Near-Field Coupling and Mode Competition in Multiple Anapole Systems

Mazzone, Valerio; Gongora, Juan Sebastian Totero; Fratalocchi, Andrea

doi:10.3390/app7060542

Cited by 29 publications

(32 citation statements)

References 29 publications

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“…Complex wave mixing effects were also considered by using non radiating states in [128], which reported Four Wave Mixing (FWM) in a similar structure of [109], and composed of a germanium nanodisk (200 nm of thickness and 625 nm of radius) in which two incident waves at different frequencies ( 1 and 2 ) give rise to four waves (3 1 , [38,117,[121][122][123][124].…”

Section: Nonlinear Harmonic Generationmentioning

confidence: 99%

Nonradiating photonics with resonant dielectric nanostructures

et al. 2019

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Nonradiating sources of energy have traditionally been studied in quantum mechanics and astrophysics, while receiving a very little attention in the photonics community. This situation has changed recently due to a number of pioneering theoretical studies and remarkable experimental demonstrations of the exotic states of light in dielectric resonant photonic structures and metasurfaces, with the possibility to localize efficiently the electromagnetic fields of high intensities within small volumes of matter. These recent advances underpin novel concepts in nanophotonics, and provide a promising pathway to overcome the problem of losses usually associated with metals and plasmonic materials for the efficient control of the light-matter interaction at the nanoscale. This review paper provides the general background and several snapshots of the recent results in this young yet prominent research field, focusing on two types of nonradiating states of light that both have been recently at the center of many studies in all-dielectric resonant meta-optics and metasurfaces: optical anapoles and photonic bound states in the continuum. We discuss a brief history of these states in optics, their underlying physics and manifestations, and also emphasize their differences and similarities. We also review some applications of such novel photonic states in both linear and nonlinear optics for the nanoscale field enhancement, a design of novel dielectric structures with high-resonances, nonlinear wave mixing and enhanced harmonic generation, as well as advanced concepts for lasing and optical neural networks. arXiv:1903.04756v1 [physics.optics]

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Section: Nonlinear Harmonic Generationmentioning

confidence: 99%

Nonradiating photonics with resonant dielectric nanostructures

et al. 2019

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“…Primarily, because of the ability to concentrate strong electromagnetic fields inside a point nonradiating source or scatterer and ensuring the suppression of radiation in an external field. Therefore, metamaterials with anapole mode demonstrated extremely high Q‐factor so that manifested themselves as perfect resonator …”

Section: Introductionmentioning

confidence: 99%

“…Therefore, metamaterials with anapole mode demonstrated extremely high Q-factor so that manifested themselves as perfect resonator. [21][22][23][24][25][26][27][28][29][30] All these properties lead to extensive research of all-dielectric and, particularly, silicon metamaterials and their many applications. 2D metamaterials or metasurfaces stand out due to the simplicity of fabrication and exhibits desirable optical properties.…”

Section: Introductionmentioning

confidence: 99%

Anapole Mode Sustaining Silicon Metamaterials in Visible Spectral Range

Ospanova

Stenishchev

Basharin

2018

Laser & Photonics Reviews

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This paper is dedicated to a type of perforated silicon metamaterials, possessing anapole mode in visible spectral range due to destructive interference between electric and toroidal dipole moments. The proposed structure gains both in attainable material and simplified fabrication. Such a material exhibits a desirable physical effect and has obvious practical application: it supports the anapole mode without complicated 3D toroidal geometry and can be processed in one step by nanofabrication methods. The metamaterial paves the way for advanced optical devices on the base of all‐dielectric metamaterials. Besides inherently low dissipative losses and strong anapole response, such an optical metamaterial can demonstrate subtle sensing, nonradiative data transfer, Aharonov‐Bohm effect and other tempting applications in nanophotonics.

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“…Namely, poloidal currents, flowing along the meridians on the torus‐like objects, generate magnetic moments that circulate inside the torus, and altogether they create toroidal moments oscillating along the torus main axis . Apparently, the main interest on toroidal moment is underpinned by their contribution to more promising anapole mode excitations that take place due to destructive interference between electric and toroidal multipoles of the same order, leading to such effects as strong field localization inside the even point‐like sources and invisibility to external observer . The works of the last decade point out to feasibility of this effect in structures from microwaves to optics and demonstrate such effects as novel types of transparency, optical invisibility, and cloaking .…”

Section: Introductionmentioning

confidence: 99%

“…[14][15][16][17][18][19][20][21][22] Apparently, the main interest on toroidal moment is underpinned by their contribution to more promising anapole mode excitations that take place due to destructive interference between electric and toroidal multipoles of the same order, leading to such effects as strong field localization inside the even point-like sources and invisibility to external observer. [10][11][12][13]17,[23][24][25][26][27][28][29][30][31][32] The works of the last decade point out to feasibility of this effect in structures from microwaves to optics and demonstrate such effects as novel types of transparency, [23] optical invisibility, [27,33] and cloaking. [34] These properties are promising since they open the way to novel sensing, modulating techniques, switching possibility between multipoles, high Q-factor resonance of Fano types, and demonstration of planar THz metamaterials as 2D Ising model.…”

Section: Introductionmentioning

confidence: 99%

Toroidal Dipole Mode Observation In Situ

Pavlov

Stenishchev

Ospanova

et al. 2019

Physica Status Solidi (b)

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Besides classical dipole moments, the metaparticles are characterized by toroidal dipole moments that are important for numerous applications ranging from strong field localizations to anapole modes and the dynamic Aharonov–Bohm effect. On the other hand, the toroidal and electric dipole radiation are undistinguished by external observers due to identical radiation patterns. Therefore, the importance of toroidal dipole moments in multipole expansion is questioned by many researchers. However, a long‐awaited unanswered question is—what is going on inside a toroidal metamolecule and is its near‐field distribution distinct from the electric dipole field? Herein, the toroidal dipole mode is experimentally confirmed in situ by proof‐of‐concept measurements of electric and magnetic fields inside properly fabricated water metamolecules with toroidal topology in the microwave frequency range.

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Near-Field Coupling and Mode Competition in Multiple Anapole Systems

Cited by 29 publications

References 29 publications

Nonradiating photonics with resonant dielectric nanostructures

Nonradiating photonics with resonant dielectric nanostructures

Anapole Mode Sustaining Silicon Metamaterials in Visible Spectral Range

Toroidal Dipole Mode Observation In Situ

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