Zilun Gong scite author profile

Featuring high photon energy and short wavelength, ultraviolet (UV) light enables numerous applications such as high-resolution imaging, photolithography, and sensing. In order to manipulate UV light, bulky optics are usually required, and hence do not meet the fast-growing requirements of integration in compact systems. Recently, metasurfaces have shown unprecedented control of light, enabling substantial miniaturization of photonic devices from terahertz to visible regions. However, material challenges have hampered the realization of such functionalities at shorter wavelengths. Herein, it is experimentally demonstrated that all-silicon (Si) metasurfaces with thicknesses of only one-tenth of the working wavelength can be designed and fabricated to manipulate broadband UV light with efficiencies comparable to plasmonic metasurface performance in infrared (IR). Also, for the first time, photolithography enabled by metasurface-generated UV holograms is shown. Such performance enhancement is attributed to increased scattering cross sections of Si antennas in the UV range, which is adequately modeled via a circuit. The new platform introduced here will deepen the understanding of light-matter interactions and introduce even more material options to broadband metaphotonic applications, including those in integrated photonics and holographic lithography technologies.

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Tunable Second Harmonic Generation in Twisted Bilayer Graphene

Song

Meng

Luo

et al. 2020

Matter

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Phase change materials in photonic devices

Gong

Wang

Chen

et al. 2021

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Recent developments in reconfigurable photonic devices highly rely on the effective refractive index change enabled by phase change materials (PCMs) as either dielectric surroundings or constituting materials. This universal characteristic, tunable refractive index, is shared among various kinds of PCMs and has been successfully utilized to achieve multilevel modulations for both free-space and integrated photonics. In this Perspective, we briefly recapitulate the fundamental mechanisms of phase transitions for three dominant PCMs. The progress in integrating different PCMs with on-chip silicon photonics and periodic antenna arrays are reviewed and analyzed in parallel. We also discuss the existing problems of PCM photonics, for example, the compatibility with commercial production line, the stability issue, and accessibility of the stimuli. In the end, we provide the outlook for the improving material engineering of PCM and multi-functional PCM-based photonics devices.

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3D nitrogen-doped graphene/Co(OH)₂-nanoplate composites for high-performance electrochemical pseudocapacitors

et al. 2014

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Excitation and propagation of surface plasmon polaritons on a non-structured surface with a permittivity gradient

Wang

Deng

et al. 2016

Light Sci Appl

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Accompanied by the rise of plasmonic materials beyond those based on noble metals and the development of advanced materials processing techniques, it is important to understand the plasmonic behavior of materials with large-scale inhomogeneity (such as gradient permittivity materials) because they cannot be modeled simply as scatterers. In this paper, we theoretically analyze the excitation and propagation of surface plasmon polaritons (SPPs) on a planar interface between a homogeneous dielectric and a material with a gradient of negative permittivity. We demonstrate the following: (i) free-space propagating waves and surface waves can be coupled by a gradient negative-permittivity material and (ii) the coupling can be enhanced if the material permittivity variation is suitably designed. This theory is then verified by numerical simulations. A direct application of this theory, ‘rainbow trapping’, is also proposed, considering a realistic design based on doped indium antimonide. This theory may lead to various applications, such as ultracompact spectroscopy and dynamically controllable generation of SPPs.

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Zilun Gong

All‐Silicon Broadband Ultraviolet Metasurfaces

Tunable Second Harmonic Generation in Twisted Bilayer Graphene

Phase change materials in photonic devices

3D nitrogen-doped graphene/Co(OH)₂-nanoplate composites for high-performance electrochemical pseudocapacitors

Excitation and propagation of surface plasmon polaritons on a non-structured surface with a permittivity gradient

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Zilun Gong

All‐Silicon Broadband Ultraviolet Metasurfaces

Tunable Second Harmonic Generation in Twisted Bilayer Graphene

Phase change materials in photonic devices

3D nitrogen-doped graphene/Co(OH)2-nanoplate composites for high-performance electrochemical pseudocapacitors

Excitation and propagation of surface plasmon polaritons on a non-structured surface with a permittivity gradient

Contact Info

Product

Resources

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3D nitrogen-doped graphene/Co(OH)₂-nanoplate composites for high-performance electrochemical pseudocapacitors