Dielectric tuning and coupling of whispering gallery modes using an anisotropic prism

TL;DR

This paper provides a detailed theoretical analysis of dielectric tuning of whispering gallery modes in axisymmetric resonators, highlighting how substrate properties influence resonance shifts, mode broadening, and polarization-selective coupling.

Contribution

It introduces a comprehensive theoretical framework for dielectric tuning of WGMs, including effects of anisotropic substrates and polarization control, which was not previously detailed.

Findings

Resonance shifts of ~30 MHz due to substrate effects.

Mode broadening of ~50 MHz achievable with dielectric substrates.

Polarization selective coupling with extinction ratios > 10^4.

Abstract

Optical whispering gallery mode (WGM) resonators are a powerful and versatile tool used in many branches of science. Fine tuning of the central frequency and line width of individual resonances is however desirable in a number of applications including frequency conversion, optical communications and efficient light-matter coupling. To this end we present a detailed theoretical analysis of dielectric tuning of WGMs supported in axisymmetric resonators. Using the Bethe-Schwinger equation and adopting an angular spectrum field representation we study the resonance shift and mode broadening of high $Q$ WGMs when a planar dielectric substrate is brought close to the resonator. Particular focus is given to use of a uniaxial substrate with an arbitrarily aligned optic axis. Competing red and blue resonance shifts ($\sim 30$ MHz), deriving from generation of a near field material polarisation and back action from the radiation continuum respectively, are found. Anomalous resonance shifts can hence be observed depending on the substrate material, whereas mode broadening on the order of $\sim 50$ MHz can also be simply realised. Furthermore, polarisation selective coupling with extinction ratios of $> 10^4$ can be achieved when the resonator and substrate are of the same composition and their optic axes are chosen correctly. Double refraction and properties of out-coupled beams are also discussed.