Litcius/Paper detail

Exploiting Ultralow Loss Multimode Waveguides for Broadband Frequency Combs

Xingchen Ji, Jae K. Jang, Utsav D. Dave, Mateus Corato‐Zanarella, Chaitanya Joshi, Alexander L. Gaeta, Michal Lipson

2020Laser & Photonics Review98 citationsDOIOpen Access PDF

Abstract

Abstract Low propagation loss in high confinement waveguides is critical for chip‐based nonlinear photonics applications. Sophisticated fabrication processes which yield sub‐nm roughness are generally needed to reduce scattering points at the waveguide interfaces to achieve ultralow propagation loss. Here, ultralow propagation loss is shown by shaping the mode using a highly multimode structure to reduce its overlap with the waveguide interfaces, thus relaxing the fabrication processing requirements. Microresonators with intrinsic quality factors ( Q ) of 31.8 ± 4.4 million are experimentally demonstrated. Although the microresonators support ten transverse modes only the fundamental mode is excited and no higher order modes are observed when using nonlinear adiabatic bends. A record‐low threshold pump power of 73 µW for parametric oscillation is measured and a broadband, almost octave spanning single‐soliton frequency comb without any signatures of higher order modes in the spectrum spanning from 1097 to 2040 nm (126 THz) is generated in the multimode microresonator. This work provides a design method that can be applied to different material platforms to achieve and use ultrahigh‐ Q multimode microresonators.

Topics & Concepts

Multi-mode optical fiberOpticsBroadbandWaveguideMaterials scienceFabricationPhotonicsOptoelectronicsTransverse modeNonlinear systemOscillation (cell signaling)Octave (electronics)Parametric statisticsAttenuationPhysicsNonlinear opticsAdiabatic processFrequency combRaman scatteringTerahertz radiationTransverse planeScatteringWhispering-gallery waveCoupled mode theoryMode (computer interface)Single-mode optical fiberPower (physics)Brillouin scatteringSupercontinuumNonlinear mediumPropagation constantTaperingQ factorSignal processingScattering parametersAdvanced Fiber Laser TechnologiesPhotonic and Optical DevicesPhotorefractive and Nonlinear Optics