Open AccessAn asymptotic theory for waves guided by diffraction gratings or along microstructured surfaces
Author(s) -
Tryfon Antonakakis,
R. V. Craster,
Sébastien Guenneau,
E. A. Skelton
Publication year - 2013
Publication title -
proceedings of the royal society a mathematical physical and engineering sciences
Language(s) - English
Resource type - Journals
eISSN - 1471-2946
pISSN - 1364-5021
DOI - 10.1098/rspa.2013.0467
Subject(s) - wavelength , diffraction , optics , surface wave , physics , surface (topology) , surface plasmon polariton , bloch wave , rayleigh wave , diffraction grating , classical mechanics , plasmon , mathematical analysis , surface plasmon , geometry , mathematics , quantum mechanics
An effective surface equation, that encapsulates the detail of a microstructure, is developed to model microstructured surfaces. The equations deduced accurately reproduce a key feature of surface wave phenomena, created by periodic geometry, that are commonly called Rayleigh–Bloch waves, but which also go under other names, for example, spoof surface plasmon polaritons in photonics. Several illustrative examples are considered and it is shown that the theory extends to similar waves that propagate along gratings. Line source excitation is considered, and an implicit long-scale wavelength is identified and compared with full numerical simulations. We also investigate non-periodic situations where a long-scale geometrical variation in the structure is introduced and show that localized defect states emerge which the asymptotic theory explains.
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