omg blueprint for trapped ion quantum computing with metastable states

Quantum computers, much like their classical counterparts, will likely benefit from flexible qubit encodings that can be matched to different tasks. For trapped ion quantum processors, a common way to access multiple encodings is to use multiple, co-trapped atomic species. Here, we outline an altern...

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Veröffentlicht in:	Applied physics letters 2021-11, Vol.119 (21)
Hauptverfasser:	Allcock, D. T. C., Campbell, W. C., Chiaverini, J., Chuang, I. L., Hudson, E. R., Moore, I. D., Ransford, A., Roman, C., Sage, J. M., Wineland, D. J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Metastable state Quantum computers Quantum computing Qubits (quantum computing) System effectiveness
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container_title	Applied physics letters
container_volume	119
creator	Allcock, D. T. C. Campbell, W. C. Chiaverini, J. Chuang, I. L. Hudson, E. R. Moore, I. D. Ransford, A. Roman, C. Sage, J. M. Wineland, D. J.
description	Quantum computers, much like their classical counterparts, will likely benefit from flexible qubit encodings that can be matched to different tasks. For trapped ion quantum processors, a common way to access multiple encodings is to use multiple, co-trapped atomic species. Here, we outline an alternative approach that allows flexible encoding capabilities in single-species systems through the use of long-lived metastable states as an effective, programmable second species. We describe the set of additional trapped ion primitives needed to enable this protocol and show that they are compatible with large-scale systems that are already in operation.
doi_str_mv	10.1063/5.0069544
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subjects	Applied physics Metastable state Quantum computers Quantum computing Qubits (quantum computing) System effectiveness
title	omg blueprint for trapped ion quantum computing with metastable states
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