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Auteurs principaux: Linteau, David, Moroni, Saverio, Carleo, Giuseppe, Holzmann, Markus
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2504.07062
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author Linteau, David
Moroni, Saverio
Carleo, Giuseppe
Holzmann, Markus
author_facet Linteau, David
Moroni, Saverio
Carleo, Giuseppe
Holzmann, Markus
contents We leverage the power of neural quantum states to describe the ground state wave function of solid and liquid atomic hydrogen, including both electronic and protonic degrees of freedom. For static protons, the resulting Born-Oppenheimer energies are consistently comparable to or lower than all previous projector Monte Carlo results for systems containing up to $128$ hydrogen atoms. The same level of accuracy is preserved upon inclusion of nuclear quantum effects, thus going beyond the Born-Oppenheimer approximation. In addition, our description overcomes major limitations of current wave functions, notably by avoiding any explicit symmetry assumption on the expected quantum crystal, and sidestepping efficiency issues of imaginary time evolution with disparate mass scales. As a first application, we examine crystal formation in an extremely high-density region up to pressure-induced melting.
format Preprint
id arxiv_https___arxiv_org_abs_2504_07062
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Neural Wave Functions for High-Pressure Atomic Hydrogen
Linteau, David
Moroni, Saverio
Carleo, Giuseppe
Holzmann, Markus
Strongly Correlated Electrons
We leverage the power of neural quantum states to describe the ground state wave function of solid and liquid atomic hydrogen, including both electronic and protonic degrees of freedom. For static protons, the resulting Born-Oppenheimer energies are consistently comparable to or lower than all previous projector Monte Carlo results for systems containing up to $128$ hydrogen atoms. The same level of accuracy is preserved upon inclusion of nuclear quantum effects, thus going beyond the Born-Oppenheimer approximation. In addition, our description overcomes major limitations of current wave functions, notably by avoiding any explicit symmetry assumption on the expected quantum crystal, and sidestepping efficiency issues of imaginary time evolution with disparate mass scales. As a first application, we examine crystal formation in an extremely high-density region up to pressure-induced melting.
title Neural Wave Functions for High-Pressure Atomic Hydrogen
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2504.07062