Dipolar interaction and molecular ordering in liquid propylene carbonate: Anomalous dielectric susceptibility and Raman non-coincidence effect
Journal article, 2011

Dielectric constant of non-associating fluids normally exhibits a 1/T temperature dependence according to Curie's law. Kirkwood correlation factor in such cases is close to unity and almost independent of the temperature. Recent broadband dielectric studies of a well-known solvent propylene carbonate (PC) revealed anomalous behavior of its loss spectrum, whose amplitude somewhat increases at high temperatures contrary to Curie's law, while it is known from the literature that its Kirkwood factor is close to unity. We analyze the origin of this discrepancy and find, based on recent literature data, that the Kirkwood factor of PC is strongly temperature dependent and significantly differs from unity, which signals the presence of temperature dependent molecular ordering. We find other signatures of this ordering in vibrational spectra of PC, where it leads to splitting of molecular vibrations due to interaction between the transition dipoles of neighboring molecules (the so-called non-coincidence effect). Spectroscopic and dielectric results agree well with each other and reveal the presence of significant temperature-dependent anti-parallel dipolar arrangement. Based on these results, it is likely that other polar liquid:; with large and localized molecular dipoles, albeit traditionally classified as non-associating, in fact do possess significant local molecular order due to dipolar interactions.

polar liquids

Static dielectric constant

spectroscopy

moments

profiles

Molecular correlations

spherical approximation

Propylene carbonate

Dipolar interactions

Mean

mixtures

ethylene

Non-coincidence effect

Kirkwood factor

dynamics

Author

A. Brodin

National Academy of Sciences in Ukraine

National Technical University of Ukraine, Kiev Polytechnic Institute

Per Jacobsson

Chalmers, Applied Physics, Condensed Matter Physics

Journal of Molecular Liquids

0167-7322 (ISSN)

Vol. 164 1-2 17-21

Subject Categories

Physical Sciences

DOI

10.1016/j.molliq.2011.08.001

More information

Latest update

12/4/2020