Long range surface plasmon resonance enhanced electro-optically tunable Goos–Hänchen shift and Imbert–Fedorov shift in ZnSe prism

A new theoretical approach towards the tuning of Goos–Hänchen shift and Imbert–Fedorov shift for the reflected light beam is observed, designed and simulated in this paper through electro-optically tunable liquid crystal at an incident wavelength of 1550 nm within the communication window. Here the considered Kretschmann–Raether geometry comprises a ZnSe prism and a liquid crystal layer of E44 between two metal layers of silver, where with the application of electric field from (0–10) V electro-optically tuning of the Goos–Hänchen shift from 64.09 µm to −53.408 µm and the Imbert–Fedorov shift from 122.8 µm to −32.5 µm for a change in refractive index of the liquid crystal layer from 1.52–1.79 are envisaged. This idea expedites the scope of fine tuning in optical switching within the µm ranges.