Studies on Stability Constants of Europium(III) Carbonate Complexes and Application of SIT and Ion-Pairing Models

Rao, R. R.; Chatt, A.

doi:10.1524/ract.1991.54.4.181

Cited by 24 publications

(19 citation statements)

References 16 publications

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“…We compare our REE(III)-carbonate complexation constants with the previously reported data obtained by solvent-extraction methods. We cite Eu(III)-carbonate complexation constant data from Lundqvist (1982), Rao and Chatt (1991), Lee and Byrne (1992) and Liu and Byrne (1998) in Table 3. Our results and the literature values were re-calculated at infinite dilution by using the following equations: log log log log log , Activity coefficients for the literature data obtained by using NaClO 4 solutions were calculated according to Millero (1992).…”

Section: Ree(iii)-carbonate Complexation Constants By Fe Coprecipitatmentioning

confidence: 99%

“…Our results and the literature values were re-calculated at infinite dilution by using the following equations: log log log log log , Activity coefficients for the literature data obtained by using NaClO 4 solutions were calculated according to Millero (1992). Rao and Chatt (1991), Lee and Byrne (1992) and Liu and Byrne (1998) reported their REE(III)-carbonate complexation constants by using total CO 3 2-(aq) concentration ([CO 3 2-, aq ] + [NaCO 3 -, aq ]). According to Millero and Schreiber (1982), activity coefficients of total CO 3 2-(aq) are calculated from the following equation;…”

Section: Ree(iii)-carbonate Complexation Constants By Fe Coprecipitatmentioning

confidence: 99%

“…where γ T and γ F denote total and free activity co- Rao and Chatt (1991) and 0.457 according to Lee and Byrne (1992). We estimated γ Eu 3+ in our 0.5 M NaCl solution from Pitzer et al (1978) and Millero and Schreiber (1982), and γ CO 3 2− from Millero (1992).…”

Section: Ree(iii)-carbonate Complexation Constants By Fe Coprecipitatmentioning

confidence: 99%

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Rare earth element partitioning between Fe oxyhydroxide precipitates and aqueous NaCl solutions doped with NaHCO3: Determinations of rare earth element complexation constants with carbonate ions.

Ohta

Kawabe

2000

Geochem. J.

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The distribution coefficients of rare earth elements (REEs; all lanthanides except Pm, Y and Sc) between Fe oxyhydroxide precipitates and 0.5 M NaCl solutions with NaHCO 3 (0.0~12.0 mM) at 25°C and 1 bar have been determined. This experimental system is a simple model for REE partitioning between deep-sea ferromanganese nodules and seawater. The distribution coefficients, K d (REE: precipitate/solution), show systematic variations with increasing NaHCO 3 concentrations. We have determined REE(III)-carbonate complexation constants from the experimental distribution coefficients as a function of NaHCO 3 concentration and pH. The REE(III)-carbonate complexation constants show almost the same series variations as reported values obtained by the solvent-extraction method, although our results by the precipitation method are rather higher by 1.0~1.5 in log unit than the literature data at zero ionic strength. amine how REE(III)-carbonate complexation affects the REE partitioning process in seawater. Kawabe et al. (1999a, b) reported preliminary experimental results of REE partitioning between Fe oxyhydroxide precipitates and NaCl solutions with and without carbonate ions. They emphasized that the lanthanide tetrad effect is associated with the distribution coefficients of REEs between Fe oxyhydroxide precipitates and NaCl solutions. They analyzed their experimental results using the refined spin-pairing energy theory, RSPET, (Jørgensen, 1979;Kawabe, 1992). Although Kawabe et al. (1999b) estimated the complexation constants for REE(CO 3 ) 2 -from their experimental results, they could not estimate those for REECO 3 + from the preliminary data. REE(III)-carbonate complexation constants have been reported by Byrne and co-workers (Cantrell and

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Section: Ree(iii)-carbonate Complexation Constants By Fe Coprecipitatmentioning

confidence: 99%

Section: Ree(iii)-carbonate Complexation Constants By Fe Coprecipitatmentioning

confidence: 99%

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Rare earth element partitioning between Fe oxyhydroxide precipitates and aqueous NaCl solutions doped with NaHCO3: Determinations of rare earth element complexation constants with carbonate ions.

Ohta

Kawabe

2000

Geochem. J.

