A simple reactive-transport model of calcite precipitation in soils and other porous media

Kirk, G. J. D.; Versteegen, Audrey; Ritz, Karl; Milodowski, Antoni E.

doi:10.1016/j.gca.2015.05.017

Cited by 17 publications

(4 citation statements)

References 41 publications

(50 reference statements)

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“…Continuing redox reactions in the anoxic soil consume protons (reduction of NO 3 − , Mn(IV), Fe(III), and SO 4 2− ), so the decrease in pH is gradually reversed. There is then a gradual reprecipitation of carbonates, though subject to inhibition by dissolved organic compounds and other factors (e.g., Kirk, Versteegen, Ritz, & Milodowski, ). Calculations with the MINTEQ equilibrium speciation model (Gustafsson, ) show that the soil solution in the unplanted soil was saturated with respect to calcite (CaCO 3 ), magnesite (MgCO 3 ), and dolomite (CaMg[CO 3 ] 2 ) throughout the experiment.…”

Section: Resultsmentioning

confidence: 99%

Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

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Wissuwa

et al. 2017

Plant Cell & Environment

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We sought to explain rice (Oryza sativa) genotype differences in tolerance of zinc (Zn) deficiency in flooded paddy soils and the counter-intuitive observation, made in earlier field experiments, that Zn uptake per plant increases with increasing planting density. We grew tolerant and intolerant genotypes in a Zn-deficient flooded soil at high and low planting densities and found (a) plant Zn concentrations and growth increased with planting density and more so in the tolerant genotype, whereas the concentrations of other nutrients decreased, indicating a specific effect on Zn uptake; (b) the effects of planting density and genotype on Zn uptake could only be explained if the plants induced changes in the soil to make Zn more soluble; and (c) the genotype and planting density effects were both associated with decreases in dissolved CO in the rhizosphere soil solution and resulting increases in pH. We suggest that the increases in pH caused solubilization of soil Zn by dissolution of alkali-soluble, Zn-complexing organic ligands from soil organic matter. We conclude that differences in venting of soil CO through root aerenchyma were responsible for the genotype and planting density effects.

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Section: Resultsmentioning

confidence: 99%

Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Affholder

Weiß

Wissuwa

et al. 2017

Plant Cell & Environment

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“…Another undesired byproduct of the MICP process is the toxic and combustible H 2 S gas released by sulfate-reducing bacteria, which results in many environmental and health issues [194]. However, undesired byproducts can be mitigated by: (1) identifying other strategies or techniques to prevent their generation, (2) using the byproducts for other applications nearby, or (3) adopting treatments to eliminate the byproducts [66].…”

Section: Undesired Byproductsmentioning

confidence: 99%

Review of the use of microorganisms in geotechnical engineering applications

et al. 2020

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Until recently, engineers either ignored or neglected the role of microorganisms in geotechnical engineering. The microbially induced calcite precipitation (MICP) research technique is an innovative and relatively green technology which consists in a biological process through which microorganisms react with minerals (calcium source and cementation reagent) to produce calcite (CaCO 3 ) as a byproduct that modifies and improves the engineering properties of soil. Laboratory and field results obtained from various studies are promising and viable, suggesting potential for various engineering applications. This research technique has also been considered to be useful in many engineering applications such as improvement of construction materials, cementation of porous media, improvement in strength and stiffness of engineering soils, hydraulic control of engineering facilities (waste containment), liquefaction, and erosion mitigation. In this review, the various methods of production of calcium carbonates (calcite), the role played by bacteria, various state-of-the-art procedures that have evolved in this research area, as well as ongoing studies are reported. Furthermore, the use of the MICP technique in remediation of contaminants and other environmental concerns is also presented. The advantages and challenges (in form of undesired byproducts) of this research technique are highlighted herein.

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“…The mass balance of Ca 2+ in the whole soil is then implicit in eqs 11 and 12 and the mass balance of soil acidity. This approach means the problem of defining the correct equations for Ca 2+ diffusion with simultaneous cation exchange on the soil solid is avoided (cf 33 ).…”

Section: +mentioning

confidence: 99%

A Model of Uranium Uptake by Plant Roots Allowing for Root-Induced Changes in the soil

Boghi

Roose

Kirk

2018

Environ. Sci. Technol.

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We develop a model with which to study the poorly understood mechanisms of uranium (U) uptake by plants. The model is based on equations for transport and reaction of U and acids and bases in the rhizosphere around cylindrical plant roots. It allows for the speciation of U with hydroxyl, carbonate, and organic ligands in the soil solution; the nature and kinetics of sorption reactions with the soil solid; and the effects of root-induced changes in rhizosphere pH. A sensitivity analysis showed the importance of soil sorption and speciation parameters as influenced by pH and CO pressure; and of root geometry and root-induced acid-base changes linked to the form of nitrogen taken up by the root. The root absorbing coefficient for U, relating influx to the concentration of U species in solution at the root surface, was also important. Simplified empirical models of U uptake by different plant species and soil types need to account for these effects.

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A simple reactive-transport model of calcite precipitation in soils and other porous media

Cited by 17 publications

References 41 publications

Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Review of the use of microorganisms in geotechnical engineering applications

A Model of Uranium Uptake by Plant Roots Allowing for Root-Induced Changes in the soil

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A simple reactive-transport model of calcite precipitation in soils and other porous media

Cited by 17 publications

References 41 publications

Soil CO2 venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Soil CO2 venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Review of the use of microorganisms in geotechnical engineering applications

A Model of Uranium Uptake by Plant Roots Allowing for Root-Induced Changes in the soil

Contact Info

Product

Resources

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Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils

Soil CO₂ venting as one of the mechanisms for tolerance of Zn deficiency by rice in flooded soils