All-optical tuning of EIT-like dielectric metasurfaces by means of chalcogenide phase change materials

Petronijevic, Emilija; Sibilia, C.

doi:10.1364/oe.24.030411

Cited by 51 publications

(29 citation statements)

References 34 publications

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“…PAS can therefore directly characterize the spectral position and the efficiency of the modes. For a specific application, one can optimize the geometric parameters, e.g., by using methods in [38] or [39]. One of the subjects of ongoing work is the use of the resonant modes for chiral near field formation.…”

Section: Resultsmentioning

confidence: 99%

Resonant Absorption in GaAs-Based Nanowires by Means of Photo-Acoustic Spectroscopy

et al. 2018

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Semiconductor nanowires made of high refractive index materials can couple the incoming light to specific waveguide modes that offer resonant absorption enhancement under the bandgap wavelength, essential for light harvesting, lasing and detection applications. Moreover, the non-trivial ellipticity of such modes can offer near field interactions with chiral molecules, governed by near chiral field. These modes are therefore very important to detect. Here, we present the photo-acoustic spectroscopy as a low-cost, reliable, sensitive and scattering-free tool to measure the spectral position and absorption efficiency of these modes. The investigated samples are hexagonal nanowires with GaAs core; the fabrication by means of lithographyfree molecular beam epitaxy provides controllable and uniform dimensions that allow for the excitation of the fundamental resonant mode around 800 nm. We show that the modulation frequency increase leads to the discrimination of the resonant mode absorption from the overall absorption of the substrate. As the experimental data are in great agreement with numerical simulations, the design can be optimized and followed by photo-acoustic characterization for a specific application.

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Section: Resultsmentioning

confidence: 99%

Resonant Absorption in GaAs-Based Nanowires by Means of Photo-Acoustic Spectroscopy

et al. 2018

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“…60 Particularly, a few works have numerically illustrated that the chalcogenide metasurfaces may lead to tunable EIT. [61][62][63] Following these theoretical predictions, the concept of tunable EIT was experimentally verified in a very recent work, which showed that a chalcogenide metasurface can be used to obtain a nonreversible switching of EIT via a thermal annealing system. 64 These previous works showed the promising potential of chalcogenide PCM in reconfigurable EIT metadevices in the optical region.…”

Section: Introductionmentioning

confidence: 90%

Reversible switching of electromagnetically induced transparency in phase change metasurfaces

Mao

et al. 2020

Adv. Photon.

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Metasurface analogue of the phenomenon of electromagnetically induced transparency (EIT) that is originally observed in atomic gases offers diverse applications for new photonic components such as nonlinear optical units, slow-light devices, and biosensors. The development of functional integrated photonic devices requires an active control of EIT in metasurfaces. We demonstrate a reversible switching of the metasurface-induced transparency in the near-infrared region by incorporating a nonvolatile phase change material, Ge 2 Sb 2 Te 5 , into the metasurface design. This leads to an ultrafast reconfigurable transparency window under an excitation of a nanosecond pulsed laser. The measurement agrees well with both theoretical calculation and finite-difference time-domain numerical simulation. Our work paves the way for dynamic metasurface devices such as reconfigurable slow light and biosensing.

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“…Recently, new strategies in view of the EIT or Fano resonances based on all-dielectric metasurfaces were introduced to restrain these losses, which have exhibited great possibility of producing high Q-factor resonances [16]- [32]. A common feature of the EIT-like all-dielectric metasurface demonstrated so far is dependent on multiple interacted structures within the unit cell, such as orthogonal silicon bars [25]- [27], silicon-based bar-ring resonator [28]- [30]. Generally in these resonator systems, one structure is designed to support the bright mode that can directly couple to the free space, the other one is served as a dark or trapped mode, which is less-accessible, or inaccessible from the incident optical field.…”

Section: Introductionmentioning

confidence: 99%

Analogue of Electromagnetically Induced Transparency in an S-Shaped All-Dielectric Metasurface

et al. 2019

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We proposed and numerically investigated an analogue of electromagnetically induced transparency (EIT) all-dielectric metasurface that features one asymmetric S-shaped silicon resonator in the unit cell and generates high transparency, high Q-factor resonance in the near infrared spectral region. Breaking the symmetry of the S-shaped structure could provide a pathway to excite a trapped magnetic mode that coupled to a bright electric dipolar moment, achieving a sharp EIT-like response. And the Q value of the resonance can be easily modified by altering the asymmetric degree of the structure. In particular, the transparency window will almost maintain its symmetric shape and high transmission of 97%, but shift accordingly as the structural parameters (silicon bar's length, width, or thickness) vary in a large range, because of the very small detuning between the two coupled modes. The proposed S-shaped all-dielectric metasurface could ease fabrication challenges and have potential applications in biochemical sensing, narrowband filters, optical modulations, and slow light devices.

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All-optical tuning of EIT-like dielectric metasurfaces by means of chalcogenide phase change materials

Cited by 51 publications

References 34 publications

Resonant Absorption in GaAs-Based Nanowires by Means of Photo-Acoustic Spectroscopy

Resonant Absorption in GaAs-Based Nanowires by Means of Photo-Acoustic Spectroscopy

Reversible switching of electromagnetically induced transparency in phase change metasurfaces

Analogue of Electromagnetically Induced Transparency in an S-Shaped All-Dielectric Metasurface

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