Simultaneous Full‐Color Printing and Holography Enabled by Centimeter‐Scale Plasmonic Metasurfaces

Simultaneous Full‐Color Printing and Holography Enabled by Centimeter‐Scale Plasmonic Metasurfaces

Optical metasurfaces enable novel ways to locally manipulate light's amplitude, phase, and polarization, underpinning a newly viable technology for applications, such as high‐density optical storage, holography, and displays. Here, a high‐security‐level platform enabled by centimeter‐scale plas...

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Veröffentlicht in:Advanced science 2020-05, Vol.7 (10), p.1903156-n/a, Article 1903156
Hauptverfasser: Zhang, Fei, Pu, Mingbo, Gao, Ping, Jin, Jinjin, Li, Xiong, Guo, Yinghui, Ma, Xiaoliang, Luo, Jun, Yu, Honglin, Luo, Xiangang
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Chemistry
Chemistry, Multidisciplinary
Color
holograms
Identification
Lasers
Light
Materials Science
Materials Science, Multidisciplinary
metasurfaces
Nanoscience & Nanotechnology
Physical Sciences
plasmonics
Science & Technology
Science & Technology - Other Topics
structural colors
Technology
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container_issue 10
container_start_page 1903156
container_title Advanced science
container_volume 7
creator Zhang, Fei
Pu, Mingbo
Gao, Ping
Jin, Jinjin
Li, Xiong
Guo, Yinghui
Ma, Xiaoliang
Luo, Jun
Yu, Honglin
Luo, Xiangang
description Optical metasurfaces enable novel ways to locally manipulate light's amplitude, phase, and polarization, underpinning a newly viable technology for applications, such as high‐density optical storage, holography, and displays. Here, a high‐security‐level platform enabled by centimeter‐scale plasmonic metasurfaces with full‐color, high‐purity, and enhanced‐information‐capacity properties is proposed. Multiple types of independent information can be embedded into a single metamark using full parameters of light, including amplitude, phase, and polarization. Under incoherent white light, the metamark appears as a polarization‐ and angle‐encoded full‐color image with flexibly controlled hue, saturation, and brightness, while switching to multiwavelength holograms under coherent laser illumination. More importantly, for actual applications, the extremely shallow functional layer makes such centimeter‐scale plasmonic metamarks suitable for cost‐effective mass production processes. Considering these superior performances of the presented multifunctional plasmonic metasurfaces, this work may find wide applications in anticounterfeiting, information security, high‐density optical storage, and so forth. Both full‐color printing and holography can be realized by a single ultrathin plasmonic metasurface. Under incoherent white light, the proposed centimeter‐scale metasurface appears as a polarization‐ and angle‐encoded full‐color image with flexibly controlled hue, saturation, and brightness, while switching to multiwavelength holograms under coherent laser illumination. More importantly, such metamarks allow large‐area and mass production at low cost.
doi_str_mv 10.1002/advs.201903156
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Here, a high‐security‐level platform enabled by centimeter‐scale plasmonic metasurfaces with full‐color, high‐purity, and enhanced‐information‐capacity properties is proposed. Multiple types of independent information can be embedded into a single metamark using full parameters of light, including amplitude, phase, and polarization. Under incoherent white light, the metamark appears as a polarization‐ and angle‐encoded full‐color image with flexibly controlled hue, saturation, and brightness, while switching to multiwavelength holograms under coherent laser illumination. More importantly, for actual applications, the extremely shallow functional layer makes such centimeter‐scale plasmonic metamarks suitable for cost‐effective mass production processes. Considering these superior performances of the presented multifunctional plasmonic metasurfaces, this work may find wide applications in anticounterfeiting, information security, high‐density optical storage, and so forth. 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subjects Chemistry
Chemistry, Multidisciplinary
Color
holograms
Identification
Lasers
Light
Materials Science
Materials Science, Multidisciplinary
metasurfaces
Nanoscience & Nanotechnology
Physical Sciences
plasmonics
Science & Technology
Science & Technology - Other Topics
structural colors
Technology
title Simultaneous Full‐Color Printing and Holography Enabled by Centimeter‐Scale Plasmonic Metasurfaces
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