Open AccessEnhancement of Electromagnetic Fields Caused by Interacting Subwavelength Cavities
Author(s) -
Jean-François Babadjian,
Éric Bonnetier,
Faouzi Triki
Publication year - 2010
Publication title -
multiscale modeling and simulation
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.037
H-Index - 70
eISSN - 1540-3467
pISSN - 1540-3459
DOI - 10.1137/100787659
Subject(s) - antisymmetric relation , physics , electromagnetic field , operator (biology) , plane (geometry) , field (mathematics) , integral equation , dipole , function (biology) , limiting , asymptotic analysis , dirac delta function , near and far field , mathematical analysis , classical mechanics , mathematical physics , optics , quantum mechanics , mathematics , geometry , pure mathematics , mechanical engineering , biochemistry , chemistry , repressor , evolutionary biology , biology , transcription factor , engineering , gene
International audienceThis article is devoted to the asymptotic analysis of the electromagnetic elds scattered by a perfectly conducting plane containing two sub-wavelength rectangular cavities. The problem is formulated through an integral equation, and a spectral analysis of the integral operator is performed. Using the generalized Rouché theorem on operator valued functions, it is possible to localize two types of resonances, symmetric and anti-symmetric, in a neighborhood of each zero of some explicit function, associated to the limiting geometry. For the symmetric modes, the elds in the cavities interact in phase, and the system of two cavities essentially acts as a dipole. In the anti-symmetric case, the fields oscillate in anti-phase, and the system behaves like a quadripole. Asymptotic expansions of the resonances, the far-eld and the near-eld are given
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