Topological order from measurements and feed-forward on a trapped ion quantum computer

Mohsin Iqbal; Nathanan Tantivasadakarn; Thomas M. Gatterman; Justin A. Gerber; Kevin Gilmore; Dan Gresh; Aaron Hankin; Nathan Hewitt; Chandler V. Horst; Mitchell Matheny; Tanner Mengle; Brian Neyenhuis; Ashvin Vishwanath; Michael Foss-Feig; Ruben Verresen; Henrik Dreyer

doi:10.1038/s42005-024-01698-3

Topological order from measurements and feed-forward on a trapped ion quantum computer

Mohsin Iqbal
, Nathanan Tantivasadakarn
, Thomas M. Gatterman
, Justin A. Gerber
, Kevin Gilmore
, Dan Gresh
, Aaron Hankin
, Nathan Hewitt
, Chandler V. Horst
, Mitchell Matheny
, Tanner Mengle
, Brian Neyenhuis
, Ashvin Vishwanath
, Michael Foss-Feig
, Ruben Verresen
, Henrik Dreyer

Institute for Theoretical Physics

Quantinuum GmbH
Quantinuum Research LLC
Harvard University

Research output: Contribution to journal › Article › peer-review

52 Scopus citations

Abstract

Quantum systems evolve in time in one of two ways: through the Schrödinger equation or wavefunction collapse. So far, deterministic control of quantum many-body systems in the lab has focused on the former, due to the probabilistic nature of measurements. This imposes serious limitations: preparing long-range entangled states, for example, requires extensive circuit depth if restricted to unitary dynamics. In this work, we use mid-circuit measurement and feed-forward to implement deterministic non-unitary dynamics on Quantinuum’s H1 programmable ion-trap quantum computer. Enabled by these capabilities, we demonstrate a constant-depth procedure for creating a toric code ground state in real-time. In addition to reaching high stabilizer fidelities, we create a non-Abelian defect whose presence is confirmed by transmuting anyons via braiding. This work clears the way towards creating complex topological orders in the lab and exploring deterministic non-unitary dynamics via measurement and feed-forward.

Original language	English
Article number	205
Journal	Communications Physics
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s42005-024-01698-3
State	Published - Dec 2024

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Iqbal, M., Tantivasadakarn, N., Gatterman, T. M., Gerber, J. A., Gilmore, K., Gresh, D., Hankin, A., Hewitt, N., Horst, C. V., Matheny, M., Mengle, T., Neyenhuis, B., Vishwanath, A., Foss-Feig, M., Verresen, R., & Dreyer, H. (2024). Topological order from measurements and feed-forward on a trapped ion quantum computer. Communications Physics, 7(1), Article 205. https://doi.org/10.1038/s42005-024-01698-3

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title = "Topological order from measurements and feed-forward on a trapped ion quantum computer",

abstract = "Quantum systems evolve in time in one of two ways: through the Schr{\"o}dinger equation or wavefunction collapse. So far, deterministic control of quantum many-body systems in the lab has focused on the former, due to the probabilistic nature of measurements. This imposes serious limitations: preparing long-range entangled states, for example, requires extensive circuit depth if restricted to unitary dynamics. In this work, we use mid-circuit measurement and feed-forward to implement deterministic non-unitary dynamics on Quantinuum{\textquoteright}s H1 programmable ion-trap quantum computer. Enabled by these capabilities, we demonstrate a constant-depth procedure for creating a toric code ground state in real-time. In addition to reaching high stabilizer fidelities, we create a non-Abelian defect whose presence is confirmed by transmuting anyons via braiding. This work clears the way towards creating complex topological orders in the lab and exploring deterministic non-unitary dynamics via measurement and feed-forward.",

author = "Mohsin Iqbal and Nathanan Tantivasadakarn and Gatterman, \{Thomas M.\} and Gerber, \{Justin A.\} and Kevin Gilmore and Dan Gresh and Aaron Hankin and Nathan Hewitt and Horst, \{Chandler V.\} and Mitchell Matheny and Tanner Mengle and Brian Neyenhuis and Ashvin Vishwanath and Michael Foss-Feig and Ruben Verresen and Henrik Dreyer",

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Iqbal, M, Tantivasadakarn, N, Gatterman, TM, Gerber, JA, Gilmore, K, Gresh, D, Hankin, A, Hewitt, N, Horst, CV, Matheny, M, Mengle, T, Neyenhuis, B, Vishwanath, A, Foss-Feig, M, Verresen, R & Dreyer, H 2024, 'Topological order from measurements and feed-forward on a trapped ion quantum computer', Communications Physics, vol. 7, no. 1, 205. https://doi.org/10.1038/s42005-024-01698-3

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AU - Iqbal, Mohsin

AU - Tantivasadakarn, Nathanan

AU - Gatterman, Thomas M.

AU - Gerber, Justin A.

AU - Gilmore, Kevin

AU - Gresh, Dan

AU - Hankin, Aaron

AU - Hewitt, Nathan

AU - Horst, Chandler V.

AU - Matheny, Mitchell

AU - Mengle, Tanner

AU - Neyenhuis, Brian

AU - Vishwanath, Ashvin

AU - Foss-Feig, Michael

AU - Verresen, Ruben

AU - Dreyer, Henrik

PY - 2024/12

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N2 - Quantum systems evolve in time in one of two ways: through the Schrödinger equation or wavefunction collapse. So far, deterministic control of quantum many-body systems in the lab has focused on the former, due to the probabilistic nature of measurements. This imposes serious limitations: preparing long-range entangled states, for example, requires extensive circuit depth if restricted to unitary dynamics. In this work, we use mid-circuit measurement and feed-forward to implement deterministic non-unitary dynamics on Quantinuum’s H1 programmable ion-trap quantum computer. Enabled by these capabilities, we demonstrate a constant-depth procedure for creating a toric code ground state in real-time. In addition to reaching high stabilizer fidelities, we create a non-Abelian defect whose presence is confirmed by transmuting anyons via braiding. This work clears the way towards creating complex topological orders in the lab and exploring deterministic non-unitary dynamics via measurement and feed-forward.

AB - Quantum systems evolve in time in one of two ways: through the Schrödinger equation or wavefunction collapse. So far, deterministic control of quantum many-body systems in the lab has focused on the former, due to the probabilistic nature of measurements. This imposes serious limitations: preparing long-range entangled states, for example, requires extensive circuit depth if restricted to unitary dynamics. In this work, we use mid-circuit measurement and feed-forward to implement deterministic non-unitary dynamics on Quantinuum’s H1 programmable ion-trap quantum computer. Enabled by these capabilities, we demonstrate a constant-depth procedure for creating a toric code ground state in real-time. In addition to reaching high stabilizer fidelities, we create a non-Abelian defect whose presence is confirmed by transmuting anyons via braiding. This work clears the way towards creating complex topological orders in the lab and exploring deterministic non-unitary dynamics via measurement and feed-forward.

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Topological order from measurements and feed-forward on a trapped ion quantum computer

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