Fault-tolerant control of an error-corrected qubit.

Abstract

Quantum error correction protects fragile quantum information by encoding it into a larger quantum system1,2. These extra degrees of freedom enable the detection and correction of errors, but also increase the control complexity of the encoded logical qubit. Fault-tolerant circuits contain the spread of errors while controlling the logical qubit, and are essential for realizing error suppression in practice3-6. Although fault-tolerant design works in principle, it has not previously been demonstrated in an error-corrected physical system with native noise characteristics. Here we experimentally demonstrate fault-tolerant circuits for the preparation, measurement, rotation and stabilizer measurement of a Bacon-Shor logical qubit using 13 trapped ion qubits. When we compare these fault-tolerant protocols to non-fault-tolerant protocols, we see significant reductions in the error rates of the logical primitives in the presence of noise. The result of fault-tolerant design is an average state preparation and measurement error of 0.6 per cent and a Clifford gate error of 0.3 per cent after offline error correction. In addition, we prepare magic states with fidelities that exceed the distillation threshold7, demonstrating all of the key single-qubit ingredients required for universal fault-tolerant control. These results demonstrate that fault-tolerant circuits enable highly accurate logical primitives in current quantum systems. With improved two-qubit gates and the use of intermediate measurements, a stabilized logical qubit can be achieved.

Department

Description

Provenance

Subjects

Citation

Published Version (Please cite this version)

10.1038/s41586-021-03928-y

Publication Info

Egan, Laird, Dripto M Debroy, Crystal Noel, Andrew Risinger, Daiwei Zhu, Debopriyo Biswas, Michael Newman, Muyuan Li, et al. (2021). Fault-tolerant control of an error-corrected qubit. Nature, 598(7880). pp. 281–286. 10.1038/s41586-021-03928-y Retrieved from https://hdl.handle.net/10161/25736.

This is constructed from limited available data and may be imprecise. To cite this article, please review & use the official citation provided by the journal.

Scholars@Duke

Noel

Crystal Noel

Assistant Professor of Electrical and Computer Engineering

Prof. Noel's research interests include both the technology development for scalable ion trap quantum computers, as well as using existing ion trap quantum computers for relevant demonstrations, tests, and simulations.

Brown

Kenneth R Brown

Michael J. Fitzpatrick Distinguished Professor of Engineering

Prof. Brown's research interest is the control of quantum systems for both understanding the natural world and developing new technologies. His current research areas are the development of robust quantum computers and the study of molecular properties at cold and ultracold temperatures.

Cetina

Marko Cetina

Assistant Professor of Physics
Monroe

Christopher R Monroe

Gilhuly Family Presidential Distinguished Professor

Unless otherwise indicated, scholarly articles published by Duke faculty members are made available here with a CC-BY-NC (Creative Commons Attribution Non-Commercial) license, as enabled by the Duke Open Access Policy. If you wish to use the materials in ways not already permitted under CC-BY-NC, please consult the copyright owner. Other materials are made available here through the author’s grant of a non-exclusive license to make their work openly accessible.