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Probing a Two-Level System Bath via the Frequency Shift of an Off-Resonantly Driven Cavity

Thibault Capelle, Emmanuel Flurin, Edouard Ivanov, Jose Palomo, Michael Rosticher, Sheon Chua, Tristan Briant, Pierre-François Cohadon, Antoine Heidmann, Thibaut Jacqmin, Samuel Deléglise

2020Physical Review Applied20 citationsDOIOpen Access PDF

Abstract

Although the main loss channel of planar microwave superconducting resonators has been identified to be related to an external coupling to a two-level system (TLS) bath, the behavior of such resonators in the presence of an off-resonant pump has yet to be fully understood. Alongside the well-known power-dependent damping, we observe a frequency shift with a conspicuous maximum for intermediate pump power that is attributed to a spectrally asymmetric saturation of the TLSs. We derive a semiclassical model that describes both of these effects quantitatively. The model is validated experimentally by performing a two-tone spectroscopy of several resonators fabricated on various substrates. Together with the provided analytic formulas, the technique proposed here is a simple yet powerful tool to unambiguously identify the presence of a limiting TLS bath, and to characterize various properties thereof, such as its average dephasing rate.

Topics & Concepts

DephasingResonatorSaturation (graph theory)MicrowavePlanarSemiclassical physicsCoupling (piping)PhysicsMaterials scienceLimitingPower (physics)SpectroscopyComputational physicsOptoelectronicsOpticsQuality (philosophy)Parametric statisticsOptical pumpingFrequency shiftWhispering-gallery waveSuperconductivitySpectral densityQ factorChannel (broadcasting)Condensed matter physicsMode couplingBeat (acoustics)Physics of Superconductivity and MagnetismAdvanced Frequency and Time StandardsMechanical and Optical Resonators
Probing a Two-Level System Bath via the Frequency Shift of an Off-Resonantly Driven Cavity | Litcius