Schrödinger’s red pixel by quasi-bound-states-in-the-continuum

Dong, Zhaogang; Jin, Lei; Rezaei, Soroosh Daqiqeh; Wang, Hao; Chen, Yang; Tjiptoharsono, Febiana; Ho, Jinfa; Gorelik, Sergey; Ng, Ray Jia Hong; Ruan, Qifeng; Qiu, Cheng‐Wei; Yang, Joel K. W.

doi:10.1126/sciadv.abm4512

Cited by 79 publications

(53 citation statements)

References 63 publications

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“…High refractive index nanostructures with Mie resonance are generally termed dielectric nanoantennas, while typical dielectrics consist of silicon (Si), titanium dioxide (TiO 2 ), gallium phosphide (GaP), gallium nitride (GaN), gallium arsenide (GaAs), etc . Moreover, Mie resonances have been extensively investigated for various applications, such as structural colors, − optical holograms, ,, field enhancements, − directionality engineering, ,, and harmonic generations. − …”

Section: Physics and Design Methodologiesmentioning

confidence: 99%

Recent Advances in Tunable Metasurfaces: Materials, Design, and Applications

et al. 2022

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Metasurfaces, a two-dimensional (2D) form of metamaterials constituted by planar meta-atoms, exhibit exotic abilities to tailor electromagnetic (EM) waves freely. Over the past decade, tremendous efforts have been made to develop various active materials and incorporate them into functional devices for practical applications, pushing the research of tunable metasurfaces to the forefront of nanophotonics. Those active materials include phase change materials (PCMs), semiconductors, transparent conducting oxides (TCOs), ferroelectrics, liquid crystals (LCs), atomically thin material, etc., and enable intriguing performances such as fast switching speed, large modulation depth, ultracompactness, and significant contrast of optical properties under external stimuli. Integration of such materials offers substantial tunability to the conventional passive nanophotonic platforms. Tunable metasurfaces with multifunctionalities triggered by various external stimuli bring in rich degrees of freedom in terms of material choices and device designs to dynamically manipulate and control EM waves on demand. This field has recently flourished with the burgeoning development of physics and design methodologies, particularly those assisted by the emerging machine learning (ML) algorithms. This review outlines recent advances in tunable metasurfaces in terms of the active materials and tuning mechanisms, design methodologies, and practical applications. We conclude this review paper by providing future perspectives in this vibrant and fast-growing research field.

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Section: Physics and Design Methodologiesmentioning

confidence: 99%

Recent Advances in Tunable Metasurfaces: Materials, Design, and Applications

et al. 2022

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“…BIC can theoretically produce an infinite radiation Q-factor and lifetime. In practice, BIC can be turned into a "quasi-BIC" or "supercavity mode" by changing attention to the vicinity of the parameter space of BIC [51][52][53], whose Q-factor and resonant bandwidth become finite values, as shown in Figure 1(d). There are two main types of symmetry-breaking methods for quasi-BIC, including structural symmetry (e.g., in-plane asymmetry parameters, α), and excitation field symmetry (e.g., the angle of the incident light).…”

Section: Bound States In the Continuummentioning

confidence: 99%

Resonant Metasurfaces for Spectroscopic Detection: Physics and Biomedical Applications

Liang

Lai

Lou

et al. 2022

Adv Devices Instrum

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Metasurfaces are ultrathin metamaterials consisting of subwavelength scatterers (e.g., meta-atoms) arranged in a specific sequence that generates low radiation losses and fantastic optical resonances. According to the electromagnetic response properties, metasurfaces can be divided into two categories: metallic nanostructures based on the response of plasmonic excitations (e.g., noble metals and graphene) and all-dielectric nanostructures based on near-field scattering (e.g., Mie scattering). Metasurfaces supporting various optical modes possess optical localization and electromagnetic field enhancement capabilities on the subwavelength scale, making them a promising platform for label-free detection in biomedical sensing. Metasurface-based optical sensors offer several outstanding advantages over conventional spectroscopic detection solutions, such as planar structures, low loss, miniaturization, and integration. Recently, novel sensing and even imaging tools based on metasurfaces have widely loomed and been proposed. Given recent advances in the field of metasurface spectroscopic detection, this review briefly summarizes the main resonance mechanisms of metasurfaces and the notable achievements, including refractive index sensing, surface-enhanced Raman scattering, surface-enhanced infrared absorption, and chiral sensing in the ultraviolet to terahertz wavelengths. Ultimately, we draw a summary of the current challenges of metasurface spectroscopic detection and look forward to future directions for improving these techniques. As the subject is broad and growing, our review will not be comprehensive. Nevertheless, we will endeavor to describe the main research in this area and assess some of the relevant literature.

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“…Dielectric optical nanoantennas behave as resonators at optical frequencies by supporting both electric and magnetic dipoles, in addition to higher order modes. − Directional scattering arises when these dipoles interact constructively or destructively, i.e. , fulfilling the first and second Kerker’s conditions, respectively. , Dielectric nanoantennas have been used to demonstrate holograms, − color microprints, ,− miniaturized lasers, , localized field enhancement, hybrid metal-dielectric antenna, high-quality factor resonators, , and optical beam steering. , However, the operating wavelengths in these demonstrations are fixed after fabrication because the optical constants of the chosen high refractive index materials, such as Si, TiO 2 , and GaP, cannot be tuned.…”

Section: Introductionmentioning

confidence: 99%

Reversible Tuning of Mie Resonances in the Visible Spectrum

Dong

Tijiptoharsono

et al. 2021

ACS Nano

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Dielectric optical nanoantennas are promising as fundamental building blocks in next generation color displays, metasurface holograms, and wavefront shaping optical devices. Due to the high refractive index of the nanoantenna material, they support geometry-dependent Mie resonances in the visible spectrum. Although phase change materials, such as the germanium–antimony–tellurium alloys, and post-transition metal oxides, such as ITO, have been used to tune antennas in the near-infrared spectrum, reversibly tuning the response of dielectric antennas in the visible spectrum remains challenging. In this paper, we designed and experimentally demonstrated dielectric nanodisc arrays exhibiting reversible tunability of Mie resonances in the visible spectrum. We achieved tunability by exploiting phase transitions in Sb2S3 nanodiscs. Mie resonances within the nanodisc give rise to structural colors in the reflection mode. Crystallization and laser-induced amorphization of these Sb2S3 resonators allow the colors to be switched back and forth. These tunable Sb2S3 nanoantenna arrays could enable the next generation of high-resolution color displays, holographic displays, and miniature LiDAR systems.

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Schrödinger’s red pixel by quasi-bound-states-in-the-continuum

Cited by 79 publications

References 63 publications

Recent Advances in Tunable Metasurfaces: Materials, Design, and Applications

Recent Advances in Tunable Metasurfaces: Materials, Design, and Applications

Resonant Metasurfaces for Spectroscopic Detection: Physics and Biomedical Applications

Reversible Tuning of Mie Resonances in the Visible Spectrum

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