Monitoring of Water and Solute Transport in the Vadose Zone: A Review

Singh, Gurbir; Kaur, Gurpreet; Williard, Karl W. J.; Schoonover, Jon E.; Kang, J. S.

doi:10.2136/vzj2016.07.0058

Cited by 68 publications

(57 citation statements)

References 385 publications

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“…Currently, the application of our approach is not suitable for soils prone to preferential flow (i.e., macroporous soils and soils with strong structural heterogeneities) because the preferential flow is likely to bypass the suction cup (Grossmann and Udluft, 1991) or the soil moisture sensor and hence the flow field will not be captured. An alternative would be to use sampling devices with a larger cross‐sectional sampling area, such as porous suction plates (Ciglasch et al, 2005; Singh et al, 2017; Weihermüller et al, 2007), instead of suction cups and to increase the number of soil moisture sensors.…”

Section: Resultsmentioning

confidence: 99%

“…In situ soil water sampling from the vadose zone can be grouped into active or passive sampling systems (Singh et al, 2017; Weihermüller et al, 2007). Passive sample systems, such as pan or zero‐tension lysimeters, have the drawback that zero‐tension lower boundary conditions cause a small saturated zone above the lower boundary and hence influence soil water fluxes and solute concentrations (Flury et al, 1999).…”

mentioning

confidence: 99%

“…Passive sample systems, such as pan or zero‐tension lysimeters, have the drawback that zero‐tension lower boundary conditions cause a small saturated zone above the lower boundary and hence influence soil water fluxes and solute concentrations (Flury et al, 1999). Active soil sampling devices, such as suction cups, suction plates, a rhizon sampler, or a wick lysimeter need a hanging water column or a vacuum to extract soil water (Singh et al, 2017; Weihermüller et al, 2007). All vacuum‐controlled methods could operate in continuous/discontinuous or variable pressure modes possibly regulated by soil water tension.…”

mentioning

confidence: 99%

“…A possibility to ensure soil water sampling of defined pore origin would be a continuous pressure application of a fixed vacuum to restrict sampling to the desired matrix potential. However, drawbacks of this operation mode are the risk to receive composite samples of more than one infiltration event if the samples cannot be collected in short time and the fact that continuous pressure application might initiate preferential flow paths in the surrounding substrate (Singh et al, 2017; Weihermüller et al, 2007). Moreover, Weihermüller et al (2007) concluded that it seems difficult or maybe even impossible to derive soil water samples unbiased by the sampling procedure and stated that each sample only temporally represents the sample location.…”

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confidence: 99%

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Advanced In Situ Soil Water Sampling System for Monitoring Solute Fluxes in the Vadose Zone

Reck¹,

Paton²,

Kluge³

2019

Vadose Zone Journal

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Core Ideas The monitoring system synchronizes soil water extraction with real drainage periods. It is remote controllable and has SMS notification in case of automated sampling initiation. It is easy to duplicate using commonly available measuring equipment. The system can monitor field soil solute fluxes, such as contaminant migration. To estimate potential risks of groundwater contamination, national and international environmental legislation stipulates standard values referred to pollutant contents in the soil and more rarely referred to loads in the soil leachate. Although in situ soil leachate analysis yields more realistic drainage water quality estimates than soil contamination level–derived estimates, there is no existing standard for how to explicitly sample soil leachate for the required contaminant migration detection. The objective of this study was to overcome current limitations of soil seepage sampling for detecting a contaminant migration in the unsaturated zone by introducing a technical solution that automatically restricts soil water extraction to drainage periods using active devices such as suction cups. Sampling is triggered by a moisture threshold parameterized according to the respective soil water retention properties defining the onset of a drainage period. We tested our sampling approach on two different bioretention systems in Germany for stormwater drainage quality analysis out of the upper soil layer. We present the monitoring results of the 4‐mo testing phase containing 19 individual storm events illustrating the fundamental functioning of the in situ soil leachate sampling system under different climatic conditions. The results clearly demonstrate the feasibility of restricting soil water extraction to drainage periods by means of actual soil moisture measures and indicate a general transferability of our approach. Our approach is easily duplicable, based on the included technical description, for further studies requiring explicit soil leachate sampling and is likely to help improve the reliability of field‐monitored pollutant migration from contaminated sites.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Advanced In Situ Soil Water Sampling System for Monitoring Solute Fluxes in the Vadose Zone

