Cavity-Coupled Neutral Atom Array Part 1: Site-selective Cavity Readout

Edita Bytyqi; Beili Hu; Josiah John Sinclair; Michelle Chong; Alyssa Rudelis; Joshua Ramette; Zachary Vendeiro; Vladan Vuletic

Cavity-Coupled Neutral Atom Array Part 1: Site-selective Cavity Readout

ORAL

Abstract

Neutral atom arrays coupled to optical cavities have emerged as a powerful platform for quantum information science. Optical cavities facilitate fast and non-destructive readout of individual atomic qubits. However, scaling to large qubit arrays remains a challenge. By employing locally addressed excited-state Stark shifts to detune atoms from resonance, we achieve site-selective hyperfine-state cavity readout across a 10-site array. The state discrimination fidelity reaches 0.994(1) for a single atom and averages 0.989(2) across the entire array, with a survival probability of 0.975(1). These advancements pave the way towards fault-tolerant quantum computing by enabling repeated rounds of error correction.

June 19, 2025, 10:30 AM – June 19, 2025, 10:42 AM

Publication: Hu, B., Sinclair, J., Bytyqi, E., Chong, M., Rudelis, A., Ramette, J., Vendeiro, Z., & Vuletić, V. (2024). Site-selective cavity readout and classical error correction of a 5-bit atomic register. arXiv:2408.15329

Presenters

Edita Bytyqi

Massachusetts Institute of Technology, MIT

Authors

Edita Bytyqi

Massachusetts Institute of Technology, MIT
Beili Hu

Massachusetts Institute of Technology
Josiah John Sinclair

Massachusetts Institute of Technology
Michelle Chong

University of Chicago, Massachusetts Institute of Technology
Alyssa Rudelis

Massachusetts Institute of Technology
Joshua Ramette

Massachusetts Institute of Technology
Zachary Vendeiro

Massachusetts Institute of Technology, Atom Computing
Vladan Vuletic

Massachusetts Institute of Technology