Multi-qubit gates and Schrödinger cat states in an optical clock. Journal Article uri icon

Overview

abstract

  • Many-particle entanglement is a key resource for achieving the fundamental precision limits of a quantum sensor1. Optical atomic clocks2, the current state of the art in frequency precision, are a rapidly emerging area of focus for entanglement-enhanced metrology3-6. Augmenting tweezer-based clocks featuring microscopic control and detection7-10 with the high-fidelity entangling gates developed for atom-array information processing11,12 offers a promising route towards making use of highly entangled quantum states for improved optical clocks. Here we develop and use a family of multi-qubit Rydberg gates to generate Schrödinger cat states of the Greenberger-Horne-Zeilinger (GHZ) type with up to nine optical clock qubits in a programmable atom array. In an atom-laser comparison at sufficiently short dark times, we demonstrate a fractional frequency instability below the standard quantum limit (SQL) using GHZ states of up to four qubits. However, because of their reduced dynamic range, GHZ states of a single size fail to improve the achievable clock precision at the optimal dark time compared with unentangled atoms13. Towards overcoming this hurdle, we simultaneously prepare a cascade of varying-size GHZ states to perform unambiguous phase estimation over an extended interval14-17. These results demonstrate key building blocks for approaching Heisenberg-limited scaling of optical atomic clock precision.

publication date

  • October 1, 2024

has restriction

  • closed

Date in CU Experts

  • October 19, 2024 1:36 AM

Full Author List

  • Cao A; Eckner WJ; Lukin Yelin T; Young AW; Jandura S; Yan L; Kim K; Pupillo G; Ye J; Darkwah Oppong N

author count

  • 11

published in

Other Profiles

Electronic International Standard Serial Number (EISSN)

  • 1476-4687

Additional Document Info

start page

  • 315

end page

  • 320

volume

  • 634

issue

  • 8033