Electromagnetic Modeling of the Propagation Characteristics of Satellite Communications Through Composite Precipitation Layers Science and Technology, 8 (2003) 107-114 © 2003 Sultan Qaboos University Solvent Extraction of Thorium(IV) by Didodecylphoric Acid Fawwaz I. Khalili, Khaled M. Mousa and Ehsan I. Soudani Department of Chemistry, University of Jordan,Amman- Jordan, Email: f_khalili99@yahoo.com. من محلول بوساطة حامض ثنائي دوديكيل الفسفوريك ) 4(+استخالص الثوريوم فواز الخليلي، خالد موسى و إحسان السوداني المذاب في الكلوروفورم، حامض ثنائي دوديكيل الفسفوريك من محلول بيرآلورات باستعمال ) 4(+تم استخالص الثوريوم :خالصة ى عمليات االستخالص ، ترآيز حامض الهيدروآلوريك،زمن االستخالص ، ترآيز المتصلة و قد درست تأثيرات العوامل التالية عل واستخدمت قيم معامل التوزيع عند درجات . ، درجة الحموضة ، القوة األيونية ، نوع االلكتروليت و اختالف درجات الحرارة عشوائية المصاحبة لعملية االستخالص ، وحددت حرارة مختلفة لحساب التغير في المحتوى الحراري و الطاقة الحرة و درجة ال ) .n 2 أو=1 حيثالمتكونص عند االستخال آذلك صيغة المعقد ) ( )Th CIO R HRn4 5-n4 n− ABSTRACT: Solvent extraction of Thorium (VI) ion from perchlorate solution using didodecylphosphoric acid, DDPA, in chloroform diluent was studied. The effects of stripping hydrochloric acid concentration, stripping time, extraction time, DDPA concentration, pH, ionic strength, supporting electrolyte and temperature on the extraction processes have been studied. From the distribution coefficient values at different temperatures, the enthalpy, the free energy and the entropy changes associated with the extraction processes were determined. The composition of the complex formed was established to be Th(ClO4)4-nRn(HR)5-n where, n=1 or 2 and (HR)2 represents the dimer of DDPA. KEYWORDS: Thorium(IV); Solvent extraction; DDPA; Thermodynamics. 1. Introduction Solvent extraction enjoys a favored position among separation techniques, due to its simplicity, speed and wide scope (Dean, 1969). The distribution coefficient (Kd) of a solute (A) between an organic phase and an aqueous phase is given by [ ] [ ]d org aqK = A / A (1) Generally, dialkylphosphoric acids extract uranium ( )VI ion in non polar diluents by a cation exchange mechanism (Baes et al. 1958; Bunus et al. 1978; Marcus and Kolarik, 1976; Mason et al. 1970; Sato, 1965) according to the following reaction ( ) ( ) aq org 2+ + 2 2 2 aq2 2 UO +2HR UO HR +2H (2) The extraction equilibrium constant is expressed as follows ( ) ( )             2+ 2 2 2 org aq ex 22+ 2 2 orgaq UO HR H K = UO HR 107 mailto:f_khalili99@yahoo.com FAWWAZ I.KHALILI, et al. or ( )      2 2+ ex d 2 orgaq K H / HRK = where ( ) [ ]   2+ d 2 2 2 aqorg K = UO HR / UO 2 It is well known that di(2-ethylhexyl)phosphoric acid, D2EHPA, in many diluents is an effective extractant for actinides from mineral acid solutions (Sato ,1967; Baes,1962; Kiwan and Amin, 1973). Peppard et al. (1957a, b; 1959) have described the application of D2EHPA to the fractionation of the trivalent lanthanides plus yttrium, to the isolation of certain carrier-free radioactive M(IlI) nuclides, to the mutual separation of certain M(III) actinides and to the separation of Ce(IV) from M(III) actinides and lanthanides. Mason et al. (1981) studied the extraction of U(VI) and Th(IV) from an aqueous nitrate phase by bis(2,6-dimethyl-4- heptyl)phosphoric acid, HD(DIBM)P, in n-heptane and benzene diluents. The extraction stiochiometries and the corresponding expression for the extraction equilibrium constants were determined. The equilibrium study of extraction of lanthanide ions with didodecylphosphoric acid, DDPA, was carried out by Kondo