2005
DOI: 10.1103/physrevlett.95.147001
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Andreev Probe of Persistent Current States in Superconducting Quantum Circuits

Abstract: Using the extraordinary sensitivity of Andreev interferometers to the superconducting phase difference associated with currents, we measure the persistent current quantum states in superconducting loops interrupted by Josephson junctions. Straightforward electrical resistance measurements of the interferometers give continuous read-out of the states, allowing us to construct the energy spectrum of the quantum circuit. The probe is estimated to be more precise and faster than previous methods, and can measure t… Show more

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Cited by 21 publications
(26 citation statements)
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“…Theoretically, we explain these as different phase states, corre-sponding to separate nonequilibrium-induced 0-transitions in two of the S-N-S Josephson junctions inside the interferometer. Our findings show how the conductance can be used to monitor the phase states, in accord with a recent suggestion [5].…”
supporting
confidence: 91%
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“…Theoretically, we explain these as different phase states, corre-sponding to separate nonequilibrium-induced 0-transitions in two of the S-N-S Josephson junctions inside the interferometer. Our findings show how the conductance can be used to monitor the phase states, in accord with a recent suggestion [5].…”
supporting
confidence: 91%
“…Such a system is called an Andreev interferometer as the oscillations are a result of quantum interference of quasiparticles that are Andreev reflected at the NS interfaces [2]. The influence of the phase on the observables of mesoscopic conductors [3][4][5] is reciprocated by the fact that the electronic properties of the N side affect the phase state of the superconductors. Examples of this are the -states found in nonequilibrium S-N-S Andreev interferometers [6,7] and in S-F-S junctions [8,9], where F stands for a ferromagnet.…”
mentioning
confidence: 99%
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“…[1][2][3][4][5][6][7][8][9][10] These devices can be grouped into three broad classes: charge, flux and phase qubits, according to which dynamical variable is most sharply defined and which basis states are used. In this paper we examine the quantum behavior of the dc Superconducting Quantum Interference Device (SQUID) phase qubit, investigate the optimization of the device and discuss how well this design provides isolation while preserving the characteristics of a phase qubit.…”
Section: Introductionmentioning
confidence: 99%