Tunable coupling between long-lived microwave cavity modes

ORAL

Abstract

Superconducting microwave cavities are a promising resource for the storage of quantum states of photons. Further, coupling cavities to nonlinear transmon qubit modes enables the efficient manipulation and readout of these states. However, this results in increased relaxation and dephasing rates associated with the transmon. Thus, a direct coupling between neighboring cavities is a desirable resource for interfering quantum states stored in separate cavity modes. Here we discuss the implementation of an engineered coupling between two cavity modes via an RF-driven frequency-conversion that uses the nonlinearity of a transmon coupled to both cavities. Importantly, this coupling does not directly excite the transmon, thus suppressing the effect of transmon decoherence. We demonstrate the tunability of the coupling strength, which minimizes unwanted interactions, and realize a 50:50 beamsplitter two orders of magnitude faster than the cavity decoherence. We observe high-contrast interference between single microwave photons, which will be useful as an element in larger quantum algorithms.

*We acknowledge support from the U.S. Army Research Office, BJL from the Yale QIMP Fellowship, YYG from an A*STAR NSS Fellowship, SMG from the NSF, and LJ the Alfred P. Sloan and Packard Foundations.

Presenters

  • Brian Lester

    • Yale University
    • Applied Physics, Yale University
    • JILA, University of Colorado

Authors

  • Brian Lester

    • Yale University
    • Applied Physics, Yale University
    • JILA, University of Colorado

  • Yvonne Gao

    • Physics, Yale University
    • Dept. of Applied Physics, Yale University

  • Chen Wang

    • Univ of Mass - Amherst
    • Physics, University of Massachusetts at Amherst
    • University of Massachusetts

  • Serge Rosenblum

    • Yale University
    • Applied Physics, Yale University
    • Applied Physics, Yale Univ

  • Luigi Frunzio

    • Yale University
    • Applied Physics, Yale University
    • Physics and Applied Physics, Yale University
    • Applied Physics, Yale Univ
    • Dept. of Applied Physics, Yale University
    • Department of Applied Physics, Yale Univ
    • Yale Univ
    • Departments of Applied Physics and Physics, Yale University

  • Michel Devoret

    • Yale University
    • Applied Physics, Yale University
    • Department of Applied Physics, Yale University
    • Applied Physics, Yale Univ
    • Physics and Applied Physics, Yale University
    • Yale Univ
    • Dept. of Applied Physics, Yale University
    • Department of Applied Physics, Yale Univ

  • Steven Girvin

    • Yale University
    • Applied Physics, Yale University
    • Department of Physics, Yale University
    • Yale Quantum Institute, Yale University

  • Liang Jiang

    • Yale University
    • Applied Physics, Yale University
    • Yale
    • Dept. of Applied Physics, Yale University

  • Robert Schoelkopf

    • Yale University
    • Applied Physics, Yale University
    • Physics and Applied Physics, Yale University
    • Applied Physics, Yale Univ
    • Dept. of Applied Physics, Yale University
    • Departments of Applied Physics and Physics, Yale University