Abstract
Liquid-liquid extraction experiments, UV/vis spectra, and equilibrium modeling by use of the program SXLSQA have been employed to reveal the origin of synergism in the extraction of Cu(ll) from sulfuric acid by the tetradentate macrocycle tetrathia-14-crown-4 (TT14C4) combined with the cation exchanger didodecylnaphthalene sulfonic acid (HDDNS) in toluene. The key feature of the system is the 1:1 complexation of Cu(ll) by TT14C4. HDDNS functions both as a source of exchangeable protons and as a solvating agent that promotes the formation of small, hydrated aggregates. In the absence of the cation-exchange vehicle provided by HDDNS, the macrocycle does not extract Cu(ll) detectably. Combined with HDDNS, however, TT14C4 significantly enhances the extraction of the metal by HDDNS. Comparative UV/vis spectrophotometry indicates the formation of the deep-blue chromophore attributed to the complex ion Cu(TT14C4)2+, wherein the planar set of four endo sulfur donor atoms of TT14C4 circumscribes the metal cation. Modeling of the extraction and spectral absorbance data by use of the program SXLSQA supports the conclusion that this 1:1 complex accounts for essentially all of the extracted Cu(ll) in excess of that extracted by HDDNS alone. The best model includes HDDNS aggregates incorporating CU(TT14C4)2+or Cu2+ions. In the analysis, activity effects in both aqueous and organic phases have been taken into account by the Pitzer and Hildebrand-Scott treatments, respectively, with explicit inclusion of the formation of aqueous hydrogen sulfate ion. The model accounts for the effect of variation of the solute components CUSO4, H2SO4, HDDNS, and TT14C4.
Original language | English |
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Pages (from-to) | 1047-1069 |
Number of pages | 23 |
Journal | Separation Science and Technology (Philadelphia) |
Volume | 30 |
Issue number | 7-9 |
DOIs | |
State | Published - 1995 |
Funding
This research was funded by the Division of Chemical Sciences, Office of Basic Energy Sciences, U.S.D epartment of Energy under contract DE-AC05840R21400 with Martin Marietta Energy Systems, Inc. The participation of Laetitia Delmau in this research was made possible in part by a travel grant from the Rectorat de I'Academie de Paris, and