Superconducting qubit in waveguide cavity with coherence time approaching 0.1ms

Chad Rigetti , Stefano Poletto , Jay M. Gambetta , B. L. T. Plourde , Jerry M. Chow , A. D. Corcoles , John A. Smolin , Seth T. Merkel

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J. R. Rozen George A. Keefe Mary B. Rothwell Mark B. Ketchen M. Steffen

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classification 🪐 quant-ph

keywords coherencequbitcavityquantumtimeartificialdevicefactor

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We report a superconducting artificial atom with an observed quantum coherence time of T2*=95us and energy relaxation time T1=70us. The system consists of a single Josephson junction transmon qubit embedded in an otherwise empty copper waveguide cavity whose lowest eigenmode is dispersively coupled to the qubit transition. We attribute the factor of four increase in the coherence quality factor relative to previous reports to device modifications aimed at reducing qubit dephasing from residual cavity photons. This simple device holds great promise as a robust and easily produced artificial quantum system whose intrinsic coherence properties are sufficient to allow tests of quantum error correction.

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Exact and Efficient Stabilizer Simulation of Thermal-Relaxation Noise for Quantum Error Correction
quant-ph 2025-12 unverdicted novelty 6.0

An exact positive-probability decomposition of thermal relaxation noise into Clifford gates and resets exists for T2 ≤ T1, with a negativity-free approximation that outperforms Pauli twirling for T2 > T1.