2014
DOI: 10.1103/physreva.89.023829
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Quasimodal expansion of electromagnetic fields in open two-dimensional structures

Abstract: A quasimodal expansion method (QMEM) is developed to model and understand the scattering properties of arbitrary shaped two-dimensional (2-D) open structures. In contrast with the bounded case which have only discrete spectrum (real in the lossless media case), open resonators show a continuous spectrum composed of radiation modes and may also be characterized by resonances associated to complex eigenvalues (quasimodes). The use of a complex change of coordinates to build Perfectly Matched Layers (PMLs) allows… Show more

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Cited by 101 publications
(115 citation statements)
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“…Note that this relation holds also with Bloch-periodic boundary conditions (and the surface-term correction found in [86] does not appear in our formulation). Although the matrix A is no longer symmetric in the k-periodic problem, it satisfies the relation A(k) T = A(−k), and since we are essentially relating k-right eigenvectors to (−k)-left eigenvectors, the relation above remains unchanged.…”
Section: A Non-degenerate Green's Function Modal Expansion Formulamentioning
confidence: 78%
“…Note that this relation holds also with Bloch-periodic boundary conditions (and the surface-term correction found in [86] does not appear in our formulation). Although the matrix A is no longer symmetric in the k-periodic problem, it satisfies the relation A(k) T = A(−k), and since we are essentially relating k-right eigenvectors to (−k)-left eigenvectors, the relation above remains unchanged.…”
Section: A Non-degenerate Green's Function Modal Expansion Formulamentioning
confidence: 78%
“…The normal modes of the system are solutions of Maxwell equations in the absence of sources, with outgoing radiation conditions, and with a certain normalization [26,[28][29][30]. Due to the outgoing radiation conditions, the Hamiltonian of the system is non-hermitian and the normal modes of the system have complex eigenfrequencies ω µ [26,31,32]. Let us notice that a normalization condition of the kind V |E µ (r, ω µ )| 2 dV cannot be applied to normal modes with resonant complex frequencies ω µ because E µ (|r| → ∞, ω µ ) → ∞ [20,[26][27][28][29]33].…”
Section: Introductionmentioning
confidence: 99%
“…In this picture, a resonator is viewed as a passive open system with only out-going emission from the resonator, which determines the boundary conditions. Its resonating modes are referred to as quasi modes [25], since they decay with time. The field evolution during one round trip in the cavity is expressed by a matrix U = R bot R top where R top and R bot are the reflectivity matrices from the top and the bottom sections of the structure, respectively, as shown in Fig.…”
Section: Device Structure and Simulation Methodsmentioning
confidence: 99%
“…the cap layer, each Bloch mode corresponds to a single spatial harmonic (or diffraction order) [16]. For Q-factor estimation, a method based on the quasi-normal mode (QNM) [25] picture is employed among several approaches [26], due to its accuracy and numerical efficiency for both 2D and 3D simulations. In this picture, a resonator is viewed as a passive open system with only out-going emission from the resonator, which determines the boundary conditions.…”
Section: Device Structure and Simulation Methodsmentioning
confidence: 99%