1991
DOI: 10.1088/0959-7174/1/2/002
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Electromagnetic wave propagation in polycrystalline materials: effective medium approach

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Cited by 17 publications
(9 citation statements)
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“…Since v z = 0, when calculating the effective impedance we cannot use Eqs. (25) - (27). We have to repeat the calculation beginning from the derivation of the proper expressions for the elements σ αβ (k; γ) of the conductivity tensor.…”
Section: Effective Surface Impedance Of Polycrystals Composed Of mentioning
confidence: 99%
“…Since v z = 0, when calculating the effective impedance we cannot use Eqs. (25) - (27). We have to repeat the calculation beginning from the derivation of the proper expressions for the elements σ αβ (k; γ) of the conductivity tensor.…”
Section: Effective Surface Impedance Of Polycrystals Composed Of mentioning
confidence: 99%
“…This version of the EMM was applied for the calculation of various physical effective properties of composite materials and polycrystals (see [1][2][3]). In elasticity this version of the EMM was developed in [4,5] for the calculation of static effective elastic moduli of matrix composites.…”
Section: Introductionmentioning
confidence: 99%
“…Because of existence of a continuous component (matrix) the phase velocity of the mean field should coincide with the wave velocity in the matrix. The attenuation factor c in the short-wave limit does not depend on the frequency and properties of inclusions and is only a function of a number of scatterers on a unit length (for electromagnetic waves see similar results in Bussemer et al (1991) and Kanaun (2000)). The latter is the consequence of the extinction paradox for the value of the total scattering cross section of the inclusion in the short-wave limit (see Appendix A).…”
Section: Solution Of the Dispersion Equation In The Short-wave Limitmentioning
confidence: 80%
“…0. It is known that in the short-wave limit the effective wave number of the mean wave field has the form (Waterman and Truel, 1961;Bussemer et al, 1991;Kanaun, 2000) b…”
Section: Solution Of the Dispersion Equation In The Short-wave Limitmentioning
confidence: 99%