Coupled surface plasmon and resonant optical tunnelling in symmetric optical microcavities

A symmetrical structure consisting of a low refractive index dielectric layer between two metallic films, i.e. an optical cavity, surrounded by a semi-infinite dielectric medium of higher refractive index, forms an optical system capable of supporting both volume and surface resonances. The latter are associated with synchronized collective electronic oscillations in the inner surfaces of the two thin metallic films, called coupled surface plasmons. These oscillations are generated by an evanescent wave in the cavity and therefore the thickness of the cavity is limited to the micron range for visible radiation. Under suitable incident conditions, light propagating in the microcavity will resonate with these plasmonic oscillations and can be strongly transmitted into the surrounding medium. In this work, we establish a simple model of the transmission characteristics of the cavity and define resonance conditions that allow high transmittance even for inner dielectric layer thicknesses of various wavelengths. This phenomenon is an enhanced version of the optical process of frustrated total reflection between dielectrics analogous to quantum tunnelling effect. In the present situation, the phenomenon is more striking because it takes place in a system with two absorbing metal films which, under resonant conditions, favour a superior transmission.