Baker-Jarvis, J.
, Riddle, B.
and Janezic, M.
(2007),
Dielectric polarization evolution equations and relaxation times, Physical Review A (Atomic, Molecular and Optical Physics), [online], https://doi.org/10.1103/PHYSREVE.75.056612
(Accessed April 30, 2024)
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Dielectric polarization evolution equations and relaxation times
Published
Author(s)
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Abstract
In this paper we develop a model that can describe broadband dielectric response, and includes frequency-dependent loss and the effects of the local electric field. The model is based on a correlation-function approach that we previously developed using statistical-mechanical theory. We develop a very general integro-differential equation for the polarization. The Laplace-transformed form of this equation contains a frequency-dependent relaxation time. We show that the real part of the relaxation is negative; however; near resonance the imaginary part of the relaxation time is positive. This is due to the effects of the local field on the molecular short-range restoring forces. We present illustrative examples for the harmonic oscillator and derive the expressions for the frequency-dependent relaxation times and a time-domain integro-differential equation for the Cole-Davidson model. We extract the real and imaginary parts of the relaxation time from alcohol permittivity data. We also develop a generalize Lyddane-Sachs-Teller relationship.Citation
Physical Review A (Atomic, Molecular and Optical Physics)
Volume
75
Issue
5
Pub Type
Journals
Download Paper
Keywords
dielectric, linear response, loss factor, nonequilibrium, permittivity relaxation.
Citation
Created May 25, 2007, Updated June 2, 2021