English

Continuous-time Quantum Monte Carlo using Worm Sampling

Strongly Correlated Electrons 2015-10-07 v2
Authors: Patrik Gunacker , Markus Wallerberger , Emanuel Gull , Andreas Hausoel , Giorgio Sangiovanni , Karsten Held
View on arXiv PDF DOI

Abstract

We present a worm sampling method for calculating one- and two-particle Green's functions using continuous-time quantum Monte Carlo simulations in the hybridization expansion (CT-HYB). Instead of measuring Green's functions by removing hybridization lines from partition function configurations, as in conventional CT-HYB, the worm algorithm directly samples the Green's function. We show that worm sampling is necessary to obtain general two-particle Green's functions which are not of density-density type and that it improves the sampling efficiency when approaching the atomic limit. Such two-particle Green's functions are needed to compute off-diagonal elements of susceptibilities and occur in diagrammatic extensions of the dynamical mean field theory and efficient estimators for the single-particle self-energy.

Keywords

quantum monte carlo monte carlo algorithms monte carlo simulation

Cite

@article{arxiv.1506.01905,
  title  = {Continuous-time Quantum Monte Carlo using Worm Sampling},
  author = {Patrik Gunacker and Markus Wallerberger and Emanuel Gull and Andreas Hausoel and Giorgio Sangiovanni and Karsten Held},
  journal= {arXiv preprint arXiv:1506.01905},
  year   = {2015}
}

Comments

12 pages, 11 figures

Related papers

View all related →
Strongly Correlated Electrons · Physics
Improved Green's Function Measurement for Hybridization Expansion Quantum Monte Carlo
Pavel Augustinský, Jan Kuneš
2013-06-17
Strongly Correlated Electrons · Physics
Efficient treatment of the high-frequency tail of the self-energy function and its relevance for multi-orbital models
Gang Li, Werner Hanke
2012-03-07
Statistical Mechanics · Physics
Quantum Monte Carlo simulation in the canonical ensemble at finite temperature
Kris Van Houcke, Stefan Rombouts, Lode Pollet
2009-11-11
Strongly Correlated Electrons · Physics
Worm Improved Estimators in Continuous-time Quantum Monte Carlo
Patrik Gunacker, Markus Wallerberger, Tin Ribic, Andreas Hausoel +2
2016-10-07
Computational Physics · Physics
Worm Algorithm and Diagrammatic Monte Carlo: A New Approach to Continuous-Space Path Integral Monte Carlo Simulations
M. Boninsegni, N. V. Prokof'ev, B. V. Svistunov
2009-11-11
Statistical Mechanics · Physics
Worm Algorithm for Continuous-space Path Integral Monte Carlo Simulations
M. Boninsegni, N. Prokof'ev, B. Svistunov
2009-11-11
Strongly Correlated Electrons · Physics
Symmetric Improved Estimators for Continuous-time Quantum Monte Carlo
Josef Kaufmann, Patrik Gunacker, Alexander Kowalski, Giorgio Sangiovanni +1
2019-08-14
Strongly Correlated Electrons · Physics
State- and superstate-sampling in hybridization-expansion continuous-time quantum Monte Carlo
Alexander Kowalski, Andreas Hausoel, Markus Wallerberger, Patrik Gunacker +1
2019-04-30
Strongly Correlated Electrons · Physics
Continuous-time quantum Monte Carlo calculation of multi-orbital vertex asymptotics
Josef Kaufmann, Patrik Gunacker, Karsten Held
2017-07-12
Statistical Mechanics · Physics
Efficient and scalable Path Integral Monte Carlo Simulations with worm-type updates for Bose-Hubbard and XXZ models
Nicolas Sadoune, Lode Pollet
2022-10-03
Strongly Correlated Electrons · Physics
Aberration of the Green's function estimator in hybridization expansion continuous-time quantum Monte Carlo
Andreas Hausoel, Markus Wallerberger, Josef Kaufmann, Karsten Held +1
2022-11-14
Strongly Correlated Electrons · Physics
Quantum spin chains in a magnetic field
V. A. Kashurnikov, N. V. Prokof'ev, B. V. Svistunov, M. Troyer
2007-05-23
Strongly Correlated Electrons · Physics
Hybridization expansion Monte Carlo simulation of multi-orbital quantum impurity problems: matrix product formalism and improved Monte Carlo sampling
Hiroshi Shinaoka, Michele Dolfi, Matthias Troyer, Philipp Werner
2014-07-01
Computational Physics · Physics
Improved efficiency with variational Monte Carlo using two level sampling
Mark Dewing
2016-09-08
Strongly Correlated Electrons · Physics
Exact real-time dynamics of single-impurity Anderson model from a single-spin hybridization-expansion
Patryk Kubiczek, Alexey N. Rubtsov, Alexander I. Lichtenstein
2019-08-07
Quantum Physics · Physics
Monte Carlo sampling from the quantum state space. II
Yi-Lin Seah, Jiangwei Shang, Hui Khoon Ng, David John Nott +1
2015-04-28
Strongly Correlated Electrons · Physics
Accelerated Continuous time quantum Monte Carlo method with Machine Learning
Taegeun Song, Hunpyo Lee
2019-08-07
Condensed Matter · Physics
Bilinear Quantum Monte Carlo: Expectations and Energy Differences
Shiwei Zhang, M. H. Kalos
2010-01-12
Numerical Analysis · Mathematics
Efficient methods for the estimation of homogenized coefficients
Jean-Christophe Mourrat
2017-11-01
Quantum Physics · Physics
From quantum-enhanced to quantum-inspired Monte Carlo
Johannes Christmann, Petr Ivashkov, Mattia Chiurco, Guglielmo Mazzola
2025-07-01
Quantum Physics · Physics
Computation of Green's function by local variational quantum compilation
Shota Kanasugi, Shoichiro Tsutsui, Yuya O. Nakagawa, Kazunori Maruyama +2
2023-08-03
Strongly Correlated Electrons · Physics
Quantum Monte Carlo Study of Strongly Correlated Electrons: Cellular Dynamical Mean-Field Theory
B. Kyung, G. Kotliar, A. -M. S. Tremblay
2009-11-11
Condensed Matter · Physics
Real-Time Dynamics from Imaginary-Time Quantum Monte Carlo Simulations: Tests on Oscillator Chains
J. Bonca, J. E. Gubernatis
2009-10-28
Strongly Correlated Electrons · Physics
Improved Estimators for the Self-Energy and Vertex Function in Hybridization Expansion Continuous-Time Quantum Monte Carlo Simulations
Hartmut Hafermann, Kelly R. Patton, Philipp Werner
2012-06-01
Statistical Mechanics · Physics
Engineering Local optimality in Quantum Monte Carlo algorithms
Lode Pollet, Kris Van Houcke, Stefan M. A. Rombouts
2007-07-28
R2 v1 2026-06-22T09:47:57.037Z