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Effects of imperfect angular adjustment on plasmonic force.

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    This study analyzes plasmonic forces between metallic plates, revealing that imperfect alignment and laser beam inclination significantly alter these forces. Non-parallel plates and beam angles impact the attractive force, with implications for nanoscale device design.

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    Area of Science:

    • Physics
    • Plasmonics
    • Electromagnetism

    Background:

    • Plasmonic forces between parallel metallic plates under normal incidence have been previously investigated.
    • Electromagnetic wave interactions in slits are crucial for understanding nanoscale phenomena.

    Purpose of the Study:

    • To analyze the effects of imperfectly adjusted plates on plasmonic forces.
    • To investigate the influence of laser beam inclination on plasmonic forces within a slit.

    Main Methods:

    • Theoretical analysis of plasmonic forces considering non-parallel metallic plates.
    • Examination of electromagnetic wave behavior and mode excitation in a slit with inclined beams.

    Main Results:

    • The plasmonic force changes with plate angle; the effect is first-order for wedge orientation along wave propagation and second-order for transverse orientation.
    • Laser beam inclination reduces the plasmonic force due to the excitation of an antisymmetric mode.

    Conclusions:

    • Plate misalignment and beam inclination introduce significant deviations in plasmonic forces compared to ideal parallel plate scenarios.
    • Understanding these effects is critical for the precise control and application of plasmonic forces in nanophotonics and device engineering.