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Preparing ground states for quantum computation of gauge theories

Preparing ground states for quantum computation of gauge theories
Preparing ground states for quantum computation of gauge theories
Simulation of adiabatic methods on a quantum computer has been successfully used to prepare ground states of gauge theories. However, this process requires a high number of quantum gates, which is inaccessible in the NISQ era. An alternative approach is to use variational methods, which utilise a hybrid of classical and quantum computation. We show how a particular example, the Quantum Approximate Optimisation Algorithm (QAOA), can be used to prepare ground states of the Schwinger Model, with an improved circuit depth compared to the adiabatic approximation that targets current devices. In addition, we discuss how, in principle, Permutational Quantum Computing can give us better optimisation beyond the NISQ era.
Tomlinson, Alexander
57e4550c-844f-4719-8c2d-93e477dc4070
Chakraborty, Bipasha
7bc388c0-e36c-47a7-b5f2-a27839178e48
Acharya, Tejas
4146621b-0432-4e1c-ba72-70f5a4ec075f
Tomlinson, Alexander
57e4550c-844f-4719-8c2d-93e477dc4070
Chakraborty, Bipasha
7bc388c0-e36c-47a7-b5f2-a27839178e48
Acharya, Tejas
4146621b-0432-4e1c-ba72-70f5a4ec075f

Tomlinson, Alexander, Chakraborty, Bipasha and Acharya, Tejas (2025) Preparing ground states for quantum computation of gauge theories. In The 41st International Symposium on Lattice Field Theory (LATTICE2024). vol. 466, 7 pp . (doi:10.22323/1.466.0471).

Record type: Conference or Workshop Item (Paper)

Abstract

Simulation of adiabatic methods on a quantum computer has been successfully used to prepare ground states of gauge theories. However, this process requires a high number of quantum gates, which is inaccessible in the NISQ era. An alternative approach is to use variational methods, which utilise a hybrid of classical and quantum computation. We show how a particular example, the Quantum Approximate Optimisation Algorithm (QAOA), can be used to prepare ground states of the Schwinger Model, with an improved circuit depth compared to the adiabatic approximation that targets current devices. In addition, we discuss how, in principle, Permutational Quantum Computing can give us better optimisation beyond the NISQ era.

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e-pub ahead of print date: 1 February 2025
Venue - Dates: The 41st International Symposium on Lattice Field Theory, , Liverpool, United Kingdom, 2024-07-28
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Identifiers

Local EPrints ID: 501136
URI: http://eprints.soton.ac.uk/id/eprint/501136
DOI: doi:10.22323/1.466.0471
PURE UUID: 5c373998-2175-47e9-86c5-22db25a44ebc

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Date deposited: 27 May 2025 16:42
Last modified: 21 Aug 2025 04:56

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Contributors

Author: Alexander Tomlinson
Author: Bipasha Chakraborty
Author: Tejas Acharya

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