Energy Decay in Josephson Qubits from Off-Resonant Coupling to Two-Level States

J. Martinis; M. Ansmann; R. Bialczak; N. Katz; E. Lucero; R. McDermott; Matthew Neeley; A. O'Connell; M. Steffen; E. Weig; A. Cleland

Energy Decay in Josephson Qubits from Off-Resonant Coupling to Two-Level States

ORAL

Abstract

Decoherence of Josephson qubits is thought to be protected from dielectric loss of two-level states by using sub-micrometer tunnel junctions that statistically avoids resonant coupling. Here, we calculate that off-resonant coupling and the subsequent phonon radiation of the two-level states may produce significant energy loss even for ultra-small junctions. This theory possibly explains several key features in a variety of experimental data for phase, flux, and charge qubits, such as the magnitude of the observed energy decay time, its statistical variation, and the increased decay rate with qubit area and frequency.

March 7, 2007, 10:51 AM – March 7, 2007, 11:03 AM

Authors

J. Martinis
- Physics Department, University of California, Santa Barbara , Santa Barbara, California 93106
- UC Santa Barbara
M. Ansmann
- UC Santa Barbara
R. Bialczak
- U.C. Santa Barbara
- UC Santa Barbara
N. Katz
- UC Santa Barbara
E. Lucero
- UC Santa Barbara
R. McDermott
- University of Wisconsin-Madison
- University of Wisconsin
Matthew Neeley
- UC Santa Barbara
A. O'Connell
- UC Santa Barbara
M. Steffen
- UC Santa Barbara
E. Weig
- UC Santa Barbara
A. Cleland
- University of California, Santa Barbara
- UC Santa Barbara