Computer Simulation Studies of Equilibrium Properties in CS2/C6H6 Liquid Mixtures

Molecular dynamics investigation with the time resolved optical Kerr effect on the CS2–C6H6 mixtures

An investigation of the molecular dynamics in pure liquids and in mixtures through the technique of time resolved optical Kerr effect is performed. The samples studied were the mixtures of carbon disulfide (CS(2)) with benzene (C(6)H(6)). The molecular dynamics of the pure liquids is briefly discussed while the main results are obtained for the mixtures. A slow dynamics component is observed for the optical heterodyne detected optical Kerr effect transient decaying exponentially with time constants on picosecond time scale. The fast subpicosend time relaxations are analyzed in terms of the nondiffusive component of the spectral response that is associated with the molecular dynamics. The modifications of the spectrum are quantified, and the explanation of the observed changes is given in terms of the structural interaction configurations that produced changes in the intermolecular potential within which the molecules execute librational motions.

Molecular dynamics simulations of acetonitrile/dimethyl sulfoxide liquid mixtures

Binary liquid mixtures of dimethyl sulfoxide and acetonitrile at the three molar fractions 0.25, 0.50, and 0.75 have been investigated by molecular dynamics computer simulations. Thermodynamic states corresponding to liquid-vapor coexistence at a temperature of 298 K were considered. Intermolecular interactions were described by potential models of the site-site (12-6) Lennard-Jones plus Coulomb type that have been developed for the description of the pure liquids. Dimethyl sulfoxide has been represented by four interactions sites and acetonitrile by a three- as well as a six-site potential model. We have calculated thermodynamic properties and the intermolecular pair distribution functions. Intermolecular interaction energies indicate deviations from the behavior of ideal mixtures. The local mole fraction analysis demonstrates that dimethyl sulfoxide is preferentially solvated by acetonitrile and that the first solvation shell surrounding acetonitrile molecules is significantly enriched by dimethyl sulfoxide. The nonideal behavior in the mixtures is not affected by the choice of the three- or the six-site potential model for acetonitrile. Orientational correlations of dipole vectors within the first solvation shells indicate that the relative molecular orientations found in pure acetonitrile and dimethyl sulfoxide are maintained in the mixtures. Parallel and antiparallel dipole-dipole configurations determine first shell acetonitrile-dimethyl sulfoxide configurations. Dynamical features of the mixtures are discussed in terms of diffusion constants and orientational correlation times as obtained from the time correlation functions for linear velocities and molecular dipole moments, respectively. Computed relaxation times indicate faster reorientational motion for dimethyl sulfoxide if acetonitrile is added. In contrast, the orientational dynamics of acetonitrile becomes stronger correlated upon dilution with dimethyl sulfoxide. The diffusion coefficients for both compounds follow this tendency.