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    Journals >Photonics Research >Volume 13 >Issue 4 >Page 960 > Article
    • Photonics Research
    • Vol. 13, Issue 4, 960 (2025)
    All-fiber orbital-angular-momentum mode encoding system based on helical fiber gratings
    Yu Chen1,2,†, Ming Gao1,2,†, Yutao Wang1,2, Xinyue Huang1,2..., Hui Hao1,2, Xiaoqi Ni1,2, Huali Lu1,2, Hua Zhao1,2,*, Peng Wang3,4, Xin Wang4 and Hongpu Li5,6|Show fewer author(s)
    Author Affiliations
  • 1School of Computer and Electronic Information, Nanjing Normal University, Nanjing 210023, China
  • 2Intelligent Optoelectronic Sensing Technology Innovation Center, Nanjing Normal University, Nanjing 210023, China
  • 3College of Electronic Engineering, Nanjing Xiaozhuang University, Nanjing 211171, China
  • 4Key Laboratory of Optoelectronic Materials and Devices, Chinese Academy of Sciences, Beijing 100083, China
  • 5Faculty of the Engineering, Shizuoka University, Hamamatsu 432-8561, Japan
  • 6e-mail: ri.kofu@shizuoka.ac.jp
    • show less
    DOI: 10.1364/PRJ.544533 Cite this Article Set citation alerts
    Yu Chen, Ming Gao, Yutao Wang, Xinyue Huang, Hui Hao, Xiaoqi Ni, Huali Lu, Hua Zhao, Peng Wang, Xin Wang, Hongpu Li, "All-fiber orbital-angular-momentum mode encoding system based on helical fiber gratings," Photonics Res. 13, 960 (2025) Copy Citation Text show less
    References

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    [3] N. Bozinovic, Y. Yue, S. Ramachandran. Terabit-scale orbital angular momentum mode division multiplexing in fibers. Science, 340, 1545-1548(2013).

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    [5] M. Padgett, R. Bowman. Tweezers with a twist. Nat. Photonics, 5, 343-348(2011).

    [6] J. Leach, B. Jack, M. J. Padgett. Quantum correlations in optical angle–orbital angular momentum variables. Science, 329, 662-665(2010).

    [7] J. Wang, J. Liu, L. Zhu. Orbital angular momentum and beyond in free-space optical communications. Nanophotonics, 11, 645-680(2022).

    [8] J. Chen, Z. Huang, J. Liu. High-order orbital angular momentum mode-based phase shift-keying communication using phase difference modulation. Opt. Express, 31, 44353-44363(2023).

    [9] Y. Yan, Y. Yue, A. Willner. Multicasting in a spatial division multiplexing system based on optical orbital angular momentum. Opt. Lett., 38, 3930-3933(2013).

    [10] J. Zhang, P. Li, J. Li. Generation of time-varying orbital angular momentum beams with space-time-coding digital metasurface. Adv. Photon., 5, 036001(2023).

    [11] J. Liu, S. Li, J. Wang. Direct fiber vector eigenmode multiplexing transmission seeded by integrated optical vortex emitters. Light Sci. Appl., 7, 17148(2017).

    [12] J. Wang, S. Chen, J. Liu. Orbital angular momentum communications based on standard multi-mode fiber. APL Photon., 6, 060804(2021).

    [13] A. E. Willner, C. Liu. Perspective on using multiple orbital-angular-momentum beams for enhanced capacity in free-space optical communication links. Nanophotonics, 10, 225-233(2020).

    [14] Q. Lu, J. Li, Z. Li. Design and fabrication of a weakly-coupled OAM ring-core fiber supporting 5-mode-group-multiplexed MIMO-free transmission. J. Lightwave Technol., 42, 828-834(2024).

    [15] J. Zhu, M. Fan, S. Wang. 1024-ary composite OAM shift keying for free-space optical communication system decoded by a two-step neural network. Opt. Lett., 48, 2692-2695(2023).

    [16] A. E. Willner, Z. Zhao, H. Huang. Perspectives on advances in high-capacity, free-space communications using multiplexing of orbital-angular-momentum beams. APL Photon., 6, 030901(2021).

    [17] T. Zou, J. Zhong, S. Liu. Helical intermediate-period fiber grating for refractive index measurements with low-sensitive temperature and torsion response. J. Lightwave Technol., 39, 6678-6685(2021).

    [18] M. Zhuang, J. Tu, Z. Li. Multi-step-index fiber with a large number of weakly coupled OAM mode groups for IM/DD systems in data centers: design, fabrication, and characterization. Opt. Lett., 48, 6036-6039(2023).

    [19] H. Zhang, B. Mao, Y. Liu. Generation of orbital angular momentum mode using a single cylindrical vector mode based on mode selective coupler. Opt. Fiber Technol., 52, 101934(2019).

    [20] F. Xia, Y. Zhao, H. Hu. Broadband generation of the first-order OAM modes in two-mode fiber by offset splicing and fiber rotating technology. Opt. Laser Technol., 112, 436-441(2019).

    [21] V. Likhov, S. Vasiliev, A. Okhrimchuk. OAM-mode coupling by segmented helical-ring-core waveguides inscribed with a femtosecond laser beam. Opt. Lett., 49, 1217-1220(2024).

    [22] P. St. J. Russell, R. Beravat, G. K. L. Wong. Helically twisted photonic crystal fibres. Philos. Trans. R. Soc. A., 375, 20150440(2017).

    [23] H. Zhao, H. Li. Advances on mode-coupling theories, fabrication techniques, and applications of the helical long-period fiber gratings: a review. Photonics, 8, 106(2021).

    [24] T. Erdogan. Fiber grating spectra. J. Lightwave Technol., 15, 1277-1294(1997).

    [25] H. Zhao, P. Wang, H. Li. All-fiber second-order orbital angular momentum generator based on a single-helix helical fiber grating. Opt. Lett., 44, 5370-5373(2019).

    [26] S. Li, Q. Mo, J. Wang. Controllable all-fiber orbital angular momentum mode converter. Opt. Lett., 40, 4376-4379(2015).

    [27] T. Detani, H. Zhao, H. Li. Simultaneous generation of the second- and third-order OAM modes by using a high-order helical long-period fiber grating. Opt. Lett., 46, 949-952(2021).

    [28] P. Wang, H. Zhao, T. Detani. Demonstration of the mode-selection rules obeyed in a single-helix helical long-period fiber grating. Opt. Lett., 45, 1846-1849(2020).

    [29] Y. Zhang, Z. Bai, C. Fu. Polarization-independent orbital angular momentum generator based on a chiral fiber grating. Opt. Lett., 44, 61-64(2019).

    [30] Z. Huang, Z. Bai, G. Zhu. Excitation of high order orbital angular momentum modes in ultra-short chiral long period fiber gratings. Opt. Express, 29, 39384-39394(2021).

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    Yu Chen, Ming Gao, Yutao Wang, Xinyue Huang, Hui Hao, Xiaoqi Ni, Huali Lu, Hua Zhao, Peng Wang, Xin Wang, Hongpu Li, "All-fiber orbital-angular-momentum mode encoding system based on helical fiber gratings," Photonics Res. 13, 960 (2025)
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