Quantum turnstiles for robust measurement of full counting statistics

POSTER

Abstract

We present a scalable protocol for measuring full counting statistics (FCS) in experiments or tensor-network simulations. In this method, an ancilla in the middle of the system acts as a turnstile, with its phase keeping track of the time-integrated particle flux. Unlike quantum gas microscopy, the turnstile protocol faithfully captures FCS starting from number-indefinite initial states or in the presence of noisy dynamics. In addition, by mapping the FCS onto a single-body observable, it allows for stable numerical calculations of FCS using approximate tensor-network methods. We demonstrate the wide-ranging utility of this approach by computing the FCS of the transferred magnetization in a Floquet Heisenberg spin chain, as studied in a recent experiment with superconducting qubits, as well as the FCS of charge transfer in random circuits.

*We acknowledge support from the Princeton Quantum Initiative Fellowship (R.S.), the National Science Foundation through grants DMR-2103938 (E.M., S.G.) and DMR-2104141 (E.M., R.V.), the US Department of Energy, Office of Science, Basic Energy Sciences, under Early Career Award No. DE-SC0021111 (V.K.), the Alfred P. Sloan Foundation through a Sloan Research Fellowship (R.V., V.K.), and the Packard Foundation through a Packard Fellowship (V.K.).

Publication: arXiv:2305.15464 [quant-ph] (2023)
arXiv:2306.09333 [quant-ph] (2023)

Presenters

  • Rhine Samajdar

    • Princeton University

Authors

  • Rhine Samajdar

    • Princeton University

  • Ewan R McCulloch

    • University of Massachusetts Amherst

  • Eliott N Rosenberg

    • Google Quantum AI

  • Vedika Khemani

    • Stanford University

  • Romain Vasseur

    • University of Massachusetts Amherst

  • Sarang Gopalakrishnan

    • Princeton University
    • Department of Electrical and Computer Engineering, Princeton University
    • Princeton