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

Photonics Research, Volume. 6, Issue 1, 47(2018)

On-chip polarization splitter based on a multimode plasmonic waveguide

Fengyuan Gan1,2, Chengwei Sun1, Hongyun Li1, Qihuang Gong1,2, and Jianjun Chen1,2、*
Author Affiliations
  • 1State Key Laboratory for Mesoscopic Physics, Collaborative Innovation Center of Quantum Matter, Department of Physics, Peking University, Beijing 100871, China
  • 2Collaborative Innovation Center of Extreme Optics, Shanxi University, Taiyuan 030006, China
    • show less
    Full TextGet PDF
    Figures&Tables (5)
    Equations (0)
    References (38)
    Cited By (15)
    Tools
    Paper Information
    Topics
    Figures & Tables(5)
    (a) Schematic and geometrical parameters of the multimode plasmonic waveguide. Power flow distributions of the (b) symmetric waveguide mode and (c) antisymmetric waveguide mode for w=700 nm, h=400 nm, d=400 nm, θ=16°, t=200 nm, and r=5 nm. The green arrows denote the vectors of the electric field. (d) Effective refractive indices, (e) propagation lengths, and (f) field confinements of the symmetric (black lines) as well as antisymmetric (red lines) SPP waveguide modes varying with wavelengths. The green dashed line in (d) denotes the effective refractive indices of the SPP mode on the flat metal surface.

    Fig. 1. (a) Schematic and geometrical parameters of the multimode plasmonic waveguide. Power flow distributions of the (b) symmetric waveguide mode and (c) antisymmetric waveguide mode for w=700  nm, h=400  nm, d=400  nm, θ=16°, t=200  nm, and r=5  nm. The green arrows denote the vectors of the electric field. (d) Effective refractive indices, (e) propagation lengths, and (f) field confinements of the symmetric (black lines) as well as antisymmetric (red lines) SPP waveguide modes varying with wavelengths. The green dashed line in (d) denotes the effective refractive indices of the SPP mode on the flat metal surface.

    Download full size
    View in Article
    (a) Schematic of the bending multimode plasmonic waveguide. (b) Transmittances of the symmetric (dashed lines) and antisymmetric (solid lines) SPP waveguide modes passing through the bending waveguide at different bending radii and bending angles (λ=900 nm). Power flow distributions of the (c) symmetric and (d) antisymmetric waveguide modes at R=2 μm and α=30°.

    Fig. 2. (a) Schematic of the bending multimode plasmonic waveguide. (b) Transmittances of the symmetric (dashed lines) and antisymmetric (solid lines) SPP waveguide modes passing through the bending waveguide at different bending radii and bending angles (λ=900  nm). Power flow distributions of the (c) symmetric and (d) antisymmetric waveguide modes at R=2  μm and α=30°.

    Download full size
    View in Article
    (a) Schematic and (b) top view of the proposed PBS. Power flow distributions of the (c) symmetric and (d) antisymmetric waveguide modes at λ=900 nm. Normalized output powers of the (e) symmetric and (f) antisymmetric waveguide modes at different wavelengths in the simulation.

    Fig. 3. (a) Schematic and (b) top view of the proposed PBS. Power flow distributions of the (c) symmetric and (d) antisymmetric waveguide modes at λ=900  nm. Normalized output powers of the (e) symmetric and (f) antisymmetric waveguide modes at different wavelengths in the simulation.

    Download full size
    View in Article
    (a) SEM image of the fabricated structures. (b) Cross-sectional SEM image of the multimode plasmonic waveguide. CMOS captured pictures under (c), (e), (g) p-polarized and (d), (f), (h) s-polarized incident light at different wavelengths. The red dashed rectangles in (c)−(h) denote the decoupling gratings.

    Fig. 4. (a) SEM image of the fabricated structures. (b) Cross-sectional SEM image of the multimode plasmonic waveguide. CMOS captured pictures under (c), (e), (g) p-polarized and (d), (f), (h) s-polarized incident light at different wavelengths. The red dashed rectangles in (c)−(h) denote the decoupling gratings.

    Download full size
    View in Article
    Measured normalized scattered powers under (a) p-polarized and (b) s-polarized incident light at different wavelengths. (c) Power flow distribution of the higher-order mode at λ=830 nm. The green arrows denote the vectors of the electric field. (d) Effective indices of the symmetric (black line), antisymmtric (red line) and higher-order (blue line) modes at different wavelengths. The green dashed line in (d) shows the effective indices of the SPP mode on the flat metal surface.

    Fig. 5. Measured normalized scattered powers under (a) p-polarized and (b) s-polarized incident light at different wavelengths. (c) Power flow distribution of the higher-order mode at λ=830  nm. The green arrows denote the vectors of the electric field. (d) Effective indices of the symmetric (black line), antisymmtric (red line) and higher-order (blue line) modes at different wavelengths. The green dashed line in (d) shows the effective indices of the SPP mode on the flat metal surface.

    Download full size
    View in Article
    Tools

    Get Citation

    Copy Citation Text

    Fengyuan Gan, Chengwei Sun, Hongyun Li, Qihuang Gong, Jianjun Chen. On-chip polarization splitter based on a multimode plasmonic waveguide[J]. Photonics Research, 2018, 6(1): 47

    Download Citation

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

    Category: Surface Plasmons

    Received: Sep. 22, 2017

    Accepted: Nov. 28, 2017

    Published Online: Jul. 10, 2018

    The Author Email: Jianjun Chen (jjchern@pku.edu.cn)

    DOI:10.1364/PRJ.6.000047

    Topics

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