Tracing lateral subsurface flow in layered soils by undisturbed monolith sampling, targeted laboratory experiments, and model‐based analysis

Ehrhardt, Annelie; Berger, Kristian; Filipović, Vilim; Wöhling, Thomas; Vogel, Hans‐Jörg; Gerke, Horst

Title: Tracing lateral subsurface flow in layered soils by undisturbed monolith sampling, targeted laboratory experiments, and model‐based analysis
Creator: Ehrhardt, Annelie; Berger, Kristian; Filipović, Vilim; Wöhling, Thomas; Vogel, Hans‐Jörg; Gerke, Horst
Date: 2022
Type: Text; Journal article
Identifier: http://researchonline.federation.edu.au/vital/access/HandleResolver/1959.17/188914
Identifier: vital:17335
Identifier: https://doi.org/10.1002/vzj2.20206
Identifier: ISSN:1539-1663
Abstract: Lateral subsurface flow (LSF) is a phenomenon frequently occurring in the field induced by local water saturation along horizon boundaries under nonequilibrium conditions. However, observations of LSF in undisturbed soils under controlled irrigation in the laboratory are limited but needed for model improvement, prediction, and quantification of LSF. We present a method for extracting an undisturbed soil monolith along a soil horizon boundary and introduce an experimental setup for the measurement of LSF and an irrigation device for simulating rainfall. An experimental test run was simulated using HYDRUS 2D. Water infiltrating into the monolith and flowing either laterally along the horizon boundary or vertically through the bottom horizon could be separately captured by suction discs at the side and the bottom. Thus, a clear distinction between lateral and vertical flow was possible. Pressure heads and water contents were recorded by tensiometers and frequency domain reflectometry (FDR) sensors distributed across the monolith in a regular two‐dimensional, vertical, cross‐sectional pattern. Sensor readings indicated the presence of nonequilibrium conditions within the monolith. Modeling results could reproduce the lateral and vertical outflow of the monolith under constant irrigation, thus showing that water flow within the monolith under steady‐state conditions can be explained by the Richards equation and the van Genuchten–Mualem model. The presented method can be used to improve and verify models designed for the prediction of the onset of LSF including that induced by local nonequilibrium conditions. Core Ideas A Laboratory method to induce and quantify lateral subsurface flow (LSF) is presented. The experimental setup is verified by modeling with HYDRUS 2D. Sampling of rectangular soil monoliths for 2D flow experiments is improved. Lateral subsurface flow and hydraulic nonequilibrium conditions are observed. The experimental data allow for improving models on the onset of LSF.
Publisher: Madison: John Wiley & Sons, Inc
Relation: Vadose zone journal Vol. 21, no. 4 (2022), p. n/a
Rights: All metadata describing materials held in, or linked to, the repository is freely available under a CC0 licence
Rights: http://creativecommons.org/licenses/by/4.0/
Rights: Copyright Authors
Rights: Open Access
Subject: Experiments; Hydraulics; Irrigation; Irrigation water; Laboratories; Laboratory experimentation; Layered soils; Loam soils; Nonequilibrium conditions; Outflow; Pressure head; Rainfall; Runoff; Saturation; Soil; Soil erosion; Soil layers; Storm seepage; Tensometers; Vertical flow; Vertical mixing; Water flow; 3707 Hydrology; 4106 Soil sciences
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