Quantum control of an oscillator with a Kerr-cat qubit

Invited-In-person  · Invited

Abstract

Bosonic codes offer a hardware-efficient strategy for quantum error correction by redundantly encoding quantum information in the large Hilbert space of a harmonic oscillator. However, experimental realizations of these codes are often limited by ancilla errors propagating to the encoded logical qubit during syndrome measurements. The Kerr-cat qubit has been proposed as an ancilla for these codes due to its theoretically-exponential noise bias, which would enable fault-tolerant error syndrome measurements, but the coupling required to perform these syndrome measurements has not yet been demonstrated. In this work, we experimentally realize driven parametric coupling of a Kerr-cat qubit to a high-quality-factor microwave cavity and demonstrate a gate set that would enable universal quantum control of the cavity. We measure the decoherence of the cavity in the presence of the Kerr-cat and discover excess dephasing due to heating of the Kerr-cat to excited states. By engineering frequency-selective dissipation to counteract this heating, we are able to eliminate this dephasing, thereby demonstrating a high on-off ratio of control. Our results pave the way toward using the Kerr-cat to fault-tolerantly measure error syndromes of bosonic codes.

Presenters

  • Andy Ding

    • AWS Center for Quantum Computing

Authors

  • Andy Ding

    • AWS Center for Quantum Computing
  • Benjamin Brock

    • Université de Sherbrooke
  • Alec Eickbusch

    • Google Quantum AI
  • Akshay Koottandavida

  • Nicholas Frattini

    • Nord Quantique
  • Rodrigo Cortinas

    • Google Quantum AI
  • Vidul Joshi

    • Yale University
  • Stijn de Graaf

    • Yale University
  • Benjamin Chapman

    • Yale University
  • Suhas Ganjam

    • Google LLC
  • Luigi Frunzio

    • Yale University
  • Robert Schoelkopf

    • Yale University
  • Michel Devoret