Microscopic Dynamics of Hard Ellipsoids in their Liquid and Glassy Phase
arXiv:cond-mat/0109286 · doi:10.1016/S0022-3093(02)01456-4
Abstract
To investigate the influence of orientational degrees of freedom onto the dynamics of molecular systems in its supercooled and glassy regime we have solved numerically the mode-coupling equations for hard ellipsoids of revolution. For a wide range of volume fractions $Ï$ and aspect ratios $x_{0}$ we find an orientational peak in the center of mass spectra $Ï_{000}^{''}(q,Ï)$ and $Ï_{000}^{''} (q,Ï)$ about one decade below a high frequency peak. This orientational peak is the counterpart of a peak appearing in the quadrupolar spectra $Ï_{22m}^{''}(q,Ï)$ and $Ï_{22m}^{''}(q,Ï)$. The latter peak is almost insensitive on $Ï$ for $x_{0}$ close to one, i.e. for weak steric hindrance, and broadens strongly with increasing $x_{0}$. Deep in the glass we find an additional peak between the orientational and the high frequency peak. We have evidence that this intermediate peak is the result of a coupling between modes with $l=0$ and $l=2$, due to the nondiagonality of the static correlators.
6 figures, 12 pages