Large and bistable Goos–Hänchen shifts from the Kretschmann configuration with a nonlinear negative–zero–positive index metamaterial

Wang, Xinglin; Jiang, Anquan; Zheng, Fanong

doi:10.1088/2040-8978/16/4/045101

Cited by 7 publications

(6 citation statements)

References 50 publications

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“…236,237 The behaviors of Dirac points in monolayer graphene can be mimicked with nonlinear negativezero-positive index metamaterials to obtain tunable bandgaps via self-focusing and self-defocusing of nonlinear surface waves 238,239 and large bistable Goos−Hanchen shifts. 240 In 2D TMDs such as MoS 2 , 241,242 MoSe 2 , 243 WSe 2 , 157,244 and WS 2 , 245 inversion symmetry is broken and can support SHG. Their second-harmonic susceptibilities can be as large as approximately nm/V, which is substantially larger than those of traditional nonlinear photonic crystals (PCs).…”

Section: Optical Transitions In Layered 2d Materials For Advance Meta...supporting

confidence: 85%

“…Associated third-harmonic phenomena can be easily tuned by applying a gate voltage or varying the input field intensity to change the refractive index of graphene, which creates possibilities for tunable metadevices. For example, nonlinear graphene–dielectric layered metamaterials can be exploited to reshape the light pulse and achieve ultralow-power all-optical active manipulation of metamaterial induced transparency regardless of the polarization, , to demonstrate all-optical switching of optical bistability or multistability and other effects. , The behaviors of Dirac points in monolayer graphene can be mimicked with nonlinear negative-zero-positive index metamaterials to obtain tunable bandgaps via self-focusing and self-defocusing of nonlinear surface waves , and large bistable Goos–Hanchen shifts …”

Section: Optical Properties Of Layered 2d Materials To Inspire Metama...mentioning

confidence: 99%

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Artificial Metaphotonics Born Naturally in Two Dimensions

Dai

et al. 2020

Chem. Rev.

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Recently, two rich and exciting research fields, layered two-dimensional (2D) materials and metamaterials, have started overlapping. Metamaterials are artificial, engineered materials with broad metaphotonic prospects such as negative refraction, perfect lensing, subwavelength imaging, and cloaking. The possibility of achieving metaphotonic properties using metamaterials based on layered 2D materials has been extensively exploited. Because they are highly tunable and adjustable with the ease of micro-and nanofabrication, 2D materials exhibit diverse optical properties such as natural negative refraction, natural anisotropic behavior, and even hyperbolic dispersion. A combination of 2D materials with conventional metamaterials promises a variety of prospective applications. In this review, we illustrate how the concept of metamaterials and their associated metaphotonic capabilities are naturally born in 2D materials. The multifunctionality of 2D materials may enable the manufacture of novel optical devices that work in a broad frequency range, from visible to terahertz, with particularly low loss, high speed, gated tunability, and miniaturized sizes. This new area of research links the fields of photonics, optoelectronics, and plasmonics with that of metamaterials and may provide insights to future innovations for 2D-material-inspired metaphotonic devices.

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Section: Optical Transitions In Layered 2d Materials For Advance Meta...supporting

confidence: 85%

Section: Optical Properties Of Layered 2d Materials To Inspire Metama...mentioning

confidence: 99%

Artificial Metaphotonics Born Naturally in Two Dimensions

Dai

et al. 2020

Chem. Rev.

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“…Most recently, our group [4] experimentally observed the inverse Doppler Effect in negatively refractive PhC (NRPhC) at optical frequency; this study was an important breakthrough in the study of PhC and provided a basis for further exploration of exceptional phenomena in 2D-NRPhC [5]. Another exceptional phenomenon regarding NRPhC is the inverse Goos-Hä nchen effect [6,7] occurring at the interface between normal material (e.g., air) and NRPhC. As is well known, when a bounded wave beam is incident from an optically denser medium to a medium less optical dense at critical angle, the centre of reflected beam undergoes a sizable lateral shift from the position predicted by geometrical optics: This is the Goos-Hä nchen (GH) shift [8].…”

Section: Introductionmentioning

confidence: 94%

Influence of surface termination on inverse Goos–Hänchen shift of negatively refractive photonic crystals

Hu¹,

Liang²,

Chen³

et al. 2016

J. Opt.

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The effect of surface termination on the inverse Goos-Hä nchen (GH) shift of two-dimensional (2D) negatively refractive photonic crystal (NRPhC) containing air holes arranged in hexagonal lattice in a dielectric background is investigated for TM polarization. Results show that the magnitude of the inverse GH shift of 2D-NRPhC strongly depends on surface termination even for an incident beam with a fixed frequency and incidence angle. Further study by calculating the dispersion of surface mode of 2D-NRPhC as a function of surface termination reveals that 2D-NRPhC presents large inverse Goos-Hä nchen shift at those terminations where surface mode is excited, that is, large inverse Goos-Hä nchen shift originates from backward surface mode of 2D-NRPhC. In addition, the coupling coefficient of incident field into the field of surface mode as a function of surface termination is studied and demonstrates above results. This paper provides technical information regarding the combination of various functional photonic elements in the design of integrated optical circuits.

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“…Имеется ряд публикаций [67][68][69][70][71][72][73][74], в которых авторы рассуждают об отрицательном GH-сдвиге. Большинство этих работ -теоретические, т. е. авторы моделируют отрицательный GH-сдвиг в различных средах (поглощающие среды, Me поверхности) и под различными углами падения.…”

Section: эффект гуса-хенхенunclassified

“…There are a number of publications [67][68][69][70][71][72][73][74] where the authors argue on negative GH shift. The majority of these works is theoretical, i. e. authors model negative GH shift in different mediums (absorbing mediums, Me surfaces) and under different incidence angles.…”

Section: Goos-hänchen Effectmentioning

confidence: 99%

Metamaterials: Myth Or Reality? "Reverse" Refractive Index. Part 3

Потапов¹

2017

FRos

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Large and bistable Goos–Hänchen shifts from the Kretschmann configuration with a nonlinear negative–zero–positive index metamaterial

Cited by 7 publications

References 50 publications

Artificial Metaphotonics Born Naturally in Two Dimensions

Artificial Metaphotonics Born Naturally in Two Dimensions

Influence of surface termination on inverse Goos–Hänchen shift of negatively refractive photonic crystals

Metamaterials: Myth Or Reality? "Reverse" Refractive Index. Part 3

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