Anomalies in light scattering

Krasnok, Alex; Baranov, Denis G.; Li, Huanan; Miri, Mohammad‐Ali; Monticone, Francesco; Alù, Andrea

doi:10.1364/aop.11.000892

Cited by 191 publications

(195 citation statements)

References 380 publications

(455 reference statements)

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“…[ 24–30 ] The idea can be traced back to the concept of coherent perfect absorption (CPA), which refers to an optical device that can absorb all incident energy provided that it corresponds to a scattering matrix eigenstate with zero eigenvalue. [ 31 ] In a two‐port system, this corresponds to an excitation with two counter‐propagating coherent beams with proper amplitude and relative phase, which interfere constructively within the structure. [ 24 ] Based on this concept, coherent wave manipulation has been proposed in various systems, finding potential applications even down to the single‐photon level.…”

Section: Figurementioning

confidence: 99%

Coherent Perfect Diffraction in Metagratings

et al. 2020

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Metasurfaces are 2D engineered structures with subwavelength granularity, offering a wide range of opportunities to tailor the impinging wavefront. However, fundamental limitations on their efficiency in wave transformation, associated with their deeply subwavelength thickness, challenge their implementation in practical application scenarios. Here, it is shown how the coherent control of metagratings through multiple wave excitations can provide new opportunities to achieve highly reconfigurable broadband metasurfaces with large diffraction efficiency, beyond the limitations of conventional approaches. Remarkably, energy distribution between the 0th and higher diffraction orders can be continuously tuned by changing the relative phase difference between two excitation waves, enabling coherent control, with added benefits of enhanced efficiency and bandwidth. This concept is demonstrated for a thin electric metagrating operating at terahertz frequencies, showing that coherent control can overcome several of the limitations of single‐layer ultrathin metastructures, and extend their feasibility in various practical scenarios.

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Section: Figurementioning

confidence: 99%

Coherent Perfect Diffraction in Metagratings

et al. 2020

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“…For better understanding of the anomalies reported here, it is useful to place them among the known scattering phenomena. Krasnok et al [14] have recently provided a thorough classification of diverse scattering anomalies on the basis of zeros and poles in the S-matrix Hamiltonians and scattering coefficients, using the notion of complex eigenfrequencies rather than complex eigenpolarizabilities. The divergence of scattering coefficients presented in our work corresponds exactly to the scenario in which a pole in the scattering coefficient intersects with the real frequency axis due to the balance between the gain of the system's eigenmode and its outcoupling loss.…”

Section: Classification Of the Scattering Anomaliesmentioning

confidence: 99%

“…For instance, properly engineered gain and loss could overcome efficiency barriers of metasurfaces for wavefront transformation imposed by impedance mismatch [8,9], mitigate constraints on electric and magnetic optical response of matter [10,11], and control the scattering by small ensembles of nano-objects [12,13]. The interplay between gain and loss gives rise to many scattering anomalies [14], such as unidirectional invisibility, coherent perfect absorber-lasers, as well as manifestations of parity-time (PT) symmetry [15][16][17], offering a platform for active control of light propagation [18][19][20] and for enhanced light-matter interactions [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Gain-induced scattering anomalies of diffractive metasurfaces

Kołkowski

Koenderink

2020

Nanophotonics

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Photonic nanostructures with gain and loss have long been of interest in the context of diverse scattering anomalies and light-shaping phenomena. Here, we investigate the scattering coefficients of simple gain-doped diffractive metasurfaces, revealing pairs of scattering anomalies surrounded by phase vortices in frequency–momentum space. These result from an interplay between resonant gain, radiative loss, and interference effects in the vicinity of Rayleigh anomalies. We find similar vortices and singular points of giant amplification in angle-resolved reflectivity spectra of prism-coupled gain slabs. Our findings could be of interest for gain-induced wavefront shaping by all-dielectric metasurfaces, possibly employing gain coefficients as low as ∼50 cm−1.

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“…The exceptional point (EP) in a non-Hermitian system occurs when eigenstates coalesce [1][2][3], and usually associates with the non-Hermitian phase transition [4,5]. In a parity-time (PT ) symmetric non-Hermitian coupled system, the PT symmetry of eigenstates spontaneously breaks at the EP [6][7][8][9][10][11][12][13][14][15][16], which determines the exact PTsymmetric phase and the broken PT -symmetric phase in this system.…”

Section: Introductionmentioning

confidence: 99%

High-order exceptional points in supersymmetric arrays

Zhang

Jin

et al. 2020

Phys. Rev. A

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We employ the intertwining operator technique to synthesize a supersymmetric (SUSY) array of arbitrary size N . The synthesized SUSY system is equivalent to a spin-(N − 1)/2 under an effective magnetic field. By considering an additional imaginary magnetic field, we obtain a generalized parity-time-symmetric non-Hermitian Hamiltonian that describes a SUSY array of coupled resonators or waveguides under a gradient gain and loss; all the N energy levels coalesce at an exceptional point (EP), forming the isotropic high-order EP with N states coalescence (EPN). Near the EPN, the scaling exponent of phase rigidity for each eigenstate is (N − 1)/2; the eigen frequency response to the perturbation acting on the resonator or waveguide couplings is 1/N . Our findings reveal the importance of the intertwining operator technique for the spectral engineering and exemplify the practical application in non-Hermitian physics. arXiv:2003.07510v1 [quant-ph]

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Anomalies in light scattering

Cited by 191 publications

References 380 publications

Coherent Perfect Diffraction in Metagratings

Coherent Perfect Diffraction in Metagratings

Gain-induced scattering anomalies of diffractive metasurfaces

High-order exceptional points in supersymmetric arrays

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