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Discovering Quantum Phase Transitions with Fermionic Neural Networks

Computational Physics 2023-02-01 v3 Other Condensed Matter Strongly Correlated Electrons Machine Learning

Abstract

Deep neural networks have been extremely successful as highly accurate wave function ans\"atze for variational Monte Carlo calculations of molecular ground states. We present an extension of one such ansatz, FermiNet, to calculations of the ground states of periodic Hamiltonians, and study the homogeneous electron gas. FermiNet calculations of the ground-state energies of small electron gas systems are in excellent agreement with previous initiator full configuration interaction quantum Monte Carlo and diffusion Monte Carlo calculations. We investigate the spin-polarized homogeneous electron gas and demonstrate that the same neural network architecture is capable of accurately representing both the delocalized Fermi liquid state and the localized Wigner crystal state. The network is given no \emph{a priori} knowledge that a phase transition exists, but converges on the translationally invariant ground state at high density and spontaneously breaks the symmetry to produce the crystalline ground state at low density.

Keywords

Cite

@article{arxiv.2202.05183,
  title  = {Discovering Quantum Phase Transitions with Fermionic Neural Networks},
  author = {G. Cassella and H. Sutterud and S. Azadi and N. D. Drummond and D. Pfau and J. S. Spencer and W. M. C. Foulkes},
  journal= {arXiv preprint arXiv:2202.05183},
  year   = {2023}
}

Comments

12 pages, 3 figures

R2 v1 2026-06-24T09:30:38.607Z