Chiral Flow on Digital Quantum Processors

ORAL

Abstract

Nonequilibrium topological phases of matter can exhibit edge (surface) phenomena which cannot be replicated in their static counterparts. We demonstrate chiral flow, a feature describing topological behavior in driven systems, using state-of-the-art digital quantum processors. With quantum circuit compression techniques, we design and implement a Floquet Hamiltonian which generates unitary evolution exhibiting nontrivial bulk-boundary correspondence. Given the intrinsic noise of the quantum hardware, we are effectively studying anomalous Floquet modes in an open quantum system. Our protocol shows that the driving frequency offers a potential method for mitigating the effects of noise in long-time simulations.

*This material is based upon work supported by the Sivian Fund and the Paul Dirac Fund at the Institute for Advanced Study and the U.S. Department of Energy, Office of Science, Office of High Energy Physics under Award Number DE-SC0009988 (A.P.).

Publication: Planned paper: "Anomalous Floquet Topological Modes on a Driven Quantum Simulator"

Presenters

  • Karlo Reyes

    • University of Southern California

Authors

  • Miguel Mercado

    • University of Southern California

  • Karlo Reyes

    • University of Southern California

  • Abhinav Prem

    • Institute for Advanced Study (IAS)

  • Aiichiro Nakano

    • University of Southern California

  • Rosa DiFelice

    • University of Southern California, CNR Institute of Nanoscience
    • University of Southern California

  • Stephan W Haas

    • University of Southern California