English

A Race Track Trapped-Ion Quantum Processor

Quantum Physics 2023-12-20 v2

Abstract

We describe and benchmark a new quantum charge-coupled device (QCCD) trapped-ion quantum computer based on a linear trap with periodic boundary conditions, which resembles a race track. The new system successfully incorporates several technologies crucial to future scalability, including electrode broadcasting, multi-layer RF routing, and magneto-optical trap (MOT) loading, while maintaining, and in some cases exceeding, the gate fidelities of previous QCCD systems. The system is initially operated with 32 qubits, but future upgrades will allow for more. We benchmark the performance of primitive operations, including an average state preparation and measurement error of 1.6(1)×103\times 10^{-3}, an average single-qubit gate infidelity of 2.5(3)×1052.5(3)\times 10^{-5}, and an average two-qubit gate infidelity of 1.84(5)×1031.84(5)\times 10^{-3}. The system-level performance of the quantum processor is assessed with mirror benchmarking, linear cross-entropy benchmarking, a quantum volume measurement of QV=216\mathrm{QV}=2^{16}, and the creation of 32-qubit entanglement in a GHZ state. We also tested application benchmarks including Hamiltonian simulation, QAOA, error correction on a repetition code, and dynamics simulations using qubit reuse. We also discuss future upgrades to the new system aimed at adding more qubits and capabilities.

Keywords

Cite

@article{arxiv.2305.03828,
  title  = {A Race Track Trapped-Ion Quantum Processor},
  author = {S. A. Moses and C. H. Baldwin and M. S. Allman and R. Ancona and L. Ascarrunz and C. Barnes and J. Bartolotta and B. Bjork and P. Blanchard and M. Bohn and J. G. Bohnet and N. C. Brown and N. Q. Burdick and W. C. Burton and S. L. Campbell and J. P. Campora and C. Carron and J. Chambers and J. W. Chan and Y. H. Chen and A. Chernoguzov and E. Chertkov and J. Colina and J. P. Curtis and R. Daniel and M. DeCross and D. Deen and C. Delaney and J. M. Dreiling and C. T. Ertsgaard and J. Esposito and B. Estey and M. Fabrikant and C. Figgatt and C. Foltz and M. Foss-Feig and D. Francois and J. P. Gaebler and T. M. Gatterman and C. N. Gilbreth and J. Giles and E. Glynn and A. Hall and A. M. Hankin and A. Hansen and D. Hayes and B. Higashi and I. M. Hoffman and B. Horning and J. J. Hout and R. Jacobs and J. Johansen and L. Jones and J. Karcz and T. Klein and P. Lauria and P. Lee and D. Liefer and C. Lytle and S. T. Lu and D. Lucchetti and A. Malm and M. Matheny and B. Mathewson and K. Mayer and D. B. Miller and M. Mills and B. Neyenhuis and L. Nugent and S. Olson and J. Parks and G. N. Price and Z. Price and M. Pugh and A. Ransford and A. P. Reed and C. Roman and M. Rowe and C. Ryan-Anderson and S. Sanders and J. Sedlacek and P. Shevchuk and P. Siegfried and T. Skripka and B. Spaun and R. T. Sprenkle and R. P. Stutz and M. Swallows and R. I. Tobey and A. Tran and T. Tran and E. Vogt and C. Volin and J. Walker and A. M. Zolot and J. M. Pino},
  journal= {arXiv preprint arXiv:2305.03828},
  year   = {2023}
}

Comments

24 pages, 24 figures. Made some minor edits and added several more authors

R2 v1 2026-06-28T10:27:22.564Z