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Interferometric cavity ring-down technique for ultra-high Q-factor microresonators

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arxiv 2206.08123 v1 pith:H4GULHEP submitted 2022-06-16 physics.optics

Interferometric cavity ring-down technique for ultra-high Q-factor microresonators

classification physics.optics
keywords cavityinterferometricmicroresonatorsring-downsingletimeultimateultra-high
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Microresonators (MRs) are key components in integrated optics. As a result, the estimation of their energy storage capacity as measured by the quality factor (Q) is crucial. However, in MR with high/ultra-high Q, the surface-wall roughness dominates the intrinsic Q and generates a coupling between counter-propagating modes. This splits the usual sharp single resonance and makes difficult the use of classical methods to assess Q. Here, we theoretically show that an interferometric excitation can be exploited in a Cavity Ring-Down (CRD) method to measure the ultimate Q of a MR. In fact, under suitable conditions, the resonant doublet merges into a single Lorentzian and the time dynamics of the MR assumes the usual behavior of a single-mode resonator unaffected by backscattering. This allows obtaining a typical exponential decay in the charging and discharging time of the MR, and thus, estimating its ultimate Q by measuring the photon lifetime.

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