Energy basis of dielectric relaxation loss

The real and imaginary components of the complex susceptibility of the majority of non-polar dielectric materials follow a fractional power law dependence on frequency known as the "universal law". One limiting form of this law shows a very low loss and also a nearly frequency-independent, or "flat"

we derive an approximate form& for a novel form of energy loss experienced by l-10 cV electrons passing through polar liquids This loss mechanism, which depends on the translational motions of polar molecuIes in the Coulomb field of an electron is shown to yield a dissipation rate comparable in magn

Empirical formulae for evaluating the dielectric relaxation intensity or the magnitude of dielectric dispersion from dielectric loss data in a limited range of frequency around the relaxation frequency are presented for the Cole-Cole, Davidson-Cole, and Williams-Watts type of relaxation. The relaxat

Empirical formulae for evaluating the dielectric relaxation intensity, or the magnitude of dielectric dispersion, from dielectric loss data, proposed by Kita and Koizumi, in a limited range of frequency around the relaxation frequency for the Davidson -Cole relaxation has been verified in the case o