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Autores principales: Bodendorfer, Norbert, Oktay, Onur, Gautam, Vaibhav, Hanada, Masanori, Rinaldi, Enrico
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2409.00398
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author Bodendorfer, Norbert
Oktay, Onur
Gautam, Vaibhav
Hanada, Masanori
Rinaldi, Enrico
author_facet Bodendorfer, Norbert
Oktay, Onur
Gautam, Vaibhav
Hanada, Masanori
Rinaldi, Enrico
contents We apply the variational Monte Carlo method based on neural network quantum states, using a neural autoregressive flow architecture as our ansatz, to determine the ground state wave function of the bosonic SU($N$) Yang-Mills-type two-matrix model at strong coupling. Previous literature hinted at the inaccuracy of such an approach at strong coupling. In this work, the accuracy of the results is tested using lattice Monte Carlo simulations: we benchmark the expectation value of the energy of the ground state for system sizes $N$ that are beyond brute-force exact diagonalization methods. We observe that the variational method with neural network states reproduces the right ground state energy when the width of the network employed in this work is sufficiently large. We confirm that the correct result is obtained for $N=2$ and $3$, while obtaining a precise value for $N=4$ requires more resources than the amount available for this work.
format Preprint
id arxiv_https___arxiv_org_abs_2409_00398
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Variational Monte Carlo with Neural Network Quantum States for Yang-Mills Matrix Model
Bodendorfer, Norbert
Oktay, Onur
Gautam, Vaibhav
Hanada, Masanori
Rinaldi, Enrico
High Energy Physics - Theory
We apply the variational Monte Carlo method based on neural network quantum states, using a neural autoregressive flow architecture as our ansatz, to determine the ground state wave function of the bosonic SU($N$) Yang-Mills-type two-matrix model at strong coupling. Previous literature hinted at the inaccuracy of such an approach at strong coupling. In this work, the accuracy of the results is tested using lattice Monte Carlo simulations: we benchmark the expectation value of the energy of the ground state for system sizes $N$ that are beyond brute-force exact diagonalization methods. We observe that the variational method with neural network states reproduces the right ground state energy when the width of the network employed in this work is sufficiently large. We confirm that the correct result is obtained for $N=2$ and $3$, while obtaining a precise value for $N=4$ requires more resources than the amount available for this work.
title Variational Monte Carlo with Neural Network Quantum States for Yang-Mills Matrix Model
topic High Energy Physics - Theory
url https://arxiv.org/abs/2409.00398