English

Operating a multi-ion clock with dynamical decoupling

Atomic Physics 2024-08-13 v1

Abstract

We study and characterize a quasi-continuous dynamical decoupling (QCDD) scheme that effectively suppresses dominant frequency shifts in a multi-ion optical clock. Addressing the challenge of inhomogeneous frequency shifts in such systems, our scheme mitigates primary contributors, namely the electric quadrupole shift (QPS) and the linear Zeeman shift (LZS). Based on 88^{88}Sr+^+ ions, we implement a QCDD scheme in linear chains of up to 7 ions and demonstrate a significant suppression of the shift by more than three orders of magnitude, leading to relative frequency inhomogeneity below 710177\cdot10^{-17}. Additionally, we evaluate the associated systematic shift arising from the radiofrequency (RF) drive used in the QCDD scheme, showing that, in the presented realization, its contribution to the systematic relative frequency uncertainty is below 101710^{-17}, with potential for further improvement. These results provide a promising avenue toward implementing multi-ion clocks exhibiting an order of magnitude or more improvement in stability while maintaining a similar high degree of accuracy to that of single-ion clocks.

Keywords

Cite

@article{arxiv.2408.05280,
  title  = {Operating a multi-ion clock with dynamical decoupling},
  author = {Nitzan Akerman and Roee Ozeri},
  journal= {arXiv preprint arXiv:2408.05280},
  year   = {2024}
}

Comments

7 pages, 4 figures

R2 v1 2026-06-28T18:08:58.719Z