Isothermal calorimetric titrations of aqueous solutions of poly(ethylene glycol) (PEG) with sodium dodecyl
sulfate (SDS) are known to exhibit a peculiar trend consisting of endothermic and exothermic effects. This
behavior was explained with the formation of two different mixed micellar aggregates, one characterized by
hydrophobic interactions and the second by ion-dipole association. Present NMR measurements on 13C, 1H,
and 23Na nuclei do not support the formation of a number of PEG-SDS aggregates characterized by interactions
of different nature. Our data are rather in accordance with the initial formation, at low surfactant concentration,
of a polymer-surfactant aggregate in which the polymeric chain assumes a strained conformation in order to
bind a small micellar cluster. The subsequent growing of the aggregate with increasing surfactant concentration
allows the polymer to relax to a more expanded, energetically favored, conformation. Further calorimetric
titrations with a set of PEG samples of different molecular weight (200 to 20000 Daltons) allowed to establish
a few points so far unclear. The minimum molecular weights necessary for observing the onset and the settling,
respectively, of polymer-surfactant interaction were identified and the characteristic multiple peak curve of
the titration of the polymer with molecular weight of 8000 Dalton was found related to the discrete binding
of two successive SDS micellar clusters on the same polymeric chain
The interaction of cesium perfluorooctanoate (CsPFO) with poly(ethylene glycol) (PEG) of different molecular weight (300 < or = MW < or = 20000 Da) has been investigated at 298.15 K by isothermal titration calorimetry (ITC), density, viscosity, and conductivity measurements. Calorimetric titrations exhibited peculiar trends analogous to those already observed for sodium dodecyl sulfate (SDS). Micelles of the perfluorosurfactant, as compared to those of SDS, yield complexes with the polymer of similar thermodynamic stability but are able to interact with shorter PEG oligomers. The average number of surfactant molecules bonded per polymer chain at the saturation is about twice that observed for SDS. ITC data at 308.15 K indicate a larger thermodynamic stability of the aggregates but an almost constant stoichiometry. The peculiar thermal effects and the viscosity trend observed during the titration of an aqueous PEG solution with the surfactant appear consistent with a conformational change of the polymer. The PEG chain would evolve from a strained to an expanded conformation, induced by the growing of the surfactant micellar clusters bonded to the polymer, as suggested in a previous study of the PEG/SDS/H2O system.
The interaction of lithium perfluorononanoate (LiPFN) with poly(ethylene glycol) (PEG) molecules of different molecular weights (300 < MW < 20000 Da) has been investigated in water at 298.15 and 308.15 K by isothermal titration calorimetry (ITC). Density, viscosity, and conductivity measurements were also performed at 298.15 K. The aggregation process of this surfactant on the PEG polymeric chain was found to be very similar to that exhibited by cesium perfluorooctanoate (CsPFO) and appears to be consistent with the necklace model. ITC titrations indicated that a fully formed LiPFN micellar cluster can be wrapped by a PEG chain having a molecular weight (MW) of approximately 3200 Da, longer than that required by the shorter perfluorooctanoate (MW approximately 2600 Da), and also suggested a stepwise mechanism for the aggregation of successive micelles. Viscosity data indicate that the formation of polymer-surfactant complexes between PEG and LiPFN involves a conformational change of the polymer. The aggregation of preformed micelles of LiPFN or CsPFO or SDS on the PEG polymeric chain always gives rise to further stabilization.
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