English

Autoencoder-based analytic continuation method for strongly correlated quantum systems

Strongly Correlated Electrons 2024-10-01 v1 Disordered Systems and Neural Networks Computational Physics

Abstract

The single particle Green's function provides valuable information on the momentum and energy-resolved spectral properties for a strongly correlated system. In large-scale numerical calculations using quantum Monte Carlo (QMC), dynamical mean field theory (DMFT), including cluster-DMFT, one usually obtains the Green's function in imaginary-time G(τ)G(\tau). The process of inverting a Laplace transform to obtain the spectral function A(ω)A(\omega) in real-frequency is an ill-posed problem and forms the core of the analytic continuation problem. In this Letter, we propose to use a completely unsupervised autoencoder-type neural network to solve the analytic continuation problem. We introduce an encoder-decoder approach that, together with only minor physical assumptions, can extract a high-quality frequency response from the imaginary time domain. With a deeply tunable architecture, this method can, in principle, locate sharp features of spectral functions that might normally be lost using already well-established methods, such as maximum entropy (MaxEnt) methods. We demonstrate the strength of the autoencoder approach by applying it to QMC results of G(τ)G(\tau) for a single-band Hubbard model. The proposed method is general and can also be applied to other ill-posed inverse problems.

Keywords

Cite

@article{arxiv.2311.17920,
  title  = {Autoencoder-based analytic continuation method for strongly correlated quantum systems},
  author = {Maksymilian Kliczkowski and Lauren Keyes and Sayantan Roy and Thereza Paiva and Mohit Randeria and Nandini Trivedi and Maciej M. Maska},
  journal= {arXiv preprint arXiv:2311.17920},
  year   = {2024}
}

Comments

7 pages, 5 figures, supplement

R2 v1 2026-06-28T13:35:51.681Z