Aqueous two-phase systems of copolymer L64 + organic salt + water: Enthalpic L64–salt interaction and Othmer–Tobias, NRTL and UNIFAC thermodynamic modeling

Phase diagrams of two-phase systems (ATPS) composed by the triblock copolymer L64 + organic salt (sodium tartrate, sodium succinate, sodium citrate, or ammonium citrate) + water, at different temperatures (278, 288, and 298 K) are presented in this work. Contrary to behavior of ATPS formed by inorga...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2011-06, Vol.171 (1), p.9-15
Main Authors: de Andrade, Vivianne Molica, Rodrigues, Guilherme Dias, de Carvalho, Raquel Moreira Maduro, da Silva, Luis Henrique Mendes, da Silva, Maria C. Hespanhol
Format: Article
Language:English
Subjects:
Anions
Applied sciences
Aqueous two-phase system
ATP
Cations
Chemical engineering
Citrates
Crystallization, leaching, miscellaneous separations
energy
Enthalpic interaction
Entropy
Exact sciences and technology
heat production
inorganic salts
Microcalorimetry
Organic salts
Phase separation
Sodium
sodium citrate
succinic acid
temperature
Thermodynamic modeling
Triblock copolymer
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Summary:Phase diagrams of two-phase systems (ATPS) composed by the triblock copolymer L64 + organic salt (sodium tartrate, sodium succinate, sodium citrate, or ammonium citrate) + water, at different temperatures (278, 288, and 298 K) are presented in this work. Contrary to behavior of ATPS formed by inorganic salts, the study of the temperature influence in the liquid–liquid equilibrium behavior of L64–organic salts ATPS showed an exothermic character for phase separation process. Microcalorimetric measurements showed that this phase separation energy is around −0.2 kJ mol −1 for all organic salts. The module of slope of tie line (STL) tends to increase with an increase in temperature. The cation nature effect showed that the salt Na 3C 6H 5O 7 was more effective in promoting phase separation than (NH 4) 3C 6H 5O 7. The capacity of the different anions tested for inducing ATPS formation with L64 followed the order: C 6H 5O 7 3− > C 4H 4O 6 2− > C 4H 4O 4 2−. Because the salt–L64 interaction energy to be very similar, the cation and anion effects on the phase separation could be attribute to a process driven by entropy. The interaction parameters of the NRTL and UNIFAC models were estimated through the experimental data of all ternary systems. The results of the NRTL (with 64 tie-lines) and UNIFAC (with 27 tie-lines) were considered excellent with global root mean square deviations, respectively, of the 1.04% and 0.87%. The consistencies of the all tie-line experimental compositions were improved by applying the Othmer–Tobias correlation.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2011.03.015