Raman line shape analysis as a mean characterizing molecular glass-forming liquids

Raman scattering spectra in glass forming toluene were studied in the temperature range 50–323 K with the goal of extracting information about homogeneous, inhomogeneous and orientational broadening. It was found that the temperature dependence of inhomogeneous line width allows one to depict two peculiar temperatures: TA and Tg, where Tg is the glass transition temperature and TA is the temperature of transition from an Arrhenius-like to a non-Arrhenius behavior for the α-relaxation time dependence on temperature, τα(T). Temperature dependence of the orientational phase loss time τOPL was found to correspond well to τα at T > TA and continues approximately Arrhenius behavior for lower temperature in contrast to τα(T). Also, a comparative analysis of homogeneous broadening of polarized and depolarized lines was done, which provided an estimation of the orientational broadening γNL(T). The found γNL(T) decreases linearly as the temperature decreases and goes to zero at T ~ Tc, where Tc is the critical temperature in framework of the mode-coupling theory (note that Tc is close to other peculiar temperatures TB and Tβ, but we did not intent to distinguish among them in the present work). Thus, it was shown that the Raman line shape analysis in molecular glass forming materials allows one to extract peculiar temperatures: TA, Tg, and, probably, Tc. st of the possibility to use a probe molecule for the Raman line shape analysis has revealed that the extracted data for probe molecule lines do not characterize the host matrices, at least in the low-viscous state (T > TA).