Structure and local environment of dimethyl sulfoxide (DMSO) in different ionic media

Although it has long been used as a solvent for organic and inorganic species, as well as drug carriers, many aspects concerning the intermolecular self-association of dimethyl sulfoxide (DMSO) and their interactions with ionic species are still controversial in the literature. In the present study, the structure and local environment of dimethyl sulfoxide (DMSO) in different ionic media were studied using three different approaches. In the first approach, the Raman non-coincidence effect (NCE) observed in the band assigned to the DMSO ν(S = O) mode, ca. 1050 cm-1, was investigated for the pure liquid and in its solutions of carbon tetrachloride (CCl4) and water. In addition, the effect of ionic species (K1, KSCN, KBr, TBAN3, TBAOCN, LiClO4, Mg (ClO4)2) on the frequency ν(S = O) as well as the NCE of the solutions were investigated. The results of NCR together with the infrared, NMR and physico-chemical properties measurements showed that these ionic species not only affect the association structure of DMSO, but are also capable of interacting strongly with the solvent. In the second approach, with the purpose of modulating the properties of an ionic liquid, the structural analysis of the mixtures involving DMSO and water as solvents and the ionic liquid EAN as a solute were carried out by X-ray and neutron scattering techniques. The results showed that the cation-anion structure of the EAN is affected by the presence of DMSO and that in both solvents strong hydrogen bonds between the EA+ cation and the oxygen from solvent and from nitrate anion are evident. The water molecules do not affect the structure of the EAN drastically, because its LH donor/acceptor character and its size allows the formation of bridges between cation and anion, however, EAN can distort the hydrogen bonding three-dimensional network in water. On the other hand, the DMSO molecules repels the anions from the polar head of EA+ in the competition in forming LH with the cation, however EAN break down DMSO association structures. In the third approach, mixtures involving three different SEPs (a class of ionic liquids); Relina, MUCHCl and DMUCHCl; with DMSO were investigated by means of their physicochemical properties and by Raman spectroscopy, in order to modulate the properties of SEPs. In this case, the results did not point to strong and specific interactions involving the ionic species and DMSO, but to a greater packaging of the system, where the deviations of its physicochemical properties with respect to the ideality are negative and its ionic mobility together with the analysis of the vibrational spectra showed no specific interactions. However, the viscosities and densities decreased in the mixtures and the ionic mobility was favored. (AU)