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Abstract

A continuum model, based on a theory of electromagnetic media with microstructure, is exploited to deal with rigid conductors endowed with polarization and magnetization. Charge carriers are considered as a continuum superimposed to the microstructured conductor where the density of bound charges depends on the internal degrees of freedom of the continuum particle. The non-linear dynamical model is formulated, deriving the mechanical balance laws that are coupled with the electromagnetic field equations. A reduction to the micropolar linear case is performed in order to analyze admissible solutions in the form of one-dimensional plane waves. Dispersion equations are derived for modes pertaining to longitudinal and transverse fields and the effects of conductivity and polarization are evidentiated. Polariton modes, arising from the dynamics of microdeformation, are also discussed.

Keywords

Electric conductors electromagnetic micropolar continua em waves in polarized conductors

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References

Landau

Lifšits

Pitaevskii

. Electrodynamics of continuous media. New York: Pergamon Press, 1984.

Maugin

. Continuum mechanics of electromagnetic solids. North Holland: Elsevier, 1988.

Eringen

Maugin

. Electrodynamics of continua I. New York: Springer–Verlag, 1990.

De Lorenzi

Tiersten

. On the interaction of the elctromagnetic field with heat conducting deformable conductors. J Math Phys 1975; 16: 938–957.

Maugin

Daher

. Phenomenological theory of elastic semiconductors. Int J Eng Sci 1986; 24: 703–731.

Jou

Casas–Vásquez

Lebon

. Extended irreversible thermodynamics. 2nd ed. Berlin: Springer, 1996.

Cuevas

del Río

López

Haro

. Consequences of a generalized Ohm’s law for magnetic transport in conducting media. J Phys D Appl Phys 1999; 32: 639–643.

Silveira

FEM

Lima

JAS

. Attenuation and damping of electromagnetic fields: Influence of inertia and displacement current. J Phys A Math Theor 2009; 42: 15.

Eringen

. Microcontinuum field theories I - foundations and solids. New York: Springer–Verlag, 1999.

10.

Romeo

. Micromorphic continuum model for electromagnetoelastic solids. ZAMP 2011; 62: 513–527.

11.

Romeo

. Polarization in dielectrics modeled as micromorphic continua. ZAMP 2015; 66: 1233–1247.

12.

Romeo

. Electomagnetoelastic equations for ferroelectrics based on a micromorphic dielectric model. Acta Mech 2012; 223: 205–219.

13.

Mills

Burstein

. Polaritons: The electromagnetic modes of media. Rep Prog Phys 1974; 37: 817–926.

14.

Pouget

Maugin

. Coupled acoustic-optic modes in deformable ferroelectrics. Acoust Soc Am 1980; 68: 588–601.

15.

Lerose

Sanzeni

Carati

et al . Classical microscopic theory of polaritons in ionic crystals. Eur Phys J D 2014; 68: 35.

16.

Pouget

Askar

Maugin

. Lattice model for elastic ferroelectric crystals: Microscopic approach. Phys Rev B 1986; 33: 6304–6319.

17.

Romeo

. Acoustic waves in micropolar elastic ferroelectrics. Mech Res Comm 2015; 63: 33–38.

18.

Romeo

. Electroelastic waves in dielectrics modeled as polarizable continua. Wave Motion 2016; 60: 121–134.

Electromagnetic field-current coupling in rigid polarized conductors

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