Reck¹,

Paton²,

Kluge³

2019

Vadose Zone Journal

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“…For example, agricultural operations now depend on a broad range of chemicals in plant and animal production such as fertilizers, pesticides, hormones, pharmaceuticals, pathogenic microorganisms, or fumigants, which have made agriculture one of the most important sources for non-point source pollution [1]. Examples of environmental problems resulting from non-agricultural activities are the disposal of brine/saline waters produced during extraction of coalbed or shale gas [2], releases from municipal or industrial landfills [3], acid mine drainage [4], contamination from nuclear activities [5,6], the formation of redox zones in organic-contaminated aquifers [7], and pollutant release from reactive permeable barriers used for aquifer remediation [8,9]).…”

Section: Introductionmentioning

confidence: 99%

Simulating the Fate and Transport of Coal Seam Gas Chemicals in Variably-Saturated Soils Using HYDRUS

Mallants

Šimůnek

Genuchten

et al. 2017

Water

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Abstract:The HYDRUS-1D and HYDRUS (2D/3D) computer software packages are widely used finite element models for simulating the one-, and two-or three-dimensional movement of water, heat, and multiple solutes in variably-saturated media, respectively. While the standard HYDRUS models consider only the fate and transport of individual solutes or solutes subject to first-order degradation reactions, several specialized HYDRUS add-on modules can simulate far more complex biogeochemical processes. The objective of this paper is to provide a brief overview of the HYDRUS models and their add-on modules, and to demonstrate possible applications of the software to the subsurface fate and transport of chemicals involved in coal seam gas extraction and water management operations. One application uses the standard HYDRUS model to evaluate the natural soil attenuation potential of hydraulic fracturing chemicals and their transformation products in case of an accidental release. By coupling the processes of retardation, first-order degradation and convective-dispersive transport of the biocide bronopol and its degradation products, we demonstrated how natural attenuation reduces initial concentrations by more than a factor of hundred in the top 5 cm of the soil. A second application uses the UnsatChem module to explore the possible use of coal seam gas produced water for sustainable irrigation. Simulations with different irrigation waters (untreated, amended with surface water, and reverse osmosis treated) provided detailed results regarding chemical indicators of soil and plant health, notably SAR, EC and sodium concentrations. A third application uses the HP1 module to analyze trace metal transport involving cation exchange and surface complexation sorption reactions in a soil leached with coal seam gas produced water following some accidental water release scenario. Results show that the main process responsible for trace metal migration in soil is complexation of naturally present trace metals with inorganic ligands such as (bi)carbonate that enter the soil upon infiltration with alkaline produced water. The examples were selected to show how users can tailor the required model complexity to specific needs, such as for rapid screening or risk assessments of various chemicals nder generic soil conditions, or for more detailed site-specific analyses of actual subsurface pollution problems.

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Detangling ecosystem services: Open‐field manipulation of soil‐dwelling microarthropods provides new opportunities to investigate their effects on nitrogen cycling

Gergócs

Flórián

Tóth

et al. 2022

Ecology and Evolution

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1. Soil microarthropods have a pivotal role in soil nitrogen cycling in that they affect microbial decomposers. A high abundance of microarthropods may increase the mobility of inorganic nitrogen ions in the soil, mainly in nitrogen-limited habitats. However, it is difficult to study ecological processes with small-sized, soil-4.06 ± 0.93 3.52 ± 0.34 2.70 ± 0.76 4.30 ± 0.59Abbreviation: SIR, substrate-induced respiration.

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Monitoring of Water and Solute Transport in the Vadose Zone: A Review

Cited by 68 publications

References 385 publications

Advanced In Situ Soil Water Sampling System for Monitoring Solute Fluxes in the Vadose Zone

Advanced In Situ Soil Water Sampling System for Monitoring Solute Fluxes in the Vadose Zone

Simulating the Fate and Transport of Coal Seam Gas Chemicals in Variably-Saturated Soils Using HYDRUS

Detangling ecosystem services: Open‐field manipulation of soil‐dwelling microarthropods provides new opportunities to investigate their effects on nitrogen cycling

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