Journals Articles Conferences News About CLP
Submit a paper Email Alert
Search
Search
Articles
Journals
News
Advanced Search
Top Searches
2D MaterialsTransformation opticsQuantum PhotonicsSmall lasersSemiconductor UV PhotonicsSupersymmetric microring laser arrays

Chinese Optics Letters, Volume. 23, Issue 1, 013601(2025)

Nano-thick SiO2 channel for subwavelength plasmonic orbital angular momentum mode transmission

Zhishen Zhang1, Xiaobo Heng2, Shuai Gao1, Li Zhang1, Fei Lin1, Weicheng Chen1、*, and Jiulin Gan3、**
Author Affiliations
  • 1Guangdong-Hong Kong-Macao Joint Laboratory for Intelligent Micro-Nano Optoelectronic Technology, School of Physics and Optoelectronic Engineering, Foshan University, Foshan 528225, China
  • 2GBA Branch of Aerospace Information Research Institute, Chinese Academy of Sciences, Guangzhou 510700, China
  • 3State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials, South China University of Technology, Guangzhou 510640, China
    • show less
    Full TextGet PDF
    Figures&Tables (7)
    Equations (16)
    References (34)
    Tools
    Paper Information
    Topics
    Figures & Tables(7)
    (a) Schematic diagram of the plasmonic OAM waveguide; (b) cross-section of the OAM waveguide; (c) energy percentage of the radial polarization component Er of the surface plasmon mode SP11. Inset is the intensity distribution of the SP11 mode.

    Fig. 1. (a) Schematic diagram of the plasmonic OAM waveguide; (b) cross-section of the OAM waveguide; (c) energy percentage of the radial polarization component Er of the surface plasmon mode SP11. Inset is the intensity distribution of the SP11 mode.

    Download full size
    View in Article
    Intensity and phase distributions of SP11e, SP11o, SP+1,1OAM, and SP−1,1OAM modes.

    Fig. 2. Intensity and phase distributions of SP11e, SP11o, SP+1,1OAM, and SP−1,1OAM modes.

    Download full size
    View in Article
    Mode properties of SP+1,1OAM mode in the nano-waveguides with r3 − r2 = 5 nm, r4 − r3 = r2 − r1, and r5 − r4 = 50 nm. (a) Modal effective index; (b) normalized mode area; (c) propagation length; (d) FoM. The inset is the cross-section of the OAM waveguide, where the thickness of the As2S3 layer is denoted as r2 − r1.

    Fig. 3. Mode properties of SP+1,1OAM mode in the nano-waveguides with r3r2 = 5 nm, r4r3 = r2r1, and r5r4 = 50 nm. (a) Modal effective index; (b) normalized mode area; (c) propagation length; (d) FoM. The inset is the cross-section of the OAM waveguide, where the thickness of the As2S3 layer is denoted as r2r1.

    Download full size
    View in Article
    (a) Normalized mode area and (b) FoM of SP+1,1OAM modes in the nano-waveguides with r4 − r3 = r2 − r1 = 10 nm and r5 − r4 = 50 nm. Inset in (b) denotes the thickness of SiO2 layer as r3 − r2. (c) Normalized mode area and (d) FoM of SP+1,1OAM modes in the nano-waveguides with r2 − r1 = 10 nm, r3 − r2 = 5 nm, and r5 − r4 = 50 nm. Inset in (d) denotes the thickness of the outer As2S3 layer as r4 − r3.

    Fig. 4. (a) Normalized mode area and (b) FoM of SP+1,1OAM modes in the nano-waveguides with r4r3 = r2r1 = 10 nm and r5r4 = 50 nm. Inset in (b) denotes the thickness of SiO2 layer as r3r2. (c) Normalized mode area and (d) FoM of SP+1,1OAM modes in the nano-waveguides with r2r1 = 10 nm, r3r2 = 5 nm, and r5r4 = 50 nm. Inset in (d) denotes the thickness of the outer As2S3 layer as r4r3.

    Download full size
    View in Article
    FoM of the SP+1,1OAM mode in four kinds of the nano-waveguides: the Ag nanowire (Model 1), the Ag nanotube (Model 2), the ring-core hybrid waveguide (Model 3), and this work.

    Fig. 5. FoM of the SP+1,1OAM mode in four kinds of the nano-waveguides: the Ag nanowire (Model 1), the Ag nanotube (Model 2), the ring-core hybrid waveguide (Model 3), and this work.

    Download full size
    View in Article
    (a) Schematic diagram of the plasmonic OAM waveguide coupler. (b) Propagating electric field of the SP+1,1OAM mode coupler, where the white arrows represent the direction of optical energy flow. The upper dashed block diagram is the electric field and phase distribution of input SP+1,1OAM mode. The lower dashed block diagram is the electric field and phase distribution of coupling mode with the maximum coupling efficiency. (c) Coupling efficiencies of different modes in the SP+1,1OAM mode coupler. (d) Maximum coupling efficiency and corresponding coupling length of the SP+1,1OAM mode coupler with different center-to-center distances.

    Fig. 6. (a) Schematic diagram of the plasmonic OAM waveguide coupler. (b) Propagating electric field of the SP+1,1OAM mode coupler, where the white arrows represent the direction of optical energy flow. The upper dashed block diagram is the electric field and phase distribution of input SP+1,1OAM mode. The lower dashed block diagram is the electric field and phase distribution of coupling mode with the maximum coupling efficiency. (c) Coupling efficiencies of different modes in the SP+1,1OAM mode coupler. (d) Maximum coupling efficiency and corresponding coupling length of the SP+1,1OAM mode coupler with different center-to-center distances.

    Download full size
    View in Article
    Intensity and phase distributions of SP21e, SP21o, SP+2,1OAM, and SP−2,1OAM modes in the waveguide with r1 = 150 nm.

    Fig. 7. Intensity and phase distributions of SP21e, SP21o, SP+2,1OAM, and SP−2,1OAM modes in the waveguide with r1 = 150 nm.

    Download full size
    View in Article
    Tools

    Get Citation

    Copy Citation Text

    Zhishen Zhang, Xiaobo Heng, Shuai Gao, Li Zhang, Fei Lin, Weicheng Chen, Jiulin Gan, "Nano-thick SiO2 channel for subwavelength plasmonic orbital angular momentum mode transmission," Chin. Opt. Lett. 23, 013601 (2025)

    Download Citation

    EndNote(RIS)BibTexPlain Text
    Set citation alerts for article
    Save article for my favorites
    Paper Information

    Category: Nanophotonics, Metamaterials, and Plasmonics

    Received: May. 24, 2024

    Accepted: Jul. 16, 2024

    Published Online: Dec. 31, 2024

    The Author Email: Weicheng Chen (chenwch@fosu.edu.cn), Jiulin Gan (msgan@scut.edu.cn)

    DOI:10.3788/COL202523.013601

    CSTR:32184.14.COL202523.013601

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology