Theory of Dielectric Relaxation in Polar Liquids

Abstract

The theory of dielectric relaxation in a model polar liquid is developed and applied to experimental data. The model is a spherical Onsager cavity, with a uniform dielectric background described by the high frequency limit ε ∞ and containing a permanent point dipole. The dipole moment undergoes rotational Brownian motion in the cavity. Dielectricfriction on the rotating dipole is taken into account and leads to a frequency‐dependent relaxation time. Earlier theoretical results, obtained first by Klug, Kranbuehl, and Vaughn and by Fatuzzo and Mason, are rederived. When the rotational Brownian motion is spherically isotropic, approximate Debye relaxation is found. When the rotational Brownian motion of the dipole is restricted to a constant angle with respect to some fixed axis, approximate Davidson–Cole relaxation is found. Experimental data on glycerol and i‐amylbromide are analyzed this way.