Abstract
AbstractThe energy gap of correlated Hubbard clusters is well studied for one‐dimensional systems using analytical methods and density‐matrix‐renormalization‐group (DMRG) simulations. Beyond 1D, however, exact results are available only for small systems by quantum Monte Carlo. For this reason and, due to the problems of DMRG in simulating 2D and 3D systems, alternative methods such as Green functions combined with many‐body approximations (GFMBA), that do not have this restriction, are highly important. However, it has remained open whether the approximate character of GFMBA simulations prevents the computation of the Hubbard gap. Here we present new GFMBA results that demonstrate that GFMBA simulations are capable of producing reliable data for the gap which agrees well with the DMRG benchmarks in 1D. An interesting observation is that the accuracy of the gap can be significantly increased when the simulations give up certain symmetry restriction of the exact system, such as spin symmetry and spatial homogeneity. This is seen as manifestation and generalization of the “symmetry dilemma” introduced by Löwdin for Hartree–Fock wave function calculations.
Highlights
Symmetry and its possible violation or breaking are basic notions in our understanding of physical phenomena
After analysing the general properties of Green functions combined with many-body approximations (GFMBA) simulations with HF and second-order Born approximation (SOA) selfenergies for the three methods (I)–(III), we focus on their performance regarding the Hubbard gap, Equation (1), in particular
To further assess the quality of the correlation gap but the total density of states (DOS), in Figure 5 we compare the results of the rsSOA and usSOA methods to the spectral function obtained by Nocera et al.[87] using the time-dependent DMRG method for an open Hubbard chain of 40 sites for U = 4 J
Summary
Symmetry and its possible violation or breaking are basic notions in our understanding of physical phenomena. For Hartree–Fock treatments of the Hubbard model, it is well known that a phase transition from a paramagnetic ground state to an antiferromagnetic one of unphysical nature occurs at a critical interaction, Uc, where the specific value depends on the system size and geometry.[47,74] Yet, at the same time, the (unphysical) broken spin-symmetry solutions result in a ground-state energy closer to the exact one, as well as in the emergence of a band gap (the latter is absent within spin-symmetric/spin-restricted mean-field schemes).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
