Irreducible Green functions method and many-particle interacting systems on a lattice

We propose a new way of analyzing the Hubbard model using equations of motion (EOM) for the higher-order Green's functions approach within the DMFT scheme. In calculating the higher order Green function we will differentiate over both times ( t ) and ( ' t ). This allows us to obtain the metallic Fermi liquid at nonzero Coulomb interaction, where the three center DOS structure with two Hubbard bands and the quasiparticle resonance peak is obtained. At small Coulomb interactions and zero temperature the height of the quasiparticle resonance peak on the Fermi energy is constant similarly as in the full DMFT method with numerical (Quantum Monte Carlo) or with analytical (e.g. iterative perturbation theory) calculations.

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“…Instead of eq. ( 6) we will use the method with differentiating over the second time ( ' t ), which gives the EOM in the following form [34]:…”

Section: The Modelmentioning

confidence: 99%

Equation of motion solutions to Hubbard model retaining Kondo effect

Górski

Mizia

2013

Physica B: Condensed Matter

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“…At the same time for the real two-time Green function (19) the representation (26) may be proved analytically within the approach suggested and developed by N. M. Plakida and Yu. A. Tserkovnikov [19,20,21,22]. Moreover as it is shown in the paper an evaluation of Σ 1 (ω, q, T ) in this framework is rather simple and does not need a preliminary knowledge of χ 1 (ω, q, T ) (so that the resummation does not occur).…”

Section: Introductionmentioning

confidence: 80%

Low-temperature asymptotic of the transverse dynamical structure factor for a magnetically polarized XX chain

Bibikov

2020

Preprint

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Dyson equation for the real two-time commutator retarded one-magnon Green function of the ferromagnetically polarized XX chain is suggested following the Plakida-Tserkovnikov algorithm. Starting from this result a low-temperature integral representation for the corresponding magnon self energy is obtained by the truncated form factor expansion however without any resummations. Within the suggested approach the low-temperature asymptotics of the transverse dynamical structure factor may be readily studied. Some obtained line shapes are presented.

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“…Moreover, the mean-field sign there alternates in the "chessboard" (staggered) order. The question of the true antiferromagnetic ground state is not completely clarified up to the present time [17,5,71,72,35,36,37]. This is related to the fact that, in contrast to ferromagnets, which have a unique ground state, antiferromagnets can have several different optimal states with the lowest energy.…”

Section: The Mean Field Conceptmentioning

confidence: 97%

“…We see that the mean-field approximation provides only a rough description of the real situation and overestimates the interaction between particles. Attempts to improve the homogeneous mean-field approximation were undertaken along different directions [17,5,71,72,35,36,37]. An extremely successful and quite nontrivial approach was developed by L. Neel [17,5,71,72], who essentially formulated the concept of local mean fields (1932).…”

Section: The Mean Field Conceptmentioning

confidence: 99%

“…The considerable progress in studying the spectra of elementary excitations and thermodynamic properties of many-body systems has been for the most part due to the development of the temperature-dependent Green functions methods [15,5,17,18]. The very important concept of the whole method is the concept of the generalized mean field [17,35,36,37]. These generalized mean fields have a complicated structure for the strongly correlated case and are not reduced to the functional of the mean densities of the electrons.…”

Section: Introductionmentioning

confidence: 99%

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Variational principle of Bogoliubov and generalized mean fields in many-particle interacting systems

Kuzemsky

2015

Int. J. Mod. Phys. B

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The approach to the theory of many-particle interacting systems from a unified standpoint, based on the variational principle for free energy is reviewed. A systematic discussion is given of the approximate free energies of complex statistical systems. The analysis is centered around the variational principle of Bogoliubov for free energy in the context of its applications to various problems of statistical mechanics. The review presents a terse discussion of selected works carried out over the past few decades on the theory of many-particle interacting systems in terms of the variational inequalities. It is the purpose of this paper to discuss some of the general principles which form the mathematical background to this approach and to establish a connection of the variational technique with other methods, such as the method of the mean (or self-consistent) field in the many-body problem. The method is illustrated by applying it to various systems of many-particle interacting systems, such as Ising, Heisenberg and Hubbard models, superconducting (SC) and superfluid systems, etc. This work proposes a new, general and pedagogical presentation, intended both for those who are interested in basic aspects and for those who are interested in concrete applications. particle interacting systems; the variational principle of Bogoliubov; Bogoliubov inequality; generalized mean fields; model Hamiltonians of many-particle interacting systems. PACS numbers: 05.30-d, 05.30.Fk, 05.30.Jp, 05.70.-a, 05.70.Fh, 02.90.+p 1530010-1 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by RUTGERS UNIVERSITY on 08/24/15. For personal use only. 1530010-2 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by RUTGERS UNIVERSITY on 08/24/15. For personal use only. 1530010-5 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by RUTGERS UNIVERSITY on 08/24/15. For personal use only. 1530010-8 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by RUTGERS UNIVERSITY on 08/24/15. For personal use only. 1530010-9 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by RUTGERS UNIVERSITY on 08/24/15. For personal use only.

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Irreducible Green functions method and many-particle interacting systems on a lattice

Cited by 36 publications

References 88 publications

Equation of motion solutions to Hubbard model retaining Kondo effect

Equation of motion solutions to Hubbard model retaining Kondo effect

Low-temperature asymptotic of the transverse dynamical structure factor for a magnetically polarized XX chain

Variational principle of Bogoliubov and generalized mean fields in many-particle interacting systems

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