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“…Although, to our knowledge, the tetracarbonato complexe has not yet been confirmed for trivalent actinides, its formation is reported for trivalent lanthanides [24][25][26], Phase equilibrium experiments at constant ionic strength in Na 2 C0 3 -NaHC0 3 -NaC10 4 solutions (pH range 8-10), e.g. solubility experiments with Ce(III) [24] and solvent extraction with Eu(III) [25,26], are interpreted assuming the formation of a tetracarbonato complex as the limiting Ln(III) carbonate complex (Ln = lanthanide). Since the experimental data do not depend on pH, but only on the C0 3~ concentration, the formation of mixed hydroxo-carbonato complexes is considered negligible.…”

Section: Spectroscopic Characteristicsmentioning

confidence: 99%

Thermodynamics of Cm(III) in Concentrated Electrolyte Solutions. Carbonate Complexation at Constant Ionic Strength (1 m NaCl)

et al. 1998

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Curium / Actinides / Carbonate complexation / Fluorescence spectroscopy SummaryThe carbonate complexation of Cm(III) is investigated by means of time resolved laser fluorescence spectroscopy (TRLFS) at 25°C in 1 m NaCl as a function of the carbonate concentration. In the first set of experiments, the carbonate concentration is controlled by the C0 2 equilibrium partial pressure, (pC0 2 = 10-1000 mbar) and pH whereas the second set of batch experiments is performed at higher carbonate concentrations ([CO §~] > 10 4 molal). Both data sets overlap in the intermediate range and fit well together. The carbonate complexes CmCOJ, Cm(C0 3 ) 2 and Cm(C0 3 ) 3~ are quantified spectroscopically in the trace concentration range by peak deconvolution of fluorescence emission spectra. At pC0 2 = 500 or 1000 mbar and pH < 6.5, there is evidence for the formation of a Cm(III) bicarbonate complex to a small extent. Up to pH 9.5 there is no indication for the formation of mixed hydroxo carbonate complexes. At high carbonate concentrations (> 0.1 molal), the formation of an additional complex, Cm(C0 3 )4~, is indicated. The stability constants determined in 1 molal NaCl solution are found to be: logy?(CmHCO! + ) = 1.9; logy?(CmC0 3 + ) = 5.90; log0(Cm(CO 3 ) 2 ) = 10.27; log^(Cm(C0 3 )D = 13.18; log/? (Cm(C0 3 )D = 14.18.

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“…However, the stoichiometry of the aqueous carbonate limiting complex (complex with maximum number of ligands) of lanthanides (Ln) and actinides (An) is still discussed, even after the well-accepted Nuclear Energy Agency review of Am published thermochemical data [1,2]. Indeed, two stoichiometries have been reported for their limiting complexes: MðCO 3 Þ 3À 3 [3][4][5][6][7][8][9] and MðCO 3 Þ 5À 4 [3,[9][10][11][12][13][14][15][16]. The latter stoichiometry has been reported for light lanthanides only, since the lanthanides heavier than Tb had never been evidenced as MðCO 3 Þ 5À 4 complexes.…”

Section: Introductionmentioning

confidence: 99%

Evidence of different stoichiometries for the limiting carbonate complexes across the lanthanide(III) series: A capillary electrophoresis‐mass spectrometry study

et al. 2008

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The electrophoretic mobilities (mu ep,Ln) of twelve lanthanides (not Ce, Pr and Yb) were measured by CE-ICP-MS in 0.15 and 0.5 mol L(-1) Alk2 CO3 aqueous solutions for Alk+ = Li+, Na+, K+ and Cs+. In 0.5 mol L(-1) solutions, two different mu ep,Ln values were found for the light (La to Nd) and the heavy (Dy to Tm) lanthanides, which suggests two different stoichiometries for the carbonate limiting complexes. These results are consistent with a solubility study that attests the Ln(CO3)3(3-) and Ln(CO3)4(5-) stoichiometries for the heavy (small) and the light (big) lanthanides, respectively. The Alk+ counterions influence the mu ep,Ln Alk2 CO3 values, but not the overall shape of the mu ep,Ln Alk2 CO3 plots as a function of the lanthanide atomic numbers: the counterions do not modify the stoichiometries of the inner sphere complexes. The influence of the Alk+ counterions decreases in the Li+ > Na+ >> K+ > Cs+ series. The K3,Ln stepwise formation constants of the Ln(CO3)3(3-) complexes slightly increase with the atomic numbers of the lanthanides while K4,Ln, the stepwise formation constants of Ln(CO3)4(5-) complexes, slightly decrease from La to Tb, and is no longer measurable for heavier lanthanides.

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Studies on Stability Constants of Europium(III) Carbonate Complexes and Application of SIT and Ion-Pairing Models

Cited by 24 publications

References 16 publications

Rare earth element partitioning between Fe oxyhydroxide precipitates and aqueous NaCl solutions doped with NaHCO3: Determinations of rare earth element complexation constants with carbonate ions.

Rare earth element partitioning between Fe oxyhydroxide precipitates and aqueous NaCl solutions doped with NaHCO3: Determinations of rare earth element complexation constants with carbonate ions.

Thermodynamics of Cm(III) in Concentrated Electrolyte Solutions. Carbonate Complexation at Constant Ionic Strength (1 m NaCl)

Evidence of different stoichiometries for the limiting carbonate complexes across the lanthanide(III) series: A capillary electrophoresis‐mass spectrometry study

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