Phase-engineered metalenses to generate converging and non-diffractive vortex beam carrying orbital angular momentum in microwave region

Kuang Zhang; Yueyi Yuan; Dawei Zhang; Xumin Ding; Badreddine Ratni; Shah Nawaz Burokur; Manjun Lu; Kun Tang; Qun Wu

doi:10.1364/OE.26.001351

Phase-engineered metalenses to generate converging and non-diffractive vortex beam carrying orbital angular momentum in microwave region

Kuang Zhang^*
, Yueyi Yuan
, Dawei Zhang
, Xumin Ding
, Badreddine Ratni
, Shah Nawaz Burokur
, Manjun Lu
, Kun Tang
, Qun Wu

^*Corresponding author for this work

State Key Laboratory of Millimeter Waves
Harbin Institute of Technology
Université Paris Nanterre
Shanghai Radio Equipment Institute

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

275 Scopus citations

Abstract

In this paper, ultra-thin metalenses are proposed to generate converging and non-diffractive vortex beam carrying orbital angular momentum (OAM) in microwave region. Phase changes are introduced to the transmission cross-polarized wave by tailoring spatial orientation of Pancharatnam-Berry phase unit cell. Based on the superposition of phase profile of spiral phase plate and that of a converging lens or an axicon, vortex beam carrying OAM mode generated by the metalens can also exhibit characteristics of a focusing beam or a Bessel beam. Measured field intensities and phase distributions at microwave frequencies verify the theoretical design procedure. The proposed method provides an efficient approach to control the radius of vortex beam carrying OAM mode in microwave wireless applications for medium-short range distance.

Original language	English
Pages (from-to)	1351-1360
Number of pages	10
Journal	Optics Express
Volume	26
Issue number	2
DOIs	https://doi.org/10.1364/OE.26.001351
State	Published - 22 Jan 2018

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title = "Phase-engineered metalenses to generate converging and non-diffractive vortex beam carrying orbital angular momentum in microwave region",

abstract = "In this paper, ultra-thin metalenses are proposed to generate converging and non-diffractive vortex beam carrying orbital angular momentum (OAM) in microwave region. Phase changes are introduced to the transmission cross-polarized wave by tailoring spatial orientation of Pancharatnam-Berry phase unit cell. Based on the superposition of phase profile of spiral phase plate and that of a converging lens or an axicon, vortex beam carrying OAM mode generated by the metalens can also exhibit characteristics of a focusing beam or a Bessel beam. Measured field intensities and phase distributions at microwave frequencies verify the theoretical design procedure. The proposed method provides an efficient approach to control the radius of vortex beam carrying OAM mode in microwave wireless applications for medium-short range distance.",

author = "Kuang Zhang and Yueyi Yuan and Dawei Zhang and Xumin Ding and Badreddine Ratni and Burokur, \{Shah Nawaz\} and Manjun Lu and Kun Tang and Qun Wu",

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T1 - Phase-engineered metalenses to generate converging and non-diffractive vortex beam carrying orbital angular momentum in microwave region

AU - Zhang, Kuang

AU - Yuan, Yueyi

AU - Zhang, Dawei

AU - Ding, Xumin

AU - Ratni, Badreddine

AU - Burokur, Shah Nawaz

AU - Lu, Manjun

AU - Tang, Kun

AU - Wu, Qun

PY - 2018/1/22

Y1 - 2018/1/22

N2 - In this paper, ultra-thin metalenses are proposed to generate converging and non-diffractive vortex beam carrying orbital angular momentum (OAM) in microwave region. Phase changes are introduced to the transmission cross-polarized wave by tailoring spatial orientation of Pancharatnam-Berry phase unit cell. Based on the superposition of phase profile of spiral phase plate and that of a converging lens or an axicon, vortex beam carrying OAM mode generated by the metalens can also exhibit characteristics of a focusing beam or a Bessel beam. Measured field intensities and phase distributions at microwave frequencies verify the theoretical design procedure. The proposed method provides an efficient approach to control the radius of vortex beam carrying OAM mode in microwave wireless applications for medium-short range distance.

AB - In this paper, ultra-thin metalenses are proposed to generate converging and non-diffractive vortex beam carrying orbital angular momentum (OAM) in microwave region. Phase changes are introduced to the transmission cross-polarized wave by tailoring spatial orientation of Pancharatnam-Berry phase unit cell. Based on the superposition of phase profile of spiral phase plate and that of a converging lens or an axicon, vortex beam carrying OAM mode generated by the metalens can also exhibit characteristics of a focusing beam or a Bessel beam. Measured field intensities and phase distributions at microwave frequencies verify the theoretical design procedure. The proposed method provides an efficient approach to control the radius of vortex beam carrying OAM mode in microwave wireless applications for medium-short range distance.

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DO - 10.1364/OE.26.001351

M3 - 文章

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JO - Optics Express

JF - Optics Express

IS - 2

ER -

Phase-engineered metalenses to generate converging and non-diffractive vortex beam carrying orbital angular momentum in microwave region

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