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Precision Measurement of the Microwave Dielectric Loss of Sapphire in the Quantum Regime with Parts-per-Billion Sensitivity

Alexander P. Read, Benjamin J. Chapman, Chan U Lei, Jacob C. Curtis, Suhas Ganjam, Lev Krayzman, Luigi Frunzio, Robert Schoelkopf

2023Physical Review Applied45 citationsDOIOpen Access PDF

Abstract

To better understand decoherence in superconducting qubits, the authors develop a technique to measure the loss tangent of dielectric substrates and predict the impact of dielectric loss on qubit lifetimes. This is done with no need to fabricate planar devices; the technique is independent of material platform. Measurements of sapphire in a demonstration of the approach suggest that coherence of superconducting qubits on a common form of sapphire is limited significantly by bulk dielectric loss. The same technique also shows that another form of sapphire would substantially mitigate this bulk dielectric loss and prolong qubit coherence.

Topics & Concepts

QubitSapphireDielectricQuantum decoherenceCoherence (philosophical gambling strategy)MicrowaveDielectric lossMaterials sciencePhase qubitOptoelectronicsDissipation factorCondensed matter physicsSensitivity (control systems)QuantumPhysicsQuantum mechanicsElectronic engineeringEngineeringLaserPhysics of Superconductivity and MagnetismQuantum and electron transport phenomenaSuperconducting and THz Device Technology
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