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Calculation of Electromagnetic Wave Scattering by a SmallImpedance Particle of an Arbitrary Shape

Published online by Cambridge University Press:  17 July 2014

A. G. Ramm*
Affiliation:
Department of Mathematics, Kansas State University, Manhattan, KS 66506-2602, USA
M. I. Andriychuk
Affiliation:
Pidstryhach Institute for Applied Problems in Mechanics and Mathematics, NASU Naukova St., 3B, 79060, Lviv, Ukraine
*
Corresponding author. E-mail: [email protected]
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Abstract

Scattering of electromagnetic (EM) waves by small (ka ≪ 1) impedance particleD of anarbitrary shape, embedded in a homogeneous medium, is studied. Analytic, closed form,formula for the scattered field is derived. The scattered field is of the orderO(a2 −κ), where κ ∈ [ 0,1)is a number. This field is much larger than in the case of Rayleigh-type scattering. Thenumerical results demonstrate a wide range of applicability of the analytic formula forthe scattered field. Comparison with Mie-type solution is carried out for various boundaryimpedances and radii of the particle.

Type
Research Article
Copyright
© EDP Sciences, 2014

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References

Andriychuk, M. I., Indratno, S. W., Ramm, A. G.. Electromagnetic wave scattering by a small impedance particle: theory and modeling. Optics Communications, 285 (2012), 1684-1691. CrossRefGoogle Scholar
L. Landau, L. Lifshitz. Electrodynamics of continuous media. Pergamon Press, London, 1982.
A.G.Ramm, Scattering of Acoustic and Electromagnetic Waves by Small Bodies of Arbitrary Shapes. Applications to Creating New Engineered Materials, Momentum Press, New York, 2013.
Ramm, A. G.. Many-body wave scattering by small bodies and applications. J. Math. Phys., 48 (2007), no. 10, 103511. CrossRefGoogle Scholar
Ramm, A. G.. Wave scattering by many small particles embedded in a medium. Phys. Lett. A, 372/17 (2008), 3064-3070. CrossRefGoogle Scholar
Ramm, A. G.. Distribution of particles which produces a “smart” material. Jour. Stat. Phys., 127 (2007), no. 5, 915-934. CrossRefGoogle Scholar
Ramm, A. G.. Scattering by many small bodies and applications to condensed matter physics. Europ. Phys. Lett., 80 (2007), 44001. CrossRefGoogle Scholar
Ramm, A. G.. Distribution of particles which produces a desired radiation pattern. Physica B, 394 (2007), no. 2, 253-255. CrossRefGoogle Scholar
Ramm, A. G.. A recipe for making materials with negative refraction in acoustics. Phys. Lett. A, 372/13 (2008), 2319-2321. CrossRefGoogle Scholar
Ramm, A. G.. Does negative refraction make a perfect lens? Phys. Lett. A, 372 (2008), 6518-6520. CrossRefGoogle Scholar
Ramm, A. G.. Electromagnetic wave scattering by small bodies. Phys. Lett. A, 372/23 (2008), 4298-4306. CrossRefGoogle Scholar
A. G. Ramm. Preparing materials with a desired refraction coefficient and applications, In the book “Topics in Chaotic Systems: Selected Papers from Chaos 2008 International Conference”. Editors C.Skiadas, I. Dimotikalis, Char. Skiadas, World Sci. Publishing, (2009), 265-273.
Ramm, A. G.. Materials with a desired refraction coefficient can be created by embedding small particles into the given material. International Journal of Structural Changes in Solids (IJSCS), 2 (2010), no. 2, 17-23. Google Scholar
Ramm, A. G.. Wave scattering by many small bodies and creating materials with a desired refraction coefficient. Afrika Matematika, 22 (2011), no. 1, 33-55. CrossRefGoogle Scholar
A. G. Ramm, Scattering by many small inhomogeneities and applications. In the book “Topics in Chaotic Systems: Selected Papers from Chaos 2010 International Conference”, Editors C.Skiadas, I. Dimotikalis, Char. Skiadas, World Sci.Publishing, (2011), 41-52.
Ramm, A. G.. Electromagnetic wave scattering by many small bodies and creating materials with a desired refraction coefficient. Progress in Electromagnetic Research M (PIER M), 13 (2010), 203-215. CrossRefGoogle Scholar
A. G. Ramm. Wave scattering by small bodies of arbitrary shapes. World Sci. Publishers, Singapore, 2005.
A. G. Ramm. Scattering by obstacles. D.Reidel, Dordrecht, 1986.
Ramm, A. G.. Electromagnetic wave scattering by a small impedance particle of an arbitrary shape. Optics Communications, 284 (2011), 3872-3877. CrossRefGoogle Scholar