Lorenz–Mie theory for 2D scattering and resonance calculations

Gagnon, Denis; Dubé, Louis J.

doi:10.1088/2040-8978/17/10/103501

Cited by 10 publications

(10 citation statements)

References 88 publications

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“…The theory of multiple scattering from cylinders was pioneered in the 1950s by Twersky . In this section, we follow the study by Gagnon and Dubé to compute the solution of the multiple scattering problem of a finite array of dielectric cylinders. Consider first a single infinitely long dielectric cylinder of radius R and refractive index n , standing in vacuum with its axis aligned to the

\overset{falseˆ}{z}

axis.…”

Section: Theoretical Methodsmentioning

confidence: 99%

Mie Scattering in the Macroscopic Response and the Photonic Bands of Metamaterials

Juárez

Mendoza²,

Mochán³

2020

Physica Status Solidi (b)

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Herein, a general approach for the numerical calculation of the effective dielectric tensor of metamaterials is presented, and it is shown that the formalism may be used to study metamaterials beyond the long‐wavelength limit. A system composed of high‐refractive‐index cylindrical inclusions is considered, and it is shown that the method reproduces the Mie resonant features and photonic band structure obtained from a multiple scattering approach, hence opening the possibility to study arbitrarily complex geometries for the design of resonance‐based negative refractive metamaterials at optical wavelengths.

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\overset{falseˆ}{z}

axis.…”

Section: Theoretical Methodsmentioning

confidence: 99%

Mie Scattering in the Macroscopic Response and the Photonic Bands of Metamaterials

Juárez

Mendoza²,

Mochán³

2020

Physica Status Solidi (b)

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“…Within this approach, the electromagnetic field is expanded in terms of Bessel-Fourier multipolar basis functions in the coordinate system centered at the origin of each individual cylinders. Using the Graf's addition theorem for Bessel functions and imposing the field continuity conditions at the boundary of each cylinder, we can obtain the polarization-dependent Mie coefficients by solving the linear system [49]:…”

Section: Calculation Of Electromagnetic Quasimodes In Real Spacementioning

confidence: 99%

“…where n indicates the n th -cylinder and is the multipolar order of the cylindrical Bessel J (x) and Hankel H (x) functions (x = k 0 r is the size parameter) used in the calculations [48,49].…”

Section: Calculation Of Electromagnetic Quasimodes In Real Spacementioning

confidence: 99%

Section: Calculation Of Electromagnetic Quasimodes In Real Spacementioning

confidence: 99%

“…Calculating the resonant electromagnetic quasimodes requires solving the homogeneous equation Tb = 0 [15,[48][49][50][51]. Specifically, we have to find the complex k values for which the relation det T( k) = 0 is satisfied [49]. The complex eigenvalue k has a direct physical interpretation, namely its real part is equal to the freespace wave number of the mode while its imaginary part describes the decay rate of the mode, which is also inversely proportional to its spectral width.…”

Section: Calculation Of Electromagnetic Quasimodes In Real Spacementioning

confidence: 99%

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Structural entropy and spatial decay of quasimodes in Vogel spirals

Prado,

Sgrignuoli,

Chen

et al. 2021

Preprint

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We investigate the spatial and temporal localization properties of quasimodes (i.e. scattering resonances) of two-dimensional Vogel spirals, composed of deterministic, aperiodic arrays of electric dipoles. By determining the structural entropy and localization maps of Vogel spirals using the Green's matrix method, we show that three distinctive decay types of quasimodes coexist in Vogel spirals: exponential, power-law, and gaussian. While the former has been expected to occur in disordered media only, the latter is demonstrated to characterize the most localized quasimodes of Vogel spirals, both spatially (smallest participation ratios) and temporarily (longest lifetimes). These decay forms are demonstrated by a no-fitting analysis of the localization maps, independently corroborated by calculating the electric field in real space, which also provides a direct evidence of the algebraic decay of critical quasimodes. Altogether our findings unveil a rich spectrum of both long-lived and spatially localized quasimodes that coexist in Vogel spirals and can be of direct relevance to novel optical functionalities for applications to light sources and sensing devices.

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