Determination of Metal-Chelate Complex Solubilities in Supercritical Carbon Dioxide

Cross, William; Akgerman, Aydin; Erkey, Can

doi:10.1021/ie950515c

Cited by 83 publications

(63 citation statements)

References 8 publications

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“…Cross et al [20] correlated the solubilities of copper(II) acetylacetonate (Cu(acac) 2 ) in scCO 2 using the Peng-Robinson equation of state, and the correlated results were in good agreement with the experimental data by fitting the critical temperature and pressure of Cu(acac) 2 as well as the binary interaction parameter, k ij , to the experimental data. Lagalante et al [16] used the regular solution theory of Hildebrand et al [21] to predict the solubilities of chromium(III) acetylacetonate (Cr(acac) 3 ).…”

Section: Introductionmentioning

confidence: 89%

Solubility of β-diketonate complexes for cobalt(III) and chromium(III) in supercritical carbon dioxide

Haruki

Kobayashi

Okamoto

et al. 2010

Fluid Phase Equilibria

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Section: Introductionmentioning

confidence: 89%

Solubility of β-diketonate complexes for cobalt(III) and chromium(III) in supercritical carbon dioxide

Haruki

Kobayashi

Okamoto

et al. 2010

Fluid Phase Equilibria

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“…Therefore, the critical properties must be estimated using a prediction method, such as the group contribution method, or they must be treated as adjustable parameters. Cross et al [8] correlated the solubility data of copper(II) acetylacetonate (Cu(acac) 2 ) in scCO 2 with a conventional mixing rule. The calculated results reproduced the experimental solubility data due to simultaneous determination of the critical temperature and pressure of Cu(acac) 2 , as well as the binary interaction parameter, k ij , by fitting the solubility data.…”

Section: Introductionmentioning

confidence: 99%

Measurement of the solubility of metal complexes in supercritical carbon dioxide using a UV–vis spectrometer

Haruki

Kobayashi

Kishimoto

et al. 2009

Fluid Phase Equilibria

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“…Several models have been proposed to predict and quantitatively explain solubility behavior of solutes in supercritical fluids. These models are based on Hildebrand solubility parameter or Peng-Robinson equation of state [16,17]. These models require a prior knowledge of thermodynamic properties of the solute.…”

Section: Theoretical Aspects Of Uranium Sfementioning

confidence: 99%

Study of effects of different parameters on supercritical fluid extraction of uranium from acidic solutions employing TBP as co-solvent

Rao

Kumar²,

Ramakumar

2008

Radiochimica Acta

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Uranium / Supercritical carbon dioxide / Pressure / Temperature / TBPSummary. In the supercritical fluid extraction of uranium from acidic medium employing TBP as co-solvent, effects of various parameters on extraction efficiency were studied. Variation in pressure (80-300 atm), temperature (308-353 K), CO 2 flow rate (0.5-3 mL/min), co-solvent percentage (1-10%), molarity of nitric acid (0.5-10 M) were found to influence uranium extraction efficiency. The uranium extraction efficiency depends on distribution ratio and kinetics of transport of U-TBP complex into supercritical CO 2 . In the 150-300 atm pressure range, variation in extraction efficiency was similar to that of uranium distribution ratio under equilibrium conditions. Whereas below 150 atm, it closely followed supercritical CO 2 density variation which could be attributed to non-equilibrium behavior that eventually attained equilibrium. In the non-equilibrium region, increased supercritical CO 2 density with pressure favored enhancement in solubility as well as extraction kinetics of the U-TBP complex. Increase in temperature generally resulted in enhanced volatility of U-TBP complex and a decrease in supercritical CO 2 density which in turn affected the extraction efficiency. Up to 333 K temperature, extraction efficiency gradually increased due to enhancement in volatility of U-TBP complex which more than compensates for decrease in the supercritical CO 2 density. Beyond this temperature, the steep fall in the extraction efficiency is attributed to combined effect of saturation in volatility of the U-TBP complex and significant decrease in the density of supercritical CO 2 approaching the critical value at which supercritical CO 2 tends to form large clusters thereby resulting in steep decrease in its solvating power. Extraction efficiency was found to increase with nitric acid molarity up to 7 M and afterwards showed small decrease possibly due to competitive co-extraction of HNO 3 . Up to CO 2 flow rate of 1 mL/min increase in extraction efficiency was observed which attained saturation afterwards. Linear increase in extraction efficiency was observed with the amount of TBP. Extraction efficiency was found to increase linearly with logarithm of extraction time. Under optimised conditions (150 atm, 333 K, 1 mL/min CO 2 flowrate, 10% co-solvent, 7 M nitric acid and 30 min dynamic extraction time) extraction efficiency was found to be (98 ± 2) %. Also, (100 ± 1) % mass balance was observed. 30 min dynamic extraction mode was found *Author for correspondence (E-mail: pradeep_barc@yahoo.com). equivalent to 40 min static mode. Online complexation mode was more efficient than in situ mode.

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Determination of Metal-Chelate Complex Solubilities in Supercritical Carbon Dioxide

Cited by 83 publications

References 8 publications

Solubility of β-diketonate complexes for cobalt(III) and chromium(III) in supercritical carbon dioxide

Solubility of β-diketonate complexes for cobalt(III) and chromium(III) in supercritical carbon dioxide

Measurement of the solubility of metal complexes in supercritical carbon dioxide using a UV–vis spectrometer

Study of effects of different parameters on supercritical fluid extraction of uranium from acidic solutions employing TBP as co-solvent

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