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Generalized theory of optical resonator and waveguide modes and their linear and Kerr nonlinear coupling

Jonathan M. Silver, Pascal Del’Haye

2022Physical review. A/Physical review, A12 citationsDOIOpen Access PDF

Abstract

We derive a general theory of linear coupling and Kerr nonlinear coupling between modes of dielectric optical resonators from first principles. The treatment is not specific to a particular geometry or choice of mode basis, and can therefore be used as a foundation for describing any phenomenon resulting from any combination of linear coupling, scattering, and Kerr nonlinearity, such as bending and surface roughness losses, geometric backscattering, self- and cross-phase modulation, four-wave mixing, third-harmonic generation, and Kerr frequency comb generation. The theory is then applied to a translationally symmetric waveguide in order to calculate the evanescent coupling strength to the modes of a microresonator placed nearby, as well as the Kerr self- and cross-phase modulation terms between the modes of the resonator. This is then used to derive a dimensionless equation describing the symmetry-breaking dynamics of two counterpropagating modes of a loop resonator and prove that cross-phase modulation is exactly twice as strong as self-phase modulation only in the case that the two counterpropagating modes are otherwise identical.

Topics & Concepts

PhysicsResonatorKerr effectCoupled mode theoryModulation (music)Coupling (piping)WaveguideDimensionless quantityOpticsCross-phase modulationNonlinear systemPhase (matter)Phase modulationQuantum mechanicsRefractive indexMaterials scienceAcousticsMetallurgyPhotonic and Optical DevicesAdvanced Fiber Laser TechnologiesMechanical and Optical Resonators