The experimental determination of hydromagnesite precipitation rates at 22.5–75ºC

Berninger, Ulf-Niklas; Jordan, Guntram; Schott, Jacques; Oelkers, Eric H.

doi:10.1180/minmag.2014.078.6.07

Cited by 21 publications

(34 citation statements)

References 45 publications

(59 reference statements)

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“…This pH increase was due to the consumption of protons by the hydromagnesite dissolution reaction (3); the pH in the other experiments remained closer to constant because the pH of their initial reactive fluids was higher leading to aqueous CO3 2formation in the fluid phase as hydromagnesite dissolved. Chemical equilibrium between the fluid and the hydromagnesite is rapidly attained in all experiments consistent with the results reported by Berninger et al (2014). For example, chemical equilibrium was attained after ~5 hours during experiment Hmgs-1 and after ~2 days during experiment Hmgs-2.…”

Section: Mg Isotope Analysessupporting

confidence: 89%

“…Close matches between calculated and measured reactive fluid concentrations are evident. Although there is some uncertainty in fitting these fast reaction rates, they are consistent with the conclusions of Berninger et al (2014), as precipitation rate constant was found to be substantially smaller than that of the dissolution rate constants.…”

Section: Temporal Variation Of Reactive Fluid Mg Concentration and Itsupporting

confidence: 77%

“…Notably, field observations have shown that passive CO2 storage may occur in ultramafic mine tailings through the weathering of Mg-silicates and precipitation of hydrous Mg-carbonates (Wilson et al, 2009(Wilson et al, , 2014Pronost et al, 2011). Such observations have motivated a number of experimental studies characterizing the formation conditions, reactivity, and thermal stability of the hydrous Mg-carbonates (Hänchen et al, 2008;Frost et al, 2008;Ballirano et al, 2010;Gautier et al, 2014;Berninger et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

Oelkers

Berninger

Perez-Fernandez

et al. 2018

Geochimica et Cosmochimica Acta

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Section: Mg Isotope Analysessupporting

confidence: 89%

Section: Temporal Variation Of Reactive Fluid Mg Concentration and Itsupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

Oelkers

Berninger

Perez-Fernandez

et al. 2018

Geochimica et Cosmochimica Acta

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“…Estimation of the CO 2 storage security of these approaches requires knowledge of the stability, solubility, and formation pathways of the carbonate mineral products that store the CO 2 . The relative stability and solubility of several Mg-carbonates has been investigated (Langmuir, 1965;Canterford et al, 1984;Königsberger et al, 1999;Zhang et al, 2006;Hopkinson et al, 2008Hopkinson et al, , 2012Hänchen et al, 2008;Xiong and Lord, 2008;Bénézeth et al, 2011;Xiong, 2011;Ballirano et al, 2013;Berninger et al, 2014;Kristova et al, 2014;Gautier et al, 2014). In general, the stability of Mg-carbonates increases from more to less hydrated phases, in the order: lansfordite < nesquehonite < dypingite < hydromagnesite < magnesite (Langmuir, 1965;Canterford et al, 1984).…”

Section: Introduction 26 27mentioning

confidence: 99%

Solubility of the hydrated Mg-carbonates nesquehonite and dypingite from 5 to 35 °C: Implications for CO2 storage and the relative stability of Mg-carbonates

