Energy Relaxation Time between Macroscopic Quantum Levels in a Superconducting Persistent Current Qubit

Bhuwan Singh; D. Nakada; D. S. Crankshaw; Janice C. Lee; Karl K. Berggren; T. P. Orlando; William D. Oliver; Yang Yu

arxiv: cond-mat/0311289 · v2 · submitted 2003-11-12 · ❄️ cond-mat.supr-con

Energy Relaxation Time between Macroscopic Quantum Levels in a Superconducting Persistent Current Qubit

Yang Yu , D. Nakada , Janice C. Lee , Bhuwan Singh , D. S. Crankshaw , T. P. Orlando , William D. Oliver , Karl K. Berggren This is my paper

classification ❄️ cond-mat.supr-con

keywords qubitenergylevelspopulationquantumtimeinitialmacroscopic

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We measured the intrawell energy relaxation time \tau_{d} between macroscopic quantum levels in the double well potential of a Nb persistent-current qubit. Interwell population transitions were generated by irradiating the qubit with microwaves. Zero population in the initial well was then observed due to a multi-level decay process in which the initial population relaxed to the lower energy levels during transitions. The qubit's decoherence time, determined from \tau_{d}, is longer than 20 microseconds, holding the promise of building a quantum computer with Nb-based superconducting qubits.

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Energy Relaxation Time between Macroscopic Quantum Levels in a Superconducting Persistent Current Qubit

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