Decoherence of a tunable capacitively shunted flux qubit

  1. R. Trappen,
  2. X. Dai,
  3. M. A. Yurtalan,
  4. D. Melanson,
  5. D. M. Tennant,
  6. A. J. Martinez,
  7. Y. Tang,
  8. J. Gibson,
  9. J. A. Grover,
  10. S. M. Disseler,
  11. J. I. Basham,
  12. R. Das,
  13. D. K. Kim,
  14. A. J. Melville,
  15. B. M. Niedzielski,
  16. C. F. Hirjibehedin,
  17. K. Serniak,
  18. S. J. Weber,
  19. J.L. Yoder,
  20. W. D. Oliver,
  21. D. A. Lidar,
  22. and A. Lupascu
We present a detailed study of the coherence of a tunable capacitively-shunted flux qubit, designed for coherent quantum annealing applications. The measured relaxation at the qubit symmetry point is mainly due to intrinsic flux noise in the main qubit loop for qubit frequencies below ∼3 GHz. At higher frequencies, thermal noise in the bias line makes a significant contribution to the relaxation, arising from the design choice to experimentally explore both fast annealing and high-frequency control. The measured dephasing rate is primarily due to intrinsic low-frequency flux noise in the two qubit loops, with additional contribution from the low-frequency noise of control electronics used for fast annealing. The flux-bias dependence of the dephasing time also reveals apparent noise correlation between the two qubit loops, possibly due to non-local sources of flux noise or junction critical-current noise. Our results are relevant for ongoing efforts toward building superconducting quantum annealers with increased coherence.
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