Decoherence in rf SQUID qubits

Douglas A. Bennett; Luigi Longobardi; Vijay Patel; Wei Chen; Dmitri V. Averin; James E. Lukens

doi:10.1007/s11128-009-0099-8

Decoherence in rf SQUID qubits

Douglas A. Bennett
, Luigi Longobardi
, Vijay Patel
, Wei Chen
, Dmitri V. Averin
, James E. Lukens

Physics and Astronomy

Stony Brook University

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

We report measurements of coherence times of an rf SQUID qubit using pulsed microwaves and rapid flux pulses. The modified rf SQUID, described by an double-well potential, has independent, in situ, controls for the tilt and barrier height of the potential. The decay of coherent oscillations is dominated by the lifetime of the excited state and low frequency flux noise and is consistent with independent measurement of these quantities obtained by microwave spectroscopy, resonant tunneling between fluxoid wells and decay of the excited state. The oscillation's waveform is compared to analytical results obtained for finite decay rates and detuning and averaged over low frequency flux noise.

Original language	English
Pages (from-to)	217-243
Number of pages	27
Journal	Quantum Information Processing
Volume	8
Issue number	2-3
DOIs	https://doi.org/10.1007/s11128-009-0099-8
State	Published - Jun 2009

Keywords

Decoherence
Flux qubit
SQUIDs
Superconducting qubits

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10.1007/s11128-009-0099-8

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abstract = "We report measurements of coherence times of an rf SQUID qubit using pulsed microwaves and rapid flux pulses. The modified rf SQUID, described by an double-well potential, has independent, in situ, controls for the tilt and barrier height of the potential. The decay of coherent oscillations is dominated by the lifetime of the excited state and low frequency flux noise and is consistent with independent measurement of these quantities obtained by microwave spectroscopy, resonant tunneling between fluxoid wells and decay of the excited state. The oscillation's waveform is compared to analytical results obtained for finite decay rates and detuning and averaged over low frequency flux noise.",

keywords = "Decoherence, Flux qubit, SQUIDs, Superconducting qubits",

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T1 - Decoherence in rf SQUID qubits

AU - Bennett, Douglas A.

AU - Longobardi, Luigi

AU - Patel, Vijay

AU - Chen, Wei

AU - Averin, Dmitri V.

AU - Lukens, James E.

PY - 2009/6

Y1 - 2009/6

N2 - We report measurements of coherence times of an rf SQUID qubit using pulsed microwaves and rapid flux pulses. The modified rf SQUID, described by an double-well potential, has independent, in situ, controls for the tilt and barrier height of the potential. The decay of coherent oscillations is dominated by the lifetime of the excited state and low frequency flux noise and is consistent with independent measurement of these quantities obtained by microwave spectroscopy, resonant tunneling between fluxoid wells and decay of the excited state. The oscillation's waveform is compared to analytical results obtained for finite decay rates and detuning and averaged over low frequency flux noise.

AB - We report measurements of coherence times of an rf SQUID qubit using pulsed microwaves and rapid flux pulses. The modified rf SQUID, described by an double-well potential, has independent, in situ, controls for the tilt and barrier height of the potential. The decay of coherent oscillations is dominated by the lifetime of the excited state and low frequency flux noise and is consistent with independent measurement of these quantities obtained by microwave spectroscopy, resonant tunneling between fluxoid wells and decay of the excited state. The oscillation's waveform is compared to analytical results obtained for finite decay rates and detuning and averaged over low frequency flux noise.

KW - Decoherence

KW - Flux qubit

KW - SQUIDs

KW - Superconducting qubits

UR - https://www.scopus.com/pages/publications/62649115924

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DO - 10.1007/s11128-009-0099-8

M3 - Article

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SP - 217

EP - 243

JO - Quantum Information Processing

JF - Quantum Information Processing

IS - 2-3

ER -

Decoherence in rf SQUID qubits

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Keywords

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