Frontiers in Quantum Science and Technology (Aug 2023)

Continuous dynamical decoupling of optical 171Yb+ qudits with radiofrequency fields

  • Ilia V. Zalivako,
  • Ilia V. Zalivako,
  • Alexander S. Borisenko,
  • Alexander S. Borisenko,
  • Ilya A. Semerikov,
  • Ilya A. Semerikov,
  • Andrey E. Korolkov,
  • Andrey E. Korolkov,
  • Pavel L. Sidorov,
  • Pavel L. Sidorov,
  • Kristina P. Galstyan,
  • Kristina P. Galstyan,
  • Nikita V. Semenin,
  • Nikita V. Semenin,
  • Vasiliy N. Smirnov,
  • Vasiliy N. Smirnov,
  • Mikhail D. Aksenov,
  • Aleksey K. Fedorov,
  • Ksenia Yu Khabarova,
  • Ksenia Yu Khabarova,
  • Nikolay N. Kolachevsky,
  • Nikolay N. Kolachevsky

DOI
https://doi.org/10.3389/frqst.2023.1228208
Journal volume & issue
Vol. 2

Abstract

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The use of multilevel quantum information carriers, also known as qudits, has attracted significant interest as a way of further scaling quantum computing devices. However, such multilevel systems usually express shorter coherence time than their two-level counterparts, which limits their computational potential. We thus propose and experimentally demonstrate two approaches for realizing the continuous dynamical decoupling of magnetic-sensitive states with mF = ±1 for qudits encoded in optical transition of trapped 171Yb+ ions. We improve the coherence time of qudit levels by an order of magnitude (more than 9 ms) without any magnetic shielding, revealing the potential advantage of the symmetry of the 171Yb+ ion energy structure for counteracting magnetic field noise. Our results are a step toward realizing qudit-based algorithms using trapped ions.

Keywords