et al. (1989). The extracted species into toluene diluent was found to be LnR3.3HR and the extraction equilibrium constants for the three lanthanide ions, that is, samarium(III), europium (III) and gadolinium (III) were obtained. Khaled et al. (1999) studied the extraction of U(VI) from an aqueous perchlorate phase by didodecyl phosphoric acid, (DDPA) in toluene the extracted species was found to be UO2(ClO4)(HR2)(HR)2 where, (HR)2 represents the dimer of DDPA. The optimum conditions for the extraction were studied and the thermodynamic parameters were calculated. This work describes an investigation of the extraction of Thorium(IV) by DDPA from perchlorate solution. 2. Experimental Reagents: The extractant, didodecylphosphoric acid, DDPA, was prepared and purified as described in the literature (Kondo et al. 1989). 0.0 0.2 0.4 0.6 0.8 1.0 0.0 2.0 4.0 6.0 8.0 10.0 12.0 Extraction time (hr) K d Figure 1. Variation of Kd with extraction time at 25 oC. 108 SOLVENT EXTRACTION OF THORIUM(IV) The organic solution was prepared by dissolving DDPA into chloroform. The aqueous solution was prepared by dissolving thorium perchlorate into perchloric acid - sodium perchlorate solution. The pH of the aqueous solution was adjusted using a 1.0-M perchloric acid and the ionic strength was adjusted using a 1.0-M sodium perchlorate solution. All other chemicals were of AR grade. Doubly distilled water was employed to make up aqueous solutions, and distilled water was employed for washing all glassware. Measurement of extraction eqilibrium: Equal volumes (10.0 ml) of the organic and aqueous solutions of known concentrations were shaken in a 30 ml vial at a required temperature, and allowed to attain equilibrium. The thorium(IV) ion concentration in the aqueous solution was 8.0 ppm. After about 4 hours, the two solutions were separated and aliquotes (1.0 ml) were taken for analysis. Concentration of thorium(IV) was determined spectrophotometrically with a DU-7 spectrophotometer using 1,8- dihydroxynaphthelene-3,6-disulphonic acid-2,7-bis[(azo-2)-phenyl arsonic acid], arsenazo(III), as spectrophotometric reagent(Savvin, 1961). Scanning was performed for a standard solution of thorium-arsenazo(III) complex against a reagent blank in the range λ= 400-800 nm. A wavelength of λ= 660 nm was chosen to be the optimum wavelength of measurement. Figure 2. Variation of [Th(IV)]rec/Th(IV)]aq with HCl concentration, [Th(IV)]rec is the amount recovered from the organic phase. 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0 [ HCl ] [T h( IV )] re c/ Th (IV )] a q Best extraction time was chosen by extraction of several samples of the same concentration for different periods (Figure 1). Best stripping hydrochloric acid concentration of 3.0 M was determined by shaking 2.0 ml of the equilibrated organic solution (5.0 x 10-4 M DDPA) and 10.0 ml hydrochloric acid at different concentrations for 24 hours (Figure 2). Best stripping time was chosen by shaking 10.0 ml of 3.0 M hydrochloric acid solution and 2.0 ml of the equilibrated organic solution of the same concentration (5.0 x 10-4 M DDPA) for different periods (Figure 3). The best DDPA concentration was chosen by extraction of several solutions of thorium(IV) ion by extractant solutions at different concentrations (Figure 4). The optimum pH was chosen by extraction samples at pH values of 0.0, 0.20, 0.31, 0.40, 0.60, 0.80 and 1.00 (Figure 5). The effect of the ionic strength was studied by extraction of several samples at ionic strength of 0.10, 0.50, 1.00, 1.50 and 2.00 M (Figure 6). The effect of the supporting electrolyte