Spectroscopy of Three-Particle Entanglement in a Macroscopic
  Superconducting Circuit

A. J. Berkley; A. J. Dragt; A. J. Leggett; C. J. Lobb; F. C. Wellstood; Frederick W. Strauch; H. Paik; Huizhong Xu; J. R. Anderson; M. A. Nielsen; P. W. Shor; Philip R. Johnson; R. C. Ramos; S. K. Dutta; S. Lloyd

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Spectroscopy of Three-Particle Entanglement in a Macroscopic Superconducting Circuit

Authors: A. J. Berkley
A. J. Dragt
A. J. Leggett
C. J. Lobb
F. C. Wellstood
Frederick W. Strauch
H. Paik
Huizhong Xu
J. R. Anderson
M. A. Nielsen
P. W. Shor
Philip R. Johnson
R. C. Ramos
S. K. Dutta
S. Lloyd
Publication date: 12 August 2005
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We study the quantum mechanical behavior of a macroscopic, three-body, superconducting circuit. Microwave spectroscopy on our system, a resonator coupling two large Josephson junctions, produced complex energy spectra well explained by quantum theory over a large frequency range. By tuning each junction separately into resonance with the resonator, we first observe strong coupling between each junction and the resonator. Bringing both junctions together into resonance with the resonator, we find spectroscopic evidence for entanglement between all three degrees of freedom and suggest a new method for controllable coupling of distant qubits, a key step toward quantum computation.Comment: 4 pages, 3 figure

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