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Dual boson diagrammatic Monte Carlo approach applied to the extended Hubbard model

Matteo Vandelli, Viktor Harkov, E. A. Stepanov, Jan Gukelberger, Evgeny Kozik, Ángel Rubio, A. I. Lichtenstein

2020Physical review. B./Physical review. B44 citationsDOIOpen Access PDF

Abstract

In this work we introduce the dual boson diagrammatic Monte Carlo technique for strongly interacting electronic systems. This method combines the strength of dynamical mean-filed theory for nonperturbative description of local correlations with the systematic account of nonlocal corrections in the dual boson theory by the diagrammatic Monte Carlo approach. It allows us to get a numerically exact solution of the dual boson theory at the two-particle local vertex level for the extended Hubbard model. We show that it can be efficiently applied to description of single-particle observables in a wide range of interaction strengths. We compare our exact results for the self-energy with the ladder dual boson approach and determine a physical regime, where the description of collective electronic effects requires more accurate consideration beyond the ladder approximation. Additionally, we find that the order-by-order analysis of the perturbative diagrammatic series for the single-particle Green's function allows to estimate the transition point to the charge density wave phase.

Topics & Concepts

Diagrammatic reasoningHubbard modelMonte Carlo methodDual (grammatical number)Statistical physicsMonte Carlo method in statistical physicsBosonPhysicsMonte Carlo molecular modelingQuantum Monte CarloHybrid Monte CarloMarkov chain Monte CarloComputer scienceMathematicsQuantum mechanicsStatisticsSuperconductivityPhilosophyLinguisticsProgramming languagePhysics of Superconductivity and MagnetismAdvanced Condensed Matter PhysicsQuantum and electron transport phenomena