Constructing ultra-long focal fields via tightly focused Bessel beams

Zhaojin Guo; Mingshuai Huang; Sheng Liu; Peng Li; Bingyan Wei; Jianlin Zhao

doi:10.3788/COL202321.072601

Constructing ultra-long focal fields via tightly focused Bessel beams

Zhaojin Guo, Mingshuai Huang, Sheng Liu, Peng Li, Bingyan Wei, Jianlin Zhao

School of Physical Science and Technology

Northwestern Polytechnical University Xian

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

5 Scopus citations

Abstract

We numerically demonstrate that the tight focusing of Bessel beams can generate focal fields with an ultra-long depth of focus (DOF). The ultra-long focal field can be controlled by appropriately regulating the order of the Bessel function and the polarization. An optical needle and an optical dark channel with nearly 100λ DOF are generated. The optical needle has a DOF of ∼104.9λ and a super-diffraction-limited focal spot with the size of 0.19λ². The dark channel has a full-width at half-maximum of ∼0.346λ and a DOF of ∼103.8λ. Furthermore, the oscillating focal field with an ultra-long DOF can be also generated by merely changing the order of the input Bessel beam. Our results are expected to contribute to potential applications in optical tweezers, atom guidance and capture, and laser processing.

Original language	English
Article number	072601
Journal	Chinese Optics Letters
Volume	21
Issue number	7
DOIs	https://doi.org/10.3788/COL202321.072601
State	Published - Jul 2023

Keywords

Bessel beam
depth of focus
tight focusing
vector beam

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10.3788/COL202321.072601

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title = "Constructing ultra-long focal fields via tightly focused Bessel beams",

abstract = "We numerically demonstrate that the tight focusing of Bessel beams can generate focal fields with an ultra-long depth of focus (DOF). The ultra-long focal field can be controlled by appropriately regulating the order of the Bessel function and the polarization. An optical needle and an optical dark channel with nearly 100λ DOF are generated. The optical needle has a DOF of ∼104.9λ and a super-diffraction-limited focal spot with the size of 0.19λ2. The dark channel has a full-width at half-maximum of ∼0.346λ and a DOF of ∼103.8λ. Furthermore, the oscillating focal field with an ultra-long DOF can be also generated by merely changing the order of the input Bessel beam. Our results are expected to contribute to potential applications in optical tweezers, atom guidance and capture, and laser processing.",

keywords = "Bessel beam, depth of focus, tight focusing, vector beam",

author = "Zhaojin Guo and Mingshuai Huang and Sheng Liu and Peng Li and Bingyan Wei and Jianlin Zhao",

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doi = "10.3788/COL202321.072601",

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T1 - Constructing ultra-long focal fields via tightly focused Bessel beams

AU - Guo, Zhaojin

AU - Huang, Mingshuai

AU - Liu, Sheng

AU - Li, Peng

AU - Wei, Bingyan

AU - Zhao, Jianlin

PY - 2023/7

Y1 - 2023/7

N2 - We numerically demonstrate that the tight focusing of Bessel beams can generate focal fields with an ultra-long depth of focus (DOF). The ultra-long focal field can be controlled by appropriately regulating the order of the Bessel function and the polarization. An optical needle and an optical dark channel with nearly 100λ DOF are generated. The optical needle has a DOF of ∼104.9λ and a super-diffraction-limited focal spot with the size of 0.19λ2. The dark channel has a full-width at half-maximum of ∼0.346λ and a DOF of ∼103.8λ. Furthermore, the oscillating focal field with an ultra-long DOF can be also generated by merely changing the order of the input Bessel beam. Our results are expected to contribute to potential applications in optical tweezers, atom guidance and capture, and laser processing.

AB - We numerically demonstrate that the tight focusing of Bessel beams can generate focal fields with an ultra-long depth of focus (DOF). The ultra-long focal field can be controlled by appropriately regulating the order of the Bessel function and the polarization. An optical needle and an optical dark channel with nearly 100λ DOF are generated. The optical needle has a DOF of ∼104.9λ and a super-diffraction-limited focal spot with the size of 0.19λ2. The dark channel has a full-width at half-maximum of ∼0.346λ and a DOF of ∼103.8λ. Furthermore, the oscillating focal field with an ultra-long DOF can be also generated by merely changing the order of the input Bessel beam. Our results are expected to contribute to potential applications in optical tweezers, atom guidance and capture, and laser processing.

KW - Bessel beam

KW - depth of focus

KW - tight focusing

KW - vector beam

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DO - 10.3788/COL202321.072601

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VL - 21

JO - Chinese Optics Letters

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Constructing ultra-long focal fields via tightly focused Bessel beams

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