et al. 2019

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Hydrated Mg-carbonate minerals form during the weathering of ultramafic rocks, and 2 can be used to sequester atmospheric CO 2 to help combat greenhouse gas-fueled climate change. Optimization of engineered CO 2 sequestration and prediction of the composition and stability of Mg-carbonate phase assemblages in natural and engineered ultramafic environments requires knowledge of the solubility of hydrated Mg-carbonate phases, and the transformation pathways between these metastable phases. In this study, we evaluate the solubility of nesquehonite [MgCO 3 •3H 2 O] and dypingite [Mg 5 (CO 3) 4 (OH) 2 •(5 or 8)H 2 O] and the transformation from nesquehonite to dypingite between 5°C and 35°C, using constanttemperature, batch-reactor experimentals.. The logarithm of the solubility product of nesquehonite was determined to be:-5.03±0.13,-5.27±0.15, and-5.34±0.04 at 5°C, 25°C, and 35°C, respectively. The logarithm of the solubility product of dypingite, never reported before, was determined to be:-34.95±0.58 and-36.04±0.31 at 25°C and 35°C, respectively, with eight waters of hydration. The transformation from nesquehonite to dypingite was temperature-dependent, and was complete within 57 days at 25°C, and 20 days at 35°C, but did not occur during experiments of 59 days at 5°C. This phase transformation appeared to occur via a dissolution-reprecipitation mechanism; external nesquehonite crystal morphology was partially maintained during the phase transformation at 25°C, but was eradicated at 35°C. Together, our results facilitate the improved evaluation of Mg-carbonate mineral precipitation during natural and engineered ultramafic mineral weathering systems that sequester CO , and 20 for the first time allow assessment of the saturation state of dypingite in aqueous solutions. 21

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“…If they are inconsistent with field observations, those laboratory measurements should be considered invalid. To this end, we tested the equilibrium constants of hydromagnesite (5424) suggested by Berninger et al (2014) against field observations to determine if they are consistent with the field observations. This work focuses on hydromagnesite (5424) which for simplicity, is abbreviated as hydromagnesite.…”

Section: Introductionmentioning

confidence: 99%

Comment on “The experimental determination of hydromagnesite precipitation rates at 22.5– 75°C” by Berninger, U.-N., Jordan, G., Schott, J. and Oelkers, E.H.

Xiong

Çetiner

2017

Mineral. mag.

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In this work, we tested the equilibrium constant of hydromagnesite [Mg5(CO3)4(OH)2·4H2O] at 22.5°C proposed by Berninger et al. (2014) against field observations. By field observations we mean that analytical resultsoriginate from samples in the natural environment. In our test, we calculated saturation states of hydromagnesite, using the equilibrium constant of hydromagnesite at 22.5°C from Berninger et al., for the carbonate lakes in Qinghai-Xizang Plateau in China and for Salda Lake in Turkey,based on the hydrochemical data from literature. The predictions based on this equilibrium constant indicate that all of these lakes are strongly under-saturated with respect to hydromagnesite. However, hydromagnesite has been shown to form in all of these lakes. Therefore, this equilibrium constant is clearly in direct contradiction with field observations, leading to the conclusion that the equilibrium constant of hydromagnesite of Berninger et al. (2014) is not suitable for geochemical modelling.

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The experimental determination of hydromagnesite precipitation rates at 22.5–75ºC

Cited by 21 publications

References 45 publications

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

Solubility of the hydrated Mg-carbonates nesquehonite and dypingite from 5 to 35 °C: Implications for CO2 storage and the relative stability of Mg-carbonates

Comment on “The experimental determination of hydromagnesite precipitation rates at 22.5– 75°C” by Berninger, U.-N., Jordan, G., Schott, J. and Oelkers, E.H.

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The experimental determination of hydromagnesite precipitation rates at 22.5–75ºC

Cited by 21 publications

References 45 publications

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

The temporal evolution of magnesium isotope fractionation during hydromagnesite dissolution, precipitation, and at equilibrium

Solubility of the hydrated Mg-carbonates nesquehonite and dypingite from 5 to 35 °C: Implications for CO2 storage and the relative stability of Mg-carbonates

Comment on “The experimental determination of hydromagnesite precipitation rates at 22.5– 75°C” by Berninger, U.-N., Jordan, G., Schott, J. and Oelkers, E.H.

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Solubility of the hydrated Mg-carbonates nesquehonite and dypingite from 5 to 35 °C: Implications for CO2 storage and the relative stability of Mg-carbonates