Litcius/Paper detail

High-<i>Q</i> nanobeam cavities on a silicon nitride platform enabled by slow light

Jiahao Zhan, Zeinab Jafari, Sylvain Veilleux, M. Dagenais, Israel De Leon

2020APL Photonics13 citationsDOIOpen Access PDF

Abstract

Silicon nitride integrated photonic devices benefit from a wide working spectral range covering the visible and near-infrared spectra, which in turn enables important applications in bio-photonics, optical communications, and sensing. High-quality factor optical resonators are essential photonic devices for such applications. However, implementing such resonators on a silicon nitride platform is quite challenging due to the low refractive index contrast attainable with this material. Here, we demonstrate that silicon nitride photonic cavities comprising a slow-light waveguide bounded by mirrors can in principle exhibit quality factors in the order of several millions despite a relatively low refractive index contrast. We show that the energy stored in such a slow-light cavity exhibits a cubic dependence on the cavity length, which can enable extremely large quality factors with modest-length cavities. We present the design and experimental characterization of silicon nitride slow-light nanobeam-type cavities. Two sets of nanobeam cavities were fabricated to experimentally verify the cubic dependence of the Q factor on the cavity length. The highest measured Q factor in our devices is 4.42 × 105, which is limited by fabrication imperfections.

Topics & Concepts

PhotonicsMaterials scienceOptoelectronicsResonatorSilicon nitrideRefractive indexSlow lightNitrideQ factorRefractive index contrastSiliconSilicon photonicsPhotonic crystalWaveguideOpticsFabricationNanotechnologyPhysicsAlternative medicineMedicineLayer (electronics)PathologyPhotonic and Optical DevicesMechanical and Optical ResonatorsAdvanced Fiber Laser Technologies