Author:
Zafarani-Moattar Mohammed Taghi,Shekaari Hemayat,Asadollahi Soheila
Abstract
AbstractIn this work, to evaluate solute–solute, solute–solvent and phase separation in aqueous systems containing {betaine + poly ethylene glycol dimethyl ether with molar mass 250 g mol−1 (PEGDME250)}, {betaine + K3PO4} and {betaine + K2HPO4}, first water activity measurements were made at 298.15 K and atmospheric pressure using the isopiestic technique. The water iso-activity lines of these three systems were obtained which have positive deviations from the semi-ideal solutions. This suggests that betaine-polymer and betaine-K3PO4 or betaine-K2HPO4 interactions are unfavorable; and these mixtures may form aqueous two-phase systems (ATPSs) at certain concentrations. Indeed the formation of ATPSs was observed experimentally. Then, osmotic coefficient values were calculated using the obtained water activity data; and, using the polynomial method the solute activity coefficients were determined. Using these activity coefficients, the transfer Gibbs energy ($$\Delta {G}_{tr}^{i}$$
Δ
G
tr
i
) values were calculated for the transfer of betaine from aqueous binary to ternary systems consisting polymer (PEGDME250) or salts (K3PO4 and K2HPO4). The obtained positive $$\Delta {G}_{tr}^{i}$$
Δ
G
tr
i
values again indicated that there is unfavorable interaction between betaine and these solutes. Finally, the volumetric and ultrasonic studies were made on these systems to examine the evidence for the nature of interactions between betaine and the studied salts or polymer.
Publisher
Springer Science and Business Media LLC
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