Spontaneous symmetry breaking in a SO(3) non-Abelian lattice gauge theory in 2+1D with quantum algorithms
Spontaneous symmetry breaking in a SO(3) non-Abelian lattice gauge theory in 2+1D with quantum algorithms
The simulation of various properties of quantum field theories is rapidly becoming a testing ground for demonstrating the prowess of quantum algorithms. Some examples include the preparation of ground states, as well as the investigation of various simple wave packets relevant for scattering phenomena. In this work, we study the ability of quantum algorithms to prepare ground states in a matter-free non-Abelian SO(3) lattice gauge theory in 2+1D in a phase where the global charge conjugation symmetry is spontaneously broken. This is challenging for two reasons: the necessity of dealing with a large Hilbert space for gauge theories compared to that of quantum spin models, and the closing of the gap between the two ground states which becomes exponentially small as a function of the volume. To deal with the large Hilbert space of gauge fields, we demonstrate how the exact imposition of the non-Abelian Gauss Law in the rishon representation of the quantum link operator significantly reduces the degrees of freedom. Further, to resolve the gap, we introduce symmetry-guided ansätze in the Gauss-Law-resolved basis for trial states as the starting point for the quantum algorithms to prepare the two lowest energy states. In addition to simulation results for a range of two-dimensional system sizes, we also provide experimental results from the trapped-ion-based quantum hardware, IonQ, when working on systems with four quantum links. The experimental/simulation results derived from our theoretical developments indicate the role of metrics--such as the energy and the infidelity--to assess the obtained results.
hep-lat, cond-mat.str-el, quant-ph
Maiti, Sandip
95f7691a-9956-4e68-8fe3-81d5ed4fa474
Banerjee, Debasish
f307cc20-b852-4105-9e07-33a8c44e913e
Chakraborty, Bipasha
7bc388c0-e36c-47a7-b5f2-a27839178e48
Huffman, Emilie
651edff6-13d7-4205-90f6-40342ccdaf6a
Maiti, Sandip
95f7691a-9956-4e68-8fe3-81d5ed4fa474
Banerjee, Debasish
f307cc20-b852-4105-9e07-33a8c44e913e
Chakraborty, Bipasha
7bc388c0-e36c-47a7-b5f2-a27839178e48
Huffman, Emilie
651edff6-13d7-4205-90f6-40342ccdaf6a
[Unknown type: UNSPECIFIED]
Abstract
The simulation of various properties of quantum field theories is rapidly becoming a testing ground for demonstrating the prowess of quantum algorithms. Some examples include the preparation of ground states, as well as the investigation of various simple wave packets relevant for scattering phenomena. In this work, we study the ability of quantum algorithms to prepare ground states in a matter-free non-Abelian SO(3) lattice gauge theory in 2+1D in a phase where the global charge conjugation symmetry is spontaneously broken. This is challenging for two reasons: the necessity of dealing with a large Hilbert space for gauge theories compared to that of quantum spin models, and the closing of the gap between the two ground states which becomes exponentially small as a function of the volume. To deal with the large Hilbert space of gauge fields, we demonstrate how the exact imposition of the non-Abelian Gauss Law in the rishon representation of the quantum link operator significantly reduces the degrees of freedom. Further, to resolve the gap, we introduce symmetry-guided ansätze in the Gauss-Law-resolved basis for trial states as the starting point for the quantum algorithms to prepare the two lowest energy states. In addition to simulation results for a range of two-dimensional system sizes, we also provide experimental results from the trapped-ion-based quantum hardware, IonQ, when working on systems with four quantum links. The experimental/simulation results derived from our theoretical developments indicate the role of metrics--such as the energy and the infidelity--to assess the obtained results.
Text
2409.07108v1
- Author's Original
More information
Accepted/In Press date: 11 September 2024
Additional Information:
21 pages, 5 appendices, 17 figures
Keywords:
hep-lat, cond-mat.str-el, quant-ph
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Local EPrints ID: 496258
URI: http://eprints.soton.ac.uk/id/eprint/496258
PURE UUID: 8a07a517-219a-4e5a-90c0-28b4c390a9b1
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Date deposited: 10 Dec 2024 17:42
Last modified: 10 Dec 2024 17:42
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Author:
Sandip Maiti
Author:
Debasish Banerjee
Author:
Emilie Huffman
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