A Race-Track Trapped-Ion Quantum Processor

Moses, Steven A.; Baldwin, Charles H.; Allman, M. S.; Ancona, R.; Ascarrunz, L.; Barnes, C. H. W.; Bartolotta, John P.; Bjork, Bryce; Blanchard, P.; Bohn, Matthew J.; Bohnet, J. G.; Brown, N. C.; Burdick, N. Q.; Burton, William Cody; Campbell, Sara; Campora, J. P.; Carron, C.; Chambers, Jeanne C.; Chan, J. W.; Chen, Yu‐Hsin; Chernoguzov, A.; Chertkov, Eli; Colina, J.; Curtis, J. P.; Daniel, Ryszard A.; DeCross, Matthew; Deen, David A.; Delaney, Conor P.; Dreiling, Joan; Ertsgaard, Christopher; Esposito, J.; Estey, Brian; Fabrikant, Maya; Figgatt, Caroline; Foltz, Clémence; Foss‐Feig, Michael; Francois, David; Gaebler, John; Gatterman, Thomas; Gilbreth, C. N.; Giles, J.; Glynn, E.; Hall, Alex; Hankin, Aaron; Hansen, Ann‐Brit Eg; Hayes, David; Higashi, B.; Hoffman, Ian M.; Horning, B.; Hout, J. J.; Jacobs, Ryan T.; Johansen, Jacob; Jones, Lyndon; Karcz, J.; Klein, T.; Lauria, P.; Lee, Patricia; Liefer, D.; Lu, Shih-Wen; Lucchetti, D.; Lytle, C.; Malm, Andrew; Matheny, Mitchell; Mathewson, B.; Mayer, Karl; Miller, David B.; Mills, Michael; Neyenhuis, B.; Nugent, Lora; Olson, S. Jay; Parks, J.; Price, Gabriel; Price, Z.; Pugh, M. C.; Ransford, Anthony; Reed, Adam; Roman, Conrad; Röwe, M.; Ryan-Anderson, Ciarán; Sanders, S.; Sedlacek, J.; Shevchuk, P.; Siegfried, P.; Skripka, T.; Spaun, B.; Sprenkle, R. T.; Stutz, Russell; Swallows, M. D.; Tobey, R.; Tran, An V.; Tran, Thinh Ngoc; Vogt, Erich; Volin, Curtis; Walker, J.; Zolot, A. M.; Pino, Juan Miguel Rey

doi:10.1103/physrevx.13.041052

articlePhysical Review XDec 18, 2023GOLD OA

A Race-Track Trapped-Ion Quantum Processor

SASteven A. Moses CHCharles H. Baldwin MSM. S. Allman RAR. Ancona LAL. Ascarrunz

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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, multilayer 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)×10^{-3}, an average single-qubit…

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Keywords

Qubit
Computer science
Quantum computer
Quantum entanglement
Quantum
Quantum gate
Computer engineering
Physics

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