was studied by extraction of several samples of different supporting electrolytes of NaClO4, NaCl and NaNO3 (Figure 7). The thermodynamic parameters were obtained by studying the extraction of several samples of thorium(IV) ion at the temperatures of 20.0, 25.0, 27.7, 32.0 and 39.0±0.2 oC (Figure 8). All 109 FAWWAZ I.KHALILI, et al. experimental data were obtained with only one variable in each experiment; the other variables were kept constant. Figure 3. Variation of [Th(IV)]rec/Th(IV)]aq with stripping time. 3. Results and Discussion Effect of extraction time: From Figure 1 establishes that equilibrium was attained in three hours, a time of four hours was selected. Stripping of thorium(IV) from the organic phase: Hydrochloric acid solution was used for stripping of Th(IV) from the organic phase. Figures 2 and 3 demonstrate that a 3.0 M hydrochloric acid is sufficient for stripping of Th(IV) with stripping time of at least 1/2 hour, and can be confirmed by the material balance with a percentage error of about 2% or less. Effect of extractant concentration: From Figure 4 it is seen that the Kd value for Th(IV) increases with the increase of the DDPA concentration. A straight line of a slope ≈ 2.5 was obtained. This means that 2.5 dimer molecules of DDPA are involved in the formation of the thorium-DDPA complex since DDPA has been shown to be dimeric in chloroform (Kondo et al. 1989). Figure 4. Variations of Kd with log [DDPA] at 25 oC. 0.7 0.72 0.74 0.76 0.78 0.8 0.0 2.0 4.0 6.0 8.0 10.0 12.0 14.0 Stripping time (hr) slope = 2.54 -1.2 -1 -0.8 -0.6 -0.4 -0.2 0 0.2 -3.8-3.7-3.6-3.5-3.4-3.3-3.2-3.1 log [DDPA] lo g K d [T h( IV )] re c/ T h( IV )] aq Effect of pH: From Figure 5 it is clear that the Kd value for Th(IV) is directly proportional to the pH. This proportionality is shown for two different concentrations of DDPA (3.0 x 10-4 and 4.0 x 10-4 M) against an aqueous perchloric acid - sodium perchlorate solution of constant ionic strength of 1.0 M. 110 SOLVENT EXTRACTION OF THORIUM(IV) Figure 5. Variation of log Kd with pH at 25 oC. slope=1.55 slope=1.56 -1.5 -1 -0.5 0 0.5 1 0.00 0.20 0.40 0.60 0.80 1.00 1.20 pH lo g K d 3.00E-4 M DDPA 4.00E-4 M DDPA From the extractant dependency and the pH dependency, the extracted species can be written in the form Th(ClO4)4-nRn(HR)5-n which means that a mixed ion exchange - solvation mechanism was involved in the extraction of Th(IV)from perchlorate solution into DDPA solution according to the following equilibrium reactions. Where n is equal to 1 or 2. ( ) ( ) ( ) ( ) + aq org org n+ 4 4 n4-n 2 4-n 5 Th C1O + 2.5 HR Th C1O R HR + 1.55 H Figure 6. Variation of Kd with ionic strength, [DDPA] 5x10-4 M at 25 oC. slope=0.63 2 2.3 2.6 2.9 3.2 3.5 3.8 0.00 0.50 1.00 1.50 2.00 Ionic strength K d Correspondingly, the extraction equilibrium constant is ( ) 1.55 2.5+ ex d 2 orgaq K =K H / HR      (7 Where, is the concentration of the hydrogen ion in the aqueous phase, is the distribution coefficient and [(HR)2]org is the concentration of DDPA dimer in the organic phase at equilibrium. Substitution of the previous values in equation (3) gives Kex = 1.27x10 H+  dK 7. A similar mechanism was found by many authors (Kiwan et al, 1971; Marcus et al. 1973) for the extraction of Th(IV) by dialkylphosphoric acid extractant. Effect of ionic strength: Figure 6 shows that the d increases as the ionic strength (I) increases. This is explained by the increase of the thermodynamic activity of the metal salt extracted and the decrease of the activity of water as the ionic strength increases (Kolarik, 1982). K 111 FAWWAZ I.KHALILI, et al. Effect of supporting electrolyte: From the data shown in Figure 7 it is clear that the extraction of thorium(IV) ion from both perchlorate and nitrate solution is approximately the same and easier than the extraction of thorium(IV) ion from chloride solution. Moreover, the same slope of about 2.5 in three cases, means that the mechanism of the extraction is independent of the supporting electrolyte present in the aqueous phase. slope=2.46 slope=2.51 -1.800 -1.500 -1.200 -0.900 -0.600 -0.300 0.000 0.300 -3.800-3.700-3.600-3.500-3.400-3.300-3.200-3.100 log [DDPA] lo gK d NaClO4 NaNO3 NaCl Figure 7. Variation of log with log [DDPA] for different supporting electrolyte, [DDPA] 5x10dK - 4 M at 25 oC. Figure 8. Variation of log Kd with 1/T, [DDPA] = 5x10-4 M. slope=1768 -0.50 -0.40 -0.30 -0.20 -0.10 0.00 3.2E-03 3.3E-03 3.3E-03 3.4E-03 3.4E-03 3.5E-03 1/T lo gK d Effect of temperature: It is seen from the data in Figure 8 that the Kd values decrease with increasing temperature, which is in agreement with the behavior reported for the extraction of Th(IV) ion (Mason et al,1981). The Van’t Hoff’s equation in the form given by equation (8) can be used to calculate the enthalpy change (∆H) associated with extraction of Th(IV). ( ) 1og 1/ 2.303 K H T R ∆ = ∆ ∆ o (8) The plot of log Kd vs. 1/T is shown in Figure 8. The plot is linear in agreement with equation (8). The value of ∆H obtained from this plot using least squares method is -33.9 ± 0.8 kJ mol-1. It is seen that extraction of Th(IV) is exothermic. The values of free energy and entropy changes were 112 SOLVENT EXTRACTION OF THORIUM(IV) calculated using equations (9) and (10) G RT In∆ = −o K (9) SG H T∆ = ∆ − ∆o o o (10) and these values were found to be AGo= -40.5 ± 2.1 kJ mol-1 and ∆So = 22.1 ± 5.3 JK-1mol-1. A positive entropy change accompanies the dehydration of Th(IV) ion which is known to be highly hydrated. The extraction system was found to be spontaneous. This is in agreement with our previous work for U(VI) (Khaled et al 1999). 4. Conclusion The equilibrium study of the extraction of thorium(IV) ion with didodecylphosphoric acid was carried out. The extracted species into chloroform diluent was found to be Th(ClO4)4-nRn(HR)5-n where, n=1 or 2 and (HR)2 represents the dimer of DDPA. The extraction equilibrium constant was obtained and the extraction system was found to be spontaneous due to the positive entropy change as well as the negative enthalpy change which favors the extraction of Th(IV) ion. 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PEPPARD, D.F., MASON, G.W. MAIEER, J.L and DRISCOLL, W.J. 1957. Fractional Extraction of the Lanthanides as their Di-alkylorthophosphates. J. Inorg. Nucl. Chem. 4: 334-343. ROZEN, A.M., MARTYNOV, B.V. ANIKIN, V.I and MAMAEV, L.A. 1973. Extraction 113 FAWWAZ I.KHALILI, et al. Capability of Sulfoxides. Soviet Radiochem. 15: 121-123. SATO, T. 1965. The Extraction of Uranium(VI) from Hydrochloric Acid Solutions by Di-(2- ethylhexyl)phosphoric Acid. J. Inorg. Nucl. Chem. 27: 1853-1860. SATO, T. 1967. The Extraction of Thorium from Nitric Acid Solutions by Di-(2- ethylhexyl)phosphoric Acid. J. Inorg Nucl. Chem. 29: 555-563. SAVVIN, S.B. 1961. Analytical Use of Arsenazo(III). Talanta. 8: 673-685. Received 15 December 2002 Accepted 24 October 2003 114 Solvent Extraction of Thorium(IV) by Didodecylphoric Acid Fawwaz I. Khalili, Khaled M. Mousa and Ehsan I. Soudani Department of Chemistry, University of Jordan,Amman- Jordan, Email: f_khalili99@yahoo.com. 2. Experimental Correspondingly, the extraction equilibrium constant is References