Near-flat top bandpass filter based on non-local resonance in a dielectric metasurface

Changhyun Lee; Sangtae Jeon; Seong Jun Kim; Soo Jin Kim

doi:10.1364/OE.480757

Near-flat top bandpass filter based on non-local resonance in a dielectric metasurface

Changhyun Lee, Sangtae Jeon, Seong Jun Kim, Soo Jin Kim

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

Localized light matter interaction at a resonant nanostructure facilitates spectrally selective transmission of light, which has led to demonstrations of ultrathin metasurface based optical filters. Unfortunately, due to the nature of Lorentzian spectral line shape in such resonances, it is inevitable to suffer significant spectral crosstalk. In this work, we demonstrate a conceptually new type of spectral filter which exhibits near flat-top bandpass with minimized spectral overlaps. To realize this, we leverage the recent development of non-local resonance in dielectric nanostructure to design a double-layered optical filter with performance comparable to the ideal spectral filters. The designed metasurface shows averaged transmission of more than 90% across the target spectral band and suppressed transmission of less than 10% out of the spectral band.

Original language	English
Pages (from-to)	4920-4931
Number of pages	12
Journal	Optics Express
Volume	31
Issue number	3
DOIs	https://doi.org/10.1364/OE.480757
Publication status	Published - 2023 Jan 30

Bibliographical note

Publisher Copyright:
© 2023 Optica Publishing Group.

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1364/OE.480757

Cite this

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abstract = "Localized light matter interaction at a resonant nanostructure facilitates spectrally selective transmission of light, which has led to demonstrations of ultrathin metasurface based optical filters. Unfortunately, due to the nature of Lorentzian spectral line shape in such resonances, it is inevitable to suffer significant spectral crosstalk. In this work, we demonstrate a conceptually new type of spectral filter which exhibits near flat-top bandpass with minimized spectral overlaps. To realize this, we leverage the recent development of non-local resonance in dielectric nanostructure to design a double-layered optical filter with performance comparable to the ideal spectral filters. The designed metasurface shows averaged transmission of more than 90% across the target spectral band and suppressed transmission of less than 10% out of the spectral band.",

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AU - Jeon, Sangtae

AU - Kim, Seong Jun

AU - Kim, Soo Jin

PY - 2023/1/30

Y1 - 2023/1/30

N2 - Localized light matter interaction at a resonant nanostructure facilitates spectrally selective transmission of light, which has led to demonstrations of ultrathin metasurface based optical filters. Unfortunately, due to the nature of Lorentzian spectral line shape in such resonances, it is inevitable to suffer significant spectral crosstalk. In this work, we demonstrate a conceptually new type of spectral filter which exhibits near flat-top bandpass with minimized spectral overlaps. To realize this, we leverage the recent development of non-local resonance in dielectric nanostructure to design a double-layered optical filter with performance comparable to the ideal spectral filters. The designed metasurface shows averaged transmission of more than 90% across the target spectral band and suppressed transmission of less than 10% out of the spectral band.

AB - Localized light matter interaction at a resonant nanostructure facilitates spectrally selective transmission of light, which has led to demonstrations of ultrathin metasurface based optical filters. Unfortunately, due to the nature of Lorentzian spectral line shape in such resonances, it is inevitable to suffer significant spectral crosstalk. In this work, we demonstrate a conceptually new type of spectral filter which exhibits near flat-top bandpass with minimized spectral overlaps. To realize this, we leverage the recent development of non-local resonance in dielectric nanostructure to design a double-layered optical filter with performance comparable to the ideal spectral filters. The designed metasurface shows averaged transmission of more than 90% across the target spectral band and suppressed transmission of less than 10% out of the spectral band.

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Near-flat top bandpass filter based on non-local resonance in a dielectric metasurface

Abstract

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