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Engineering Dispersive-Dissipative Modal Coupling in Hybrid Optical Microresonators

Xiaoxiu Zhu, Xiao Xiong, Zhu Zhendong, Wenjing Liu, Qi-Tao Cao, Yun‐Feng Xiao

2024Physical Review Letters10 citationsDOI

Abstract

Hybrid microresonators have served an intriguing platform for fundamental research and applied photonics. Here, we study the plasmonics-engineered coupling between degenerate optical whispering gallery modes, which can be tuned in a complex space featuring the dissipative strong, dispersive strong, and weak coupling regimes. Experimentally, the engineering of a single plasmonic resonance to a cavity mode family is examined in a waveguide-integrated high-Q microdisk, from which the complex coupling coefficients are extracted and agree well with theoretical predictions. The coupling strength over 10 GHz is achieved for both dissipative and dispersive interactions, showing a remarkable enhancement compared to that induced by a dielectric scatterer. Furthermore, the far fields of hybridized cavity modes are measured, revealing the coherent interference between the radiative channels. Our results shed light on the engineering of whispering gallery modes through plasmonic resonances, and provide fundamental guidance to practical microcavity devices.

Topics & Concepts

Whispering-gallery waveDissipative systemCoupling (piping)PhotonicsPlasmonResonance (particle physics)PhysicsResonatorOptoelectronicsDegenerate energy levelsWaveguideWhispering galleryDielectricCoupled mode theoryCavity quantum electrodynamicsOpticsMaterials scienceRefractive indexQuantum mechanicsQuantumMetallurgyOpen quantum systemPhotonic and Optical DevicesPlasmonic and Surface Plasmon ResearchAdvanced Fiber Laser Technologies
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