High-fidelity gates with mid-circuit erasure conversion in a metastable neutral atom qubit

Pai Peng; Shuo Ma; Genyue Liu; Bichen Zhang; Sven Jandura; Jahan Claes; Alex Burgers; Guido Pupillo; Shruti Puri; Jeff D Thompson

High-fidelity gates with mid-circuit erasure conversion in a metastable neutral atom qubit

ORAL · Invited

Abstract

Rydberg atoms in optical tweezer arrays have progressed rapidly in recent years, demonstrating programmable processors and quantum simulators with scaling to hundreds of atoms. Alkaline earth atoms, in particular, provide novel avenues for enhancing coherence, control and scalability. For example, in the context of eventual application in fault-tolerant quantum computing, it is advantages to implement qubits with structured error models, such as detectable erasure errors. In a recent work [1], we demonstrate high-fidelity gates and erasure conversion using a new neutral atom qubit — nuclear spin levels of a long-lived metastable state in 171Yb. The long coherence time and fast excitation to the Rydberg state enable one- and two-qubit gates with fidelities of 0.9990(1) and 0.980(1), respectively. Importantly, we show that 56% of single-qubit gate errors and 33% of two-qubit gate errors are converted into erasure through fast mid-circuit detection of ground state atoms.

[1] S. Ma, G. Liu, P. Peng, et al. Nature 622 279 (2023).

^*We acknowledge helpful conversations with Shimon Kolkowitz and Michael Gullans. This work was supported by the Army Research Office (W911NF-1810215), the Office of Naval Research (N00014-20- 1-2426), DARPA ONISQ (W911NF-20-10021), the National Science Foundation (QLCI grant OMA-2120757), and the Sloan Foundation. This research also received funding from the European Union's Horizon 2020 program under the Marie Sklodowska-Curie project 955479 (MOQS), the Horizon Europe program HORIZON-CL4-2021- DIGITALEMERGING-01-30 via the project 101070144 (EuRyQa) and from the French National Research Agency under the Investments of the Future Program project ANR-21-ESRE-0032 (aQCess).

March 5, 2024, 4:12 PM – March 5, 2024, 4:48 PM

Publication: S. Ma, G. Liu, P. Peng, et al. Nature 622 279 (2023).

Presenters

Pai Peng
- Princeton

Authors

Pai Peng
- Princeton
Shuo Ma
- Princeton University
Genyue Liu
- Princeton University
Bichen Zhang
- Princeton University
Sven Jandura
- University of Strasbourg
Jahan Claes
- Yale University
Alex Burgers
- Princeton
Guido Pupillo
- University of Strasbourg
Shruti Puri
- Yale University
Jeff D Thompson
- Princeton University