High-efficiency Bessel beam array generation by Huygens metasurfaces

Zemeng Lin; Xiaowei Li; Ruizhe Zhao; Xu Song; Yongtian Wang; Lingling Huang

doi:10.1515/nanoph-2019-0085

High-efficiency Bessel beam array generation by Huygens metasurfaces

Zemeng Lin, Xiaowei Li^*, Ruizhe Zhao, Xu Song, Yongtian Wang, Lingling Huang

^*Corresponding author for this work

Beijing Institute of Technology

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

69 Citations (Scopus)

Abstract

Bessel beams have attracted considerable interest because of their unique non-diffractive, self-healing characteristics. Different approaches have been proposed to generate Bessel beams, such as using axicons, diffractive optical elements, composite holograms, or spatial light modulators. However, these approaches have suffered from limited numerical aperture, low efficiency, polarization-dependent properties, etc. Here, by utilizing dielectric Huygens metasurfaces as ultrathin, compact platforms by integrating the functionalities of Dammann gratings and axicons, we successfully demonstrate multiple Bessel beam generation with polarization-independent property. The number of two-dimensional arrays can be controlled flexibly, which can enhance information capacity with a total efficiency that can reach 66.36%. This method can have various applications, such as parallel laser fabrication, efficient optical tweezers, and optical communication.

Original language	English
Pages (from-to)	1079-1085
Number of pages	7
Journal	Nanophotonics
Volume	8
Issue number	6
DOIs	https://doi.org/10.1515/nanoph-2019-0085
Publication status	Published - 2019

Keywords

Bessel beams
Dammann gratings
Huygens metasurfaces

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abstract = "Bessel beams have attracted considerable interest because of their unique non-diffractive, self-healing characteristics. Different approaches have been proposed to generate Bessel beams, such as using axicons, diffractive optical elements, composite holograms, or spatial light modulators. However, these approaches have suffered from limited numerical aperture, low efficiency, polarization-dependent properties, etc. Here, by utilizing dielectric Huygens metasurfaces as ultrathin, compact platforms by integrating the functionalities of Dammann gratings and axicons, we successfully demonstrate multiple Bessel beam generation with polarization-independent property. The number of two-dimensional arrays can be controlled flexibly, which can enhance information capacity with a total efficiency that can reach 66.36%. This method can have various applications, such as parallel laser fabrication, efficient optical tweezers, and optical communication.",

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author = "Zemeng Lin and Xiaowei Li and Ruizhe Zhao and Xu Song and Yongtian Wang and Lingling Huang",

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T1 - High-efficiency Bessel beam array generation by Huygens metasurfaces

AU - Lin, Zemeng

AU - Li, Xiaowei

AU - Zhao, Ruizhe

AU - Song, Xu

AU - Wang, Yongtian

AU - Huang, Lingling

PY - 2019

Y1 - 2019

N2 - Bessel beams have attracted considerable interest because of their unique non-diffractive, self-healing characteristics. Different approaches have been proposed to generate Bessel beams, such as using axicons, diffractive optical elements, composite holograms, or spatial light modulators. However, these approaches have suffered from limited numerical aperture, low efficiency, polarization-dependent properties, etc. Here, by utilizing dielectric Huygens metasurfaces as ultrathin, compact platforms by integrating the functionalities of Dammann gratings and axicons, we successfully demonstrate multiple Bessel beam generation with polarization-independent property. The number of two-dimensional arrays can be controlled flexibly, which can enhance information capacity with a total efficiency that can reach 66.36%. This method can have various applications, such as parallel laser fabrication, efficient optical tweezers, and optical communication.

AB - Bessel beams have attracted considerable interest because of their unique non-diffractive, self-healing characteristics. Different approaches have been proposed to generate Bessel beams, such as using axicons, diffractive optical elements, composite holograms, or spatial light modulators. However, these approaches have suffered from limited numerical aperture, low efficiency, polarization-dependent properties, etc. Here, by utilizing dielectric Huygens metasurfaces as ultrathin, compact platforms by integrating the functionalities of Dammann gratings and axicons, we successfully demonstrate multiple Bessel beam generation with polarization-independent property. The number of two-dimensional arrays can be controlled flexibly, which can enhance information capacity with a total efficiency that can reach 66.36%. This method can have various applications, such as parallel laser fabrication, efficient optical tweezers, and optical communication.

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High-efficiency Bessel beam array generation by Huygens metasurfaces

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Keywords

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