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

IF 2.5 3区地球科学 Q3 ENVIRONMENTAL SCIENCES

Vadose Zone Journal Pub Date : 2022-06-28 DOI:10.1002/vzj2.20206

Annelie Ehrhardt, Kristian Berger, V. Filipović, T. Wöhling, H. Vogel, H. Gerke

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引用次数: 2

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.

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通过不受干扰的整体取样、有针对性的实验室实验和基于模型的分析来追踪分层土壤中的横向地下流动

侧向潜流（LSF）是在非平衡条件下，由地层边界局部水饱和度引起的场中经常发生的现象。然而，在实验室中对控制灌溉条件下原状土壤中LSF的观测是有限的，但需要对LSF进行模型改进、预测和量化。我们提出了一种沿土层边界提取未扰动土体的方法，并介绍了一个用于测量LSF的实验装置和一个用于模拟降雨的灌溉装置。使用HYDRUS 2D模拟实验测试运行。渗透到整料中并沿着层位边界横向流动或垂直穿过底部层位的水可以分别被侧面和底部的吸盘捕获。因此，可以在横向流和垂直流之间进行明确的区分。通过张力计和频域反射计（FDR）传感器记录压头和含水量，这些传感器以规则的二维、垂直、横截面模式分布在整料上。传感器读数表明整料内存在非平衡条件。建模结果可以再现恒定灌溉条件下整料的横向和垂直流出，从而表明稳定状态下整料内的水流可以用Richards方程和van Genuchten–Mualem模型来解释。所提出的方法可用于改进和验证为预测LSF开始而设计的模型，包括由局部非平衡条件引起的LSF。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Vadose Zone Journal 环境科学-环境科学

CiteScore

5.60

自引率

7.10%

发文量

审稿时长

3.8 months

期刊介绍： Vadose Zone Journal is a unique publication outlet for interdisciplinary research and assessment of the vadose zone, the portion of the Critical Zone that comprises the Earth’s critical living surface down to groundwater. It is a peer-reviewed, international journal publishing reviews, original research, and special sections across a wide range of disciplines. Vadose Zone Journal reports fundamental and applied research from disciplinary and multidisciplinary investigations, including assessment and policy analyses, of the mostly unsaturated zone between the soil surface and the groundwater table. The goal is to disseminate information to facilitate science-based decision-making and sustainable management of the vadose zone. Examples of topic areas suitable for VZJ are variably saturated fluid flow, heat and solute transport in granular and fractured media, flow processes in the capillary fringe at or near the water table, water table management, regional and global climate change impacts on the vadose zone, carbon sequestration, design and performance of waste disposal facilities, long-term stewardship of contaminated sites in the vadose zone, biogeochemical transformation processes, microbial processes in shallow and deep formations, bioremediation, and the fate and transport of radionuclides, inorganic and organic chemicals, colloids, viruses, and microorganisms. Articles in VZJ also address yet-to-be-resolved issues, such as how to quantify heterogeneity of subsurface processes and properties, and how to couple physical, chemical, and biological processes across a range of spatial scales from the molecular to the global.