Modeling of surface plasmon resonance in metalized optical waveguides with low V number by eigenmode expansion method.

The paper reports on the numerical study of surface plasmon resonance excitation in a bent metal-coated single mode optical fiber with a low V-number. It was shown that by choosing a proper combination of normalized frequency, bend radius, and metal film thickness one can achieve strong coupling between the fundamental mode guided by the fiber core, and symmetric surface plasmon mode supported by the metal layer applied to the fiber cladding. The effect is demonstrated to allow precision refractive index measurement, with spectral sensitivity and resolution estimated at 70 µm/refractive index unit and 3⋅10(-7), respectively.

Analysis of surface plasmon resonance in bent single-mode waveguides with metal-coated cladding by eigenmode expansion method.

A numerical study is presented of surface plasmon waves excitation in a metal film applied to the cladding of a standard bent single-mode optical fiber. It was shown that by adjusting the bend radius and metal film thickness one can achieve effective coupling between the fiber fundamental mode and symmetric surface plasmon mode through the intermediary of whispering gallery modes supported by the cladding of the bent fiber. This effect is demonstrated to allow for refractometric measurement both in the wavelength and intensity-modulated regimes with a resolution of up to 10⁻8 RIU. Usage of standard noise reduction techniques for intensity-modulated optical signals promises further increase in accuracy.