Metasurface Device with Helicity-Dependent Functionality

Dandan Wen; Shumei Chen; Fuyong Yue; Kinlong Chan; Ming Chen; Marcus Ardron; King Fai Li; Polis Wing Han Wong; Kok Wai Cheah; Edwin Yue Bun Pun; Guixin Li; Shuang Zhang; Xianzhong Chen

doi:10.1002/adom.201500498

Metasurface Device with Helicity-Dependent Functionality

Dandan Wen, Shumei Chen, Fuyong Yue, Kinlong Chan, Ming Chen, Marcus Ardron, King Fai Li, Polis Wing Han Wong, Kok Wai Cheah, Edwin Yue Bun Pun, Guixin Li^*, Shuang Zhang^*, Xianzhong Chen^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

114 Citations (Scopus)

97 Downloads (CityUHK Scholars)

Abstract

Driven by miniaturization and system integration, ultrathin, multifunction optical elements are urgently needed. Traditional polarization-selective optical elements are mainly based on birefringence, which is realized by using the well-designed structure of each phase pixel. However, further reduction of the pixel size and improvement of the phase levels are hindered by the complicated fabrication process. An approach is proposed to realize a metasurface device that possesses two distinct functionalities. The designed metasurface device, consisting of gold nanorods with spatially varying orientation, has been experimentally demonstrated to function as either a lens or a hologram, depending on the helicity of the incident light. As the phase of the scattered light is controlled by the orientation of the nanorods, arbitrary phase levels and dispersionless phase profile can be realized through a much simpler fabrication process than the conventional device. This approach provides an unconventional alternative to realize multifunction optical element, dramatically increasing the functionality density of the optical systems.

Original language	English
Pages (from-to)	321-327
Journal	Advanced Optical Materials
Volume	4
Issue number	2
Online published	17 Nov 2015
DOIs	https://doi.org/10.1002/adom.201500498
Publication status	Published - Feb 2016

Research Keywords

Helicity-dependent functionality
Hologram
Lens
Metasurface
Ultrathin multifunction devices

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Metasurface Device with Helicity-Dependent Functionality",

abstract = "Driven by miniaturization and system integration, ultrathin, multifunction optical elements are urgently needed. Traditional polarization-selective optical elements are mainly based on birefringence, which is realized by using the well-designed structure of each phase pixel. However, further reduction of the pixel size and improvement of the phase levels are hindered by the complicated fabrication process. An approach is proposed to realize a metasurface device that possesses two distinct functionalities. The designed metasurface device, consisting of gold nanorods with spatially varying orientation, has been experimentally demonstrated to function as either a lens or a hologram, depending on the helicity of the incident light. As the phase of the scattered light is controlled by the orientation of the nanorods, arbitrary phase levels and dispersionless phase profile can be realized through a much simpler fabrication process than the conventional device. This approach provides an unconventional alternative to realize multifunction optical element, dramatically increasing the functionality density of the optical systems.",

keywords = "Helicity-dependent functionality, Hologram, Lens, Metasurface, Ultrathin multifunction devices",

author = "Dandan Wen and Shumei Chen and Fuyong Yue and Kinlong Chan and Ming Chen and Marcus Ardron and Li, {King Fai} and Wong, {Polis Wing Han} and Cheah, {Kok Wai} and Pun, {Edwin Yue Bun} and Guixin Li and Shuang Zhang and Xianzhong Chen",

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doi = "10.1002/adom.201500498",

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AU - Wen, Dandan

AU - Chen, Shumei

AU - Yue, Fuyong

AU - Chan, Kinlong

AU - Chen, Ming

AU - Ardron, Marcus

AU - Li, King Fai

AU - Wong, Polis Wing Han

AU - Cheah, Kok Wai

AU - Pun, Edwin Yue Bun

AU - Li, Guixin

AU - Zhang, Shuang

AU - Chen, Xianzhong

PY - 2016/2

Y1 - 2016/2

N2 - Driven by miniaturization and system integration, ultrathin, multifunction optical elements are urgently needed. Traditional polarization-selective optical elements are mainly based on birefringence, which is realized by using the well-designed structure of each phase pixel. However, further reduction of the pixel size and improvement of the phase levels are hindered by the complicated fabrication process. An approach is proposed to realize a metasurface device that possesses two distinct functionalities. The designed metasurface device, consisting of gold nanorods with spatially varying orientation, has been experimentally demonstrated to function as either a lens or a hologram, depending on the helicity of the incident light. As the phase of the scattered light is controlled by the orientation of the nanorods, arbitrary phase levels and dispersionless phase profile can be realized through a much simpler fabrication process than the conventional device. This approach provides an unconventional alternative to realize multifunction optical element, dramatically increasing the functionality density of the optical systems.

AB - Driven by miniaturization and system integration, ultrathin, multifunction optical elements are urgently needed. Traditional polarization-selective optical elements are mainly based on birefringence, which is realized by using the well-designed structure of each phase pixel. However, further reduction of the pixel size and improvement of the phase levels are hindered by the complicated fabrication process. An approach is proposed to realize a metasurface device that possesses two distinct functionalities. The designed metasurface device, consisting of gold nanorods with spatially varying orientation, has been experimentally demonstrated to function as either a lens or a hologram, depending on the helicity of the incident light. As the phase of the scattered light is controlled by the orientation of the nanorods, arbitrary phase levels and dispersionless phase profile can be realized through a much simpler fabrication process than the conventional device. This approach provides an unconventional alternative to realize multifunction optical element, dramatically increasing the functionality density of the optical systems.

KW - Helicity-dependent functionality

KW - Hologram

KW - Lens

KW - Metasurface

KW - Ultrathin multifunction devices

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DO - 10.1002/adom.201500498

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Metasurface Device with Helicity-Dependent Functionality

Abstract

Research Keywords

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