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Hauptverfasser: Gupta, Riddhi S., Sundaresan, Neereja, Alexander, Thomas, Wood, Christopher J., Merkel, Seth T., Healy, Michael B., Hillenbrand, Marius, Jochym-O'Connor, Tomas, Wootton, James R., Yoder, Theodore J., Cross, Andrew W., Takita, Maika, Brown, Benjamin J.
Format: Preprint
Veröffentlicht: 2023
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Online-Zugang:https://arxiv.org/abs/2305.13581
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author Gupta, Riddhi S.
Sundaresan, Neereja
Alexander, Thomas
Wood, Christopher J.
Merkel, Seth T.
Healy, Michael B.
Hillenbrand, Marius
Jochym-O'Connor, Tomas
Wootton, James R.
Yoder, Theodore J.
Cross, Andrew W.
Takita, Maika
Brown, Benjamin J.
author_facet Gupta, Riddhi S.
Sundaresan, Neereja
Alexander, Thomas
Wood, Christopher J.
Merkel, Seth T.
Healy, Michael B.
Hillenbrand, Marius
Jochym-O'Connor, Tomas
Wootton, James R.
Yoder, Theodore J.
Cross, Andrew W.
Takita, Maika
Brown, Benjamin J.
contents To run large-scale algorithms on a quantum computer, error-correcting codes must be able to perform a fundamental set of operations, called logic gates, while isolating the encoded information from noise~\cite{Harper2019,Ryan-Anderson2021,Egan2021fault, Chen2022calibrated, Sundaresan2022matching, ryananderson2022implementing, Postler2022demonstration, GoogleAI2023}. We can complete a universal set of logic gates by producing special resources called magic states~\cite{Bravyi2005universal,Maier2013magic, Chamberland2022building}. It is therefore important to produce high-fidelity magic states to conduct algorithms while introducing a minimal amount of noise to the computation. Here, we propose and implement a scheme to prepare a magic state on a superconducting qubit array using error correction. We find that our scheme produces better magic states than those we can prepare using the individual qubits of the device. This demonstrates a fundamental principle of fault-tolerant quantum computing~\cite{Shor96}, namely, that we can use error correction to improve the quality of logic gates with noisy qubits. Additionally, we show we can increase the yield of magic states using adaptive circuits, where circuit elements are changed depending on the outcome of mid-circuit measurements. This demonstrates an essential capability we will need for many error-correction subroutines. Our prototype will be invaluable in the future as it can reduce the number of physical qubits needed to produce high-fidelity magic states in large-scale quantum-computing architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2305_13581
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Encoding a magic state with beyond break-even fidelity
Gupta, Riddhi S.
Sundaresan, Neereja
Alexander, Thomas
Wood, Christopher J.
Merkel, Seth T.
Healy, Michael B.
Hillenbrand, Marius
Jochym-O'Connor, Tomas
Wootton, James R.
Yoder, Theodore J.
Cross, Andrew W.
Takita, Maika
Brown, Benjamin J.
Quantum Physics
To run large-scale algorithms on a quantum computer, error-correcting codes must be able to perform a fundamental set of operations, called logic gates, while isolating the encoded information from noise~\cite{Harper2019,Ryan-Anderson2021,Egan2021fault, Chen2022calibrated, Sundaresan2022matching, ryananderson2022implementing, Postler2022demonstration, GoogleAI2023}. We can complete a universal set of logic gates by producing special resources called magic states~\cite{Bravyi2005universal,Maier2013magic, Chamberland2022building}. It is therefore important to produce high-fidelity magic states to conduct algorithms while introducing a minimal amount of noise to the computation. Here, we propose and implement a scheme to prepare a magic state on a superconducting qubit array using error correction. We find that our scheme produces better magic states than those we can prepare using the individual qubits of the device. This demonstrates a fundamental principle of fault-tolerant quantum computing~\cite{Shor96}, namely, that we can use error correction to improve the quality of logic gates with noisy qubits. Additionally, we show we can increase the yield of magic states using adaptive circuits, where circuit elements are changed depending on the outcome of mid-circuit measurements. This demonstrates an essential capability we will need for many error-correction subroutines. Our prototype will be invaluable in the future as it can reduce the number of physical qubits needed to produce high-fidelity magic states in large-scale quantum-computing architectures.
title Encoding a magic state with beyond break-even fidelity
topic Quantum Physics
url https://arxiv.org/abs/2305.13581