Entanglement features of random neural network quantum states

ORAL

Abstract

Neural networks offer a novel approach to represent wave functions for solving quantum many-body problems. But what kinds of quantum states are efficiently represented by neural networks? In this talk, we will discuss entanglement properties of an ensemble of neural network states represented by random restricted Boltzmann machines. Phases with distinct entanglement features are identified and characterized. For certain parameters, we will show that these neural network states can look typical in their entanglement profile while still being distinguishable from a typical state by their fractal dimensions. The obtained phase diagrams may help inform the initialization of neural network ansatzes for future computational tasks.

*This work was supported by Gordon and Betty Moore Foundation's EPiQS Initiative through Grant GBMF8691 (XQS), the Air Force Office of Scientific Research through grant No. FA9550-16-1-0334 (MOF), National Science Foundation under Grant No. 2111998 (XLQ), the Simons Fundation (XLQ), and the DOE Office of Science, Office of High Energy Physics, under Grant No. DE-SC0019380 (XLQ).

Publication: X.-Q. Sun, T. Nebabu, X. Han, M. O. Flynn, X.-L. Qi, Phys. Rev. B 106, 115138 (2022)

Presenters

  • Xiao-Qi Sun

    • University of Illinois at Urbana-Champaign

Authors

  • Xiao-Qi Sun

    • University of Illinois at Urbana-Champaign

  • Tamra Nebabu

    • Stanford University

  • Xizhi Han

    • Stanford University & University of California, Santa Barbara

  • Michael Flynn

    • Boston University

  • Xiao-Liang Qi

    • Stanford University