Structural and dynamical investigation of glassforming smectogen by X-ray diffraction and infra-red spectroscopy aided by density functional theory calculations
Aleksandra Deptuch, Natalia Górska, Stanisław Baran, Magdalena Urbańska
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引用次数: 0
Abstract
Molecular arrangement in the chiral smectic phases of the glassforming
(S)-4'-(1-methylheptylcarbonyl)biphenyl-4-yl
4-[7-(2,2,3,3,4,4,4-heptafluorobutoxy) heptyl-1-oxy]benzoate is investigated by
X-ray diffraction. An increased correlation length of the positional
short-range order in the supercooled state agrees with the previous assumption
of the hexatic smectic phase. However, the registered X-ray diffraction
patterns are not typical for the hexatic phases. Comparison of the smectic
layer spacing and optical tilt angle indicates a strongly non-linear shape of
molecules, which enables choice of the molecular models obtained by DFT
calculations, used subsequently to interpret the infra-red spectra. The
presumption of the hexatic smectic FA* or IA* phase is supported by the
splitting of the absorption bands related to the C=O stretching in the
supercooled state, which is absent in the smectic CA* phase above the melting
temperature. The glass transition affects the temperature dependence of the
smectic layer spacing but only subtly impacts the infra-red spectra.
Application of the k-means cluster analysis enables distinction between the
infra-red spectra below and above the glass transition temperature, but only
for certain spectral ranges.