (II) slow change period (January-March), and (III) rainfall rapid change period (June, when the impact of rainfall on the test cylinder was greater). The two largest values of the soil water potential variation gradient, 19.9 and 17.8 cm/d, were observed in the silty clay layer of the test cylinder, and the influence of evaporation and infiltration in the silty clay layer was most notable at the interface. The lateral transport of soil water at the interface was influenced to a certain degree by the layered heterogeneity, wherein the fine sand layer exhibited the most pronounced impact. This was followed by silt and silty clay layers, with the silt layer showing the lowest degree of influence. The research results can provide scientific reference for the rational planning of water resources in the Yinchuan Plain.

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