To catch and reverse a quantum jump mid-flight

ORAL

Abstract

A quantum system driven by a weak deterministic force while under strong continuous observation exhibits quantum jumps between its energy levels. Employing a three-level superconducting artificial atom of the V-type involved in the original observation of quantum jumps, we show that quantum jumps can be caught and even reversed mid-flight. The three required levels are: G (for Ground), B (for Bright), and D (for Dark). The D level is engineered to be decoupled from both any dissipative environment and any measurement apparatus. Quantum jumps between G and D are monitored indirectly by the combination of a Rabi drive between the G and B levels, together with the monitoring of the occupation of B, itself tracked by a dispersively-coupled readout cavity. Using digital low-latency feedback electronics, we demonstrate the catch of a quantum jump mid-flight, i.e. a coherent superposition of D (corresponding to having jumped) and G (corresponding to having not jumped). The fidelity of the mid-flight state is above 70%, in agreement with quantum trajectory theory simulations. Our monitoring scheme can be useful for other quantum information tasks, such as the continuous monitoring of error syndromes.

*Work supported by: ARO, ONR, NSF, AFOSR, and YINQE

Presenters

  • Zlatko Minev

    • Department of Applied Physics, Yale University
    • Yale
    • Department of Applied Physics, Yale Univ
    • Applied Physics, Yale University

Authors

  • Zlatko Minev

    • Department of Applied Physics, Yale University
    • Yale
    • Department of Applied Physics, Yale Univ
    • Applied Physics, Yale University

  • Shantanu Mundhada

    • Applied Physics, Yale University
    • Department of Applied Physics, Yale Univ

  • Shyam Shankar

    • Applied Physics, Yale University
    • Department of Applied Physics, Yale University
    • Department of Applied Physics, Yale Univ
    • Yale Univ

  • Philip Reinhold

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

  • Ricardo Gutiérrez-Jáuregui

    • Physics, Dodd-Walls Centre for Photonic and Quantum Technologies

  • Robert Schoelkopf

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

  • Mazyar Mirrahimi

    • Applied Physics, Yale Univ
    • Yale University
    • Inria and Yale Quantum Institute
    • Yale Quantum Institute, Yale University, New Haven, CT, United States; INRIA
    • INRIA Paris
    • QUANTIC team, INRIA de Paris
    • 3. INRIA Paris and Yale Quantum Institute

  • Howard Carmichael

    • Physics, Dodd-Walls Centre for Photonic and Quantum Technologies

  • 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