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Auteurs principaux: Hul, Anton, Medvidović, Matija, Carrasquilla, Juan
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.07779
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author Hul, Anton
Medvidović, Matija
Carrasquilla, Juan
author_facet Hul, Anton
Medvidović, Matija
Carrasquilla, Juan
contents Variational Monte Carlo calculations have recently reached state-of-the-art accuracy in the approximation of ground state properties of quantum many-body systems. Making use of flexible neural quantum states and automatic differentiation has bypassed traditional computational obstacles such as reliance on basis sets. In this paper, we propose a neural quantum state architecture capable of representing symmetric bosonic wavefunctions in Fock space, enabling the study of systems with variable particle number. By supplementing our variational state with Monte Carlo sampling and geometric optimization, we demonstrate competitive variational energies across an array of one- and two-dimensional systems, converging to the physical boson number under a set chemical potential. Our approach enables accurate estimates of one-body reduced density matrices, opening access to observables such as condensate fractions and radial density profiles from first principles. Our method opens the door to numerical predictions of key measurable quantities in practical grand canonical systems.
format Preprint
id arxiv_https___arxiv_org_abs_2605_07779
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Neural network quantum states in the grand canonical ensemble
Hul, Anton
Medvidović, Matija
Carrasquilla, Juan
Quantum Physics
Variational Monte Carlo calculations have recently reached state-of-the-art accuracy in the approximation of ground state properties of quantum many-body systems. Making use of flexible neural quantum states and automatic differentiation has bypassed traditional computational obstacles such as reliance on basis sets. In this paper, we propose a neural quantum state architecture capable of representing symmetric bosonic wavefunctions in Fock space, enabling the study of systems with variable particle number. By supplementing our variational state with Monte Carlo sampling and geometric optimization, we demonstrate competitive variational energies across an array of one- and two-dimensional systems, converging to the physical boson number under a set chemical potential. Our approach enables accurate estimates of one-body reduced density matrices, opening access to observables such as condensate fractions and radial density profiles from first principles. Our method opens the door to numerical predictions of key measurable quantities in practical grand canonical systems.
title Neural network quantum states in the grand canonical ensemble
topic Quantum Physics
url https://arxiv.org/abs/2605.07779