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    Electromagnetically induced absorption (EIA) in plasmonic waveguides shows tunable responses and fast-light effects. This research enables advanced nanophotonic devices and on-chip applications.

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    Area of Science:

    • Nanophotonics
    • Plasmonics
    • Quantum Optics

    Background:

    • Electromagnetically induced absorption (EIA) is key for abnormal dispersion and fast-light phenomena.
    • Plasmonic waveguide systems offer a platform for manipulating light at the nanoscale.

    Purpose of the Study:

    • To numerically predict and analyze EIA in a compact plasmonic waveguide system.
    • To explore the tunability of EIA response and fast-light effects by structural modifications.
    • To demonstrate the potential for plasmonic nanosensing applications.

    Main Methods:

    • Numerical simulation of a plasmonic waveguide with a slot resonator above a square cavity.
    • Analysis of EIA response by varying structural parameters.
    • Investigation of fast-light effect via aberrant dispersion at EIA valleys.
    • Characterization of a plasmonic nanosensor based on Fano resonance.

    Main Results:

    • Achieved tunable EIA response in the plasmonic waveguide system.
    • Observed double EIA valleys with an additional slot resonator.
    • Demonstrated a fast-light effect with an optical delay of approximately -1.0 ps.
    • Developed a plasmonic nanosensor with high sensitivity (1200 nm/RIU) and figure of merit (16600).

    Conclusions:

    • The proposed compact plasmonic structure effectively exhibits EIA and fast-light properties.
    • The tunability of the system allows for versatile applications in integrated nanophotonics.
    • The developed plasmonic nanosensor shows significant potential for sensing applications.