Raman bandshapes of liquids

Vibrational dephasing of liquid carbon disulfide at different pressures is investigated by molecular dynamics simulation. Pertubation theory allows one to use the well-stablished method of equilibrium molecular dynamics of rigid molecules in studying vibrational dephasing. Besides the effective three-centre Lennard-Jones intermolecular potential for the simulation of CS2 , an effective coupling potential between vibrational, translational and rotational degrees of freedom is also assumed. The role of repulsive and attractive terms in this potential, as well as anisotropy, is discussed. The experimental trends of the average vibrational frequency shift between gas and liquid phase and vibrational correlation function with density are well reproduced by molecular dynamics. The simulations indicate a small correlation between vibrational and reorientational relaxations, which can be shown as the result of the coupling of these degrees of freedom with translational motion. A stochastic model is developed to investigate the correlation between vibrational and reorientational correlation functions. Very similar correlation is obtained from both theory and computer simulation. The simulations also showed that correlation functions of vibrational frequency fluctuations of CS2 are not a single exponential. Thus, the well known Kubo\'s formula for the vibrational correlation function is not valid for CS2 , and a double exponential model for the memory function is introduced. (AU)