Controlling the arrow of time in circuit QED

ORAL

Abstract

The unitary time evolution of a quantum system implies that flipping the overall sign of a Hamiltonian is equivalent to reversing time. Time reversal operations have utility in, for example, measuring out-of-time-ordered correlators (OTOCs), which have been considered theoretically to quantify information scrambling and identify many-body localized phases. Following a proposal by Zhu, Hafezi, and Grover [Phys. Rev. A 94, 062329 (2016)], we present the design and preliminary measurements of a planar superconducting circuit where the sign of an effective Hamiltonian of bus-coupled qubits is controlled by the state of an ancilla qubit. We discuss some of the practical challenges of this approach and the implications for OTOC measurements.

*This work was supported by AFOSR MURI (16RT0696 and FA9550-15-1-0015); the IQIM, an NSF PFC (PHY-1125565) supported by the Gordon and Betty Moore Foundation (GBMF-2644); and the Kavli Nanoscience Institute at Caltech.

Presenters

  • Andrew Keller

    • Applied Physics and Material Science, Caltech
    • Caltech

Authors

  • Andrew Keller

    • Applied Physics and Material Science, Caltech
    • Caltech

  • Nicole Yunger Halpern

    • Institute for Quantum Information and Matter, California Institute of Technology
    • California Institute of Technology
    • Caltech

  • Paul Dieterle

    • Caltech

  • Michael Fang

    • Caltech

  • Alp Sipahigil

    • Applied Physics and Material Science, Caltech
    • Caltech

  • Oskar Painter

    • Applied Physics and Material Science, Caltech
    • Caltech
    • Applied Physics, Caltech
    • California Institute of Technology