Comparative Study of State-of-the-Art Matrix-Product-State Methods for Lattice Models with Large Local Hilbert Spaces without U(1) symmetry

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Jan Stolpp
  • Thomas Köhler
  • Salvatore R. Manmana
  • Eric Jeckelmann
  • Fabian Heidrich-Meisner
  • Sebastian Paeckel

Research Organisations

External Research Organisations

  • University of Göttingen
  • Uppsala University
  • Ludwig-Maximilians-Universität München (LMU)
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Details

Original languageEnglish
Article number108106
JournalComputer physics communications
Volume269
Early online date24 Jul 2021
Publication statusPublished - Dec 2021

Abstract

Lattice models consisting of high-dimensional local degrees of freedom without global particle-number conservation constitute an important problem class in the field of strongly correlated quantum many-body systems. For instance, they are realized in electron-phonon models, cavities, atom-molecule resonance models, or superconductors. In general, these systems elude a complete analytical treatment and need to be studied using numerical methods where matrix-product states (MPSs) provide a flexible and generic ansatz class. Typically, MPS algorithms scale at least quadratic in the dimension of the local Hilbert spaces. Hence, tailored methods, which truncate this dimension, are required to allow for efficient simulations. Here, we describe and compare three state-of-the-art MPS methods each of which exploits a different approach to tackle the computational complexity. We analyze the properties of these methods for the example of the Holstein model, performing high-precision calculations as well as a finite-size-scaling analysis of relevant ground-state observables. The calculations are performed at different points in the phase diagram yielding a comprehensive picture of the different approaches.

Keywords

    DMRG, Lattice phonons, MPS, Quantum lattice models, Quantum physics

ASJC Scopus subject areas

Cite this

Comparative Study of State-of-the-Art Matrix-Product-State Methods for Lattice Models with Large Local Hilbert Spaces without U(1) symmetry. / Stolpp, Jan; Köhler, Thomas; Manmana, Salvatore R. et al.
In: Computer physics communications, Vol. 269, 108106, 12.2021.

Research output: Contribution to journalArticleResearchpeer review

Stolpp J, Köhler T, Manmana SR, Jeckelmann E, Heidrich-Meisner F, Paeckel S. Comparative Study of State-of-the-Art Matrix-Product-State Methods for Lattice Models with Large Local Hilbert Spaces without U(1) symmetry. Computer physics communications. 2021 Dec;269:108106. Epub 2021 Jul 24. doi: 10.1016/j.cpc.2021.108106
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title = "Comparative Study of State-of-the-Art Matrix-Product-State Methods for Lattice Models with Large Local Hilbert Spaces without U(1) symmetry",
abstract = "Lattice models consisting of high-dimensional local degrees of freedom without global particle-number conservation constitute an important problem class in the field of strongly correlated quantum many-body systems. For instance, they are realized in electron-phonon models, cavities, atom-molecule resonance models, or superconductors. In general, these systems elude a complete analytical treatment and need to be studied using numerical methods where matrix-product states (MPSs) provide a flexible and generic ansatz class. Typically, MPS algorithms scale at least quadratic in the dimension of the local Hilbert spaces. Hence, tailored methods, which truncate this dimension, are required to allow for efficient simulations. Here, we describe and compare three state-of-the-art MPS methods each of which exploits a different approach to tackle the computational complexity. We analyze the properties of these methods for the example of the Holstein model, performing high-precision calculations as well as a finite-size-scaling analysis of relevant ground-state observables. The calculations are performed at different points in the phase diagram yielding a comprehensive picture of the different approaches.",
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