Applying HYDRUS to Flow in a Sodic Clay Soil with Solution Composition–Dependent Hydraulic Conductivity

Reading, Lucy; Baumgartl, Thomas; Bristow, Keith L.; Lockington, David

doi:10.2136/vzj2011.0137

Cited by 20 publications

(26 citation statements)

References 38 publications

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“…This may be because CaSO 4 application decreased soil solution pH, increased aggregation stability, and improved the soil hydraulic conductivity properties. The efficiency of Ca 2+ application to improve doi: 10.17221/14/2015-SWR permeability of sodic and saline-sodic soils was demonstrated previously (Suarez et al 1984;Reading et al 2012a). The change of soil K under different treatments with leaching time can be simulated by HYDRUS-1D, which reflects the measured result.…”

Section: Changes In the Physical And Chemical Properties Of The Soil mentioning

confidence: 56%

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Using HYDRUS to simulate the dynamic changes of Ca2+ and Na+ in sodic soils reclaimed by gypsum

Wang¹,

Bai²,

Yang³

2016

Soil & Water Res.

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Wang J., Bai Z., Yang P. (2016): Using HYDRUS to simulate the dynamic changes of Ca 2+ and Na + in sodic soils reclaimed by gypsum. Soil & Water Res., 11: 1-10.Sodic soils are characterized by the occurrence of excess sodium to levels that can adversely affect soil structure.In recent years, with the advent of alternatives for reclaiming sodic soils, such as the addition of by-products of flue gas desulfurization, fly ash, phosphogypsum, etc., using CaSO 4 to reclaim sodic soil has again become a hot topic. In this study, cation exchange batch experiments and column leaching experiments were conducted to analyze the adsorption-exchange and dynamic changes of Ca 2+ and Na + during the reclamation of sodic soils with CaSO 4 . The HYDRUS-1D software was subsequently used to simulate and predict dynamic changes in Ca 2+ and Na + . The cation exchange batch experiments consisted of six treatments with six CaSO 4 rates (0, 0.25, 0.5, 1, 1.5, and 2 g/l), and the column leaching experiments consisted of two treatments with two CaSO 4 concentrations (0.5 and 1.5 g/l). The results of the static cation exchange batch experiments indicated that the ion adsorption-exchange coefficients K Ca-Na , K Ca-Mg , and K Ca-K were 1.9, 0.8, and 1.1, respectively. Applying CaSO 4 and leaching are efficient methods to reclaim sodic soil. The pH and electrical conductivity of the soil solution gradually decreased with longer leaching time in all of the treatments. HYDRUS-1D successfully simulated both the dynamic changes of the Ca 2+ and Na + concentrations at different soil depths under different treatments and leaching time, and the effects of soil hydraulic conductivity and soil pH on the transport of Ca 2+ and Na + . The correspondence between the observed and simulated variables was remarkable.

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Section: Changes In the Physical And Chemical Properties Of The Soil mentioning

confidence: 56%

“…The UNSATCHEM model has recently been incorporated in the HYDRUS-1D software package (Simunek et al 2008. The HYDRUS-1D software may be used to analyze the movements of water and solute in unsaturated, partially saturated, or fully saturated homogeneous layered media (Simunek et al 2008;Reading et al 2012a).…”

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confidence: 99%

Using HYDRUS to simulate the dynamic changes of Ca2+ and Na+ in sodic soils reclaimed by gypsum

Wang¹,

Bai²,

Yang³

2016

Soil & Water Res.

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“…Reading et al (2012a) used reactive transport modeling to address issues associated with irrigation and management of sodic soils, where chemical ameliorants are often used to improve infiltration and hydraulic conductivity and enhance the leaching of excess salts from the root zone. Describing such a system requires a model that accommodates solute transport and the requisite chemical reactions (i.e., cation exchange and mineral dissolution/precipitation).…”

Section: Summary Of Contributionsmentioning

confidence: 99%

“…Describing such a system requires a model that accommodates solute transport and the requisite chemical reactions (i.e., cation exchange and mineral dissolution/precipitation). As Reading et al (2012a) noted, however, the model must also describe physical changes in soil properties that accompany changes in soil chemistry; more specifically, changes in hydraulic conductivity that occur when sodium dominates the cation exchange complex. While several available models can be used to describe such basic chemical reactions, only UNSATCHEM and HYDRUS‐1D can address changes in hydraulic conductivity associated with shifts in soil chemistry (Šimůnek et al, 1996, 2008).…”

Section: Summary Of Contributionsmentioning

confidence: 99%

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Reactive Transport Modeling

Seaman

Chang

Goldberg

et al. 2012

Vadose Zone Journal

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This special sec on in the Vadose Zone Journal focusing on reac ve transport modeling was developed from a special symposium jointly sponsored by the Soil Physics and Soil Chemistry Divisions of the Soil Science Society of America at the 2010 annual mee ngs held in Long Beach, CA. It contains eight contribu ons refl ec ng a diverse range of reac ve transport modeling applica ons that address the fate and transport of both reac ve solutes and colloidal material (i.e., viruses). Further, the eight studies range in scale from laboratory batch and column experiments to the regional scale. Three of the submissions refl ect eff orts to model experimental data that were already reported in the literature, providing addi onal insight concerning underlying physical and chemical processes. In addi on to the obvious predic ve applica ons, the eight contribu ons to this special sec on illustrate the addional advantages to including reac ve transport modeling as an ac ve component within a diverse research agenda. In addi on to scenario tes ng, reac ve transport modeling provides a framework for synthesizing diverse experimental data, evalua ng the rela ve importance of various compe ng and interrelated biogeochemical processes, and iden fying important data gaps and research priori es under more natural condi ons at mul ple temporal and spa al scales.

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Equilibrium Soil Chemistry Submodels

Suarez,

Skaggs

2022

Modeling Processes and Their Interactions in Cropping Systems

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Applying HYDRUS to Flow in a Sodic Clay Soil with Solution Composition–Dependent Hydraulic Conductivity

Cited by 20 publications

References 38 publications

Using HYDRUS to simulate the dynamic changes of Ca<sup>2+</sup> and Na<sup>+</sup> in sodic soils reclaimed by gypsum

Using HYDRUS to simulate the dynamic changes of Ca<sup>2+</sup> and Na<sup>+</sup> in sodic soils reclaimed by gypsum

Reactive Transport Modeling

Equilibrium Soil Chemistry Submodels

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