Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K

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Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K. / Papadimitriou, Stathys; Kennedy, Hilary; Kennedy, David et al.
In: Geochimica et Cosmochimica Acta, Vol. 109, 15.05.2013, p. 241-253.

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Papadimitriou, S, Kennedy, H, Kennedy, D & Thomas, DN 2013, 'Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K', Geochimica et Cosmochimica Acta, vol. 109, pp. 241-253. https://doi.org/10.1016/j.gca.2013.01.044

APA

Papadimitriou, S., Kennedy, H., Kennedy, D., & Thomas, D. N. (2013). Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K. Geochimica et Cosmochimica Acta, 109, 241-253. https://doi.org/10.1016/j.gca.2013.01.044

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Papadimitriou S, Kennedy H, Kennedy D, Thomas DN. Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K. Geochimica et Cosmochimica Acta. 2013 May 15;109:241-253. doi: 10.1016/j.gca.2013.01.044

Author

Papadimitriou, Stathys ; Kennedy, Hilary ; Kennedy, David et al. / Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K. In: Geochimica et Cosmochimica Acta. 2013 ; Vol. 109. pp. 241-253.

RIS

TY - JOUR

T1 - Ikaite solubility in seawater-derived brines at 1 atm and sub-zero temperatures to 265 K

AU - Papadimitriou, Stathys

AU - Kennedy, Hilary

AU - Kennedy, David

AU - Thomas, David N.

PY - 2013/5/15

Y1 - 2013/5/15

N2 - The concentration-based (stoichiometric) equilibrium solubility product of ikaite (CaCO3·6H2O) in seawater and cryogenic seawater-derived brines was determined at 1 atm total pressure over the temperature range from −1.1 to −7.5 °C and the salinity range from 34 to 124 in temperature–salinity pairs representative of sea ice brines. The solubility measurements were obtained in solutions that were undersaturated and supersaturated with respect to ikaite by equilibration with CO2/N2 gas mixtures of known pCO2 (20–400 μatm). The solutions were then equilibrated with synthetic ikaite (seed) for up to 3 months in a closed system. Arrival of the solid–solution system at a long-term chemical equilibrium was indicated by attainment of constant chemical solution composition with respect to total dissolved calcium, total dissolved inorganic carbon, and total alkalinity. Using these measurements, the stoichiometric equilibrium solubility product of ikaite (View the MathML sourceKsp,ikaite∗=[Ca2+][CO32-], in View the MathML sourcemol2kgsolution-2) was determined, with the carbonate ion concentration computed from the measured total alkalinity and total dissolved inorganic carbon concentrations. The computed carbonate ion concentration and, by extension, the View the MathML sourceKsp,ikaite∗ are both contingent on solving the system of equations that describe the parameters of the CO2 system in seawater by extrapolation to the experimental salinity and temperature conditions. The results show that the View the MathML sourcepKsp,ikaite∗=-logKsp,ikaite∗ in seawater of salinity 34 at −1.1 °C was 5.362 ± 0.004 and that the View the MathML sourcepKsp,ikaite∗ in sea ice at the freezing point of brines of salinity greater than 34 can be described as a function of temperature (T , in K) by the equation, View the MathML sourcepKsp,ikaite∗=-15489.09608+623443.70216T-1+2355.14596lnT, in the temperature range of 265.15 K < T < 271.15 K (−8 °C < t < −2 °C). Brines of low pCO2 (20 μatm) yielded a much slower (>1 month) approach to chemical equilibrium when incubated without seeding ikaite crystals. Simple modeling indicated that ikaite should not precipitate from sea ice brines evolving under closed system conditions with respect to CO2 exchange. To facilitate ikaite precipitation, brine pCO2 reduction due to photosynthesis or CO2 degassing, or both, is necessary.

AB - The concentration-based (stoichiometric) equilibrium solubility product of ikaite (CaCO3·6H2O) in seawater and cryogenic seawater-derived brines was determined at 1 atm total pressure over the temperature range from −1.1 to −7.5 °C and the salinity range from 34 to 124 in temperature–salinity pairs representative of sea ice brines. The solubility measurements were obtained in solutions that were undersaturated and supersaturated with respect to ikaite by equilibration with CO2/N2 gas mixtures of known pCO2 (20–400 μatm). The solutions were then equilibrated with synthetic ikaite (seed) for up to 3 months in a closed system. Arrival of the solid–solution system at a long-term chemical equilibrium was indicated by attainment of constant chemical solution composition with respect to total dissolved calcium, total dissolved inorganic carbon, and total alkalinity. Using these measurements, the stoichiometric equilibrium solubility product of ikaite (View the MathML sourceKsp,ikaite∗=[Ca2+][CO32-], in View the MathML sourcemol2kgsolution-2) was determined, with the carbonate ion concentration computed from the measured total alkalinity and total dissolved inorganic carbon concentrations. The computed carbonate ion concentration and, by extension, the View the MathML sourceKsp,ikaite∗ are both contingent on solving the system of equations that describe the parameters of the CO2 system in seawater by extrapolation to the experimental salinity and temperature conditions. The results show that the View the MathML sourcepKsp,ikaite∗=-logKsp,ikaite∗ in seawater of salinity 34 at −1.1 °C was 5.362 ± 0.004 and that the View the MathML sourcepKsp,ikaite∗ in sea ice at the freezing point of brines of salinity greater than 34 can be described as a function of temperature (T , in K) by the equation, View the MathML sourcepKsp,ikaite∗=-15489.09608+623443.70216T-1+2355.14596lnT, in the temperature range of 265.15 K < T < 271.15 K (−8 °C < t < −2 °C). Brines of low pCO2 (20 μatm) yielded a much slower (>1 month) approach to chemical equilibrium when incubated without seeding ikaite crystals. Simple modeling indicated that ikaite should not precipitate from sea ice brines evolving under closed system conditions with respect to CO2 exchange. To facilitate ikaite precipitation, brine pCO2 reduction due to photosynthesis or CO2 degassing, or both, is necessary.

U2 - 10.1016/j.gca.2013.01.044

DO - 10.1016/j.gca.2013.01.044

M3 - Article

VL - 109

SP - 241

EP - 253

JO - Geochimica et Cosmochimica Acta

JF - Geochimica et Cosmochimica Acta

SN - 0016-7037

ER -