Non‐Hermitian Control of Topological Scattering Singularities Emerging from Bound States in the Continuum

Sakotic, Zarko; Stanković, P.; Bengin, Vesna; Krasnok, Alex; Alù, Andrea; Janković, Nikolina

doi:10.1002/lpor.202200308

Cited by 21 publications

(22 citation statements)

References 85 publications

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“…Fig. 2b shows that the pole and zero possess opposite topological charges, suggesting they could merge if material losses were ignored 34 . Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Additionally, the optical response of α-MoO3 bilayers within this frequency range presents an epsilon-near-zero (ENZ) regime, providing exceptional control over light scattering 29,30 . It has been shown that ENZ materials consisting of multiple layers can support embedded eigenstates (EE), also known as bound states in the continuum, with incredibly high Q-factors [31][32][33][34] . All these distinct properties make α-MoO3 particularly compelling for thermal emission engineering applications.…”

mentioning

confidence: 99%

“…= , as it exhibits negligible losses in the considered frequency range. The dielectric thickness 8.9 D h = µm is selected so that the Fabry-Pérot resonance of the layer corresponds to the frequency , Tx  , following the recent works[31][32][33][34] . The bottom layer is rotated relative to the top layer, with[0 90] = representing the angle of twist.…”

mentioning

confidence: 99%

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Embedded Eigenstate Enables Perfect Absorption Tunable with Twist

Chistyakov

Krasnok

2021

2021 Fifteenth International Congress on Artificial Materials for Novel Wave Phenomena (Metamaterials)

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The field of thermal emission engineering shows great potential for various applications, such as lighting, energy harvesting, and imaging, using natural or artificial structures. However, existing structures face challenges in fabrication or do not provide the necessary degree of control over key parameters such as emission intensity, spectral composition, and angular distribution. To address these limitations, we propose a novel approach that leverages in-plane hyperbolic response, embedded eigenstates enabled by epsilon-near-zero, and exceptional tunability through twisting in α-MoO3

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“…Fig. 2b shows that the pole and zero possess opposite topological charges, suggesting they could merge if material losses were ignored 34 . Fig.…”

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

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Embedded Eigenstate Enables Perfect Absorption Tunable with Twist

Chistyakov

Krasnok

2021

2021 Fifteenth International Congress on Artificial Materials for Novel Wave Phenomena (Metamaterials)

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“…Topological concepts are essential in explaining and predicting unique phenomena like bound states in the continuum (BIC) also known as an embedded eigenstate. BIC is an eigenmode of an optically open system that exhibits an unbounded radiative Q-factor, even though it lies within the continuum of unbounded states. ,− BIC can be realized in symmetry-protected scenarios, such as a hedgehog-like arrangement of dipole polarization along a sphere , or over a plane, or by exploiting the destructive interference between at least two strongly coupled resonant modes linked to the same radiation channel. ,− More recently, the topological scattering features of BIC were discussed in nonperiodic, planar reflective structures using epsilon-near-zero (ENZ) and epsilon-near-pole (ENP) materials, , which was also leveraged in acoustic and nonreciprocal electromagnetic systems . The ENZ resonances are commonly found in isotropic, anisotropic, and 2D materials, such as InAs, ITO, SiC, α-MoO 3 , and hBN.…”

Section: Miscellaneous Topics On Topological Metamaterialsmentioning

confidence: 99%

“…543,1121−1130 BIC can be realized in symmetry-protected scenarios, such as a hedgehoglike arrangement of dipole polarization along a sphere 1122,1124 or over a plane, 1127 or by exploiting the destructive interference between at least two strongly coupled resonant modes linked to the same radiation channel. 1121,1131−1138 More recently, the topological scattering features of BIC were discussed in nonperiodic, planar reflective structures using epsilon-nearzero (ENZ) and epsilon-near-pole (ENP) materials, 1128,1139 which was also leveraged in acoustic 1140 and nonreciprocal electromagnetic systems. 1141 The ENZ resonances are commonly found in isotropic, anisotropic, and 2D materials, such as InAs, ITO, SiC, α-MoO 3 , and hBN.…”

Section: Topological Properties Of Scattering Anomaliesmentioning

confidence: 99%

Topological Metamaterials

Yves

Krasnok

et al. 2023

Chem. Rev.

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The topological properties of an object, associated with an integer called the topological invariant, are global features that cannot change continuously but only through abrupt variations, hence granting them intrinsic robustness. Engineered metamaterials (MMs) can be tailored to support highly nontrivial topological properties of their band structure, relative to their electronic, electromagnetic, acoustic and mechanical response, representing one of the major breakthroughs in physics over the past decade. Here, we review the foundations and the latest advances of topological photonic and phononic MMs, whose nontrivial wave interactions have become of great interest to a broad range of science disciplines, such as classical and quantum chemistry. We first introduce the basic concepts, including the notion of topological charge and geometric phase. We then discuss the topology of natural electronic materials, before reviewing their photonic/phononic topological MM analogues, including 2D topological MMs with and without time-reversal symmetry, Floquet topological insulators, 3D, higher-order, non-Hermitian and nonlinear topological MMs. We also discuss the topological aspects of scattering anomalies, chemical reactions and polaritons. This work aims at connecting the recent advances of topological concepts throughout a broad range of scientific areas and it highlights opportunities offered by topological MMs for the chemistry community and beyond.

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Covert Scattering Control in Metamaterials with Non‐Locally Encoded Hidden Symmetry

Sol,

Röntgen,

del Hougne

2023

Advanced Materials

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Symmetries and tunability are of fundamental importance in wave scattering control, but symmetries are often obvious upon visual inspection which constitutes a significant vulnerability of metamaterial wave devices to reverse‐engineering risks. Here, it is theoretically and experimentally shown that a symmetry in the reduced basis of the “primary meta‐atoms” that are directly connected to the outside world is sufficient; meanwhile, a suitable topology of non‐local interactions between them, mediated by the internal “secondary” meta‐atoms, can hide the symmetry from sight in the canonical basis. Covert symmetry‐based scattering control in a cable‐network metamaterial featuring a hidden parity () symmetry in combination with hidden‐‐symmetry‐preserving and hidden‐‐symmetry‐breaking tuning mechanisms is experimentally demonstrated. Physical‐layer security in wired communications is achieved, using the domain‐wise hidden ‐symmetry as shared secret between the sender and the legitimate receiver. Within the approximation of negligible absorption, the first tuning of a complex scattering metamaterial without mirror symmetry to feature exceptional points (EPs) of ‐symmetric reflectionless states, as well as quasi‐bound states in the continuum, is reported. These results are reproduced in metamaterials involving non‐reciprocal interactions between meta‐atoms, including the first observation of reflectionless EPs in a non‐reciprocal system.This article is protected by copyright. All rights reserved

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Non‐Hermitian Control of Topological Scattering Singularities Emerging from Bound States in the Continuum

Cited by 21 publications

References 85 publications

Embedded Eigenstate Enables Perfect Absorption Tunable with Twist

Embedded Eigenstate Enables Perfect Absorption Tunable with Twist

Topological Metamaterials

Covert Scattering Control in Metamaterials with Non‐Locally Encoded Hidden Symmetry

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