One-electron spectra and susceptibilities of the three-dimensional electron gas from self-consistent solutions of Hedin's equations

Kutepov, Andrey; Kotliar, Gabriel

doi:10.1103/physrevb.96.035108

Cited by 34 publications

(30 citation statements)

References 44 publications

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“…We want to point out that finite temperature calculations are very hard in the Diffusion Monte Carlo (DMC) 27 , while our method is very well suited for finite temperature calculations, and converges even faster with the increasing order. While wave function properties, such as energy and pair distribution function, are very precisely computed by DMC 27 , and some of them are also are amenable to approximations such as GW 28,29 , the response functions are more challenging to evaluate with the existing techniques. The strength of our approach is that it can be used to compute both the static and the dynamic, the single and the multiparticle correlation functions.…”

Section: Resultsmentioning

confidence: 99%

A combined variational and diagrammatic quantum Monte Carlo approach to the many-electron problem

Chen

Haule

2019

Nat Commun

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Two of the most influential ideas developed by Richard Feynman are the Feynman diagram technique and his variational approach. Here we show that combining both, and introducing a diagrammatic quantum Monte Carlo method, results in a powerful and accurate solver to the generic solid state problem, in which a macroscopic number of electrons interact by the long range Coulomb repulsion. We apply it to the quintessential problem of solid state, the uniform electron gas, which is at the heart of the density functional theory success in describing real materials, yet it has not been adequately solved for over 90 years. Our method allows us to calculate numerically exact momentum and frequency resolved spin and charge response functions. This method can be applied to a number of moderately interacting electron systems, including models of realistic metallic and semiconducting solids.

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Section: Resultsmentioning

confidence: 99%

A combined variational and diagrammatic quantum Monte Carlo approach to the many-electron problem

Chen

Haule

2019

Nat Commun

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“…[38]) and in scGW (scheme A) approximation as a function of r s (radius of the sphere containing one electron). The data have been taken from our work on the electron gas [39].…”

Section: Resultsmentioning

confidence: 99%

Ground state properties of 3d metals from self-consistent GW approach

Kutepov¹

2017

J. Phys.: Condens. Matter

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The self consistent GW approach (scGW) has been applied to calculate the ground state properties (equilibrium Wigner-Seitz radius S and bulk modulus B) of 3d transition metals Sc, Ti, V, Fe, Co, Ni, and Cu. The approach systematically underestimates S with average relative deviation from the experimental data of about 1% and it overestimates the calculated bulk modulus with relative error of about 25%. It is shown that scGW is superior in accuracy as compared to the local density approximation but it is less accurate than the generalized gradient approach for the materials studied. If compared to the random phase approximation, scGW is slightly less accurate, but its error for 3d metals looks more systematic. The systematic nature of the deviation from the experimental data suggests that the next order of the perturbation theory should allow one to reduce the error.

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“…The effect of the vertex function in Ref. [78] is rather small, therefore, it would be interesting if these calculations could be extended towards larger r s , where even variational and backflow reptation MC results are in disagreement.…”

Section: R S As a Control Parametermentioning

confidence: 99%

“…In their method, the self-energy is in the GW form, however, the screened interaction is replaced by the Kukkonen-Overhauser effective interaction [77]. Furthermore, a diagrammatic approach based on the Bethe-Salpeter equation for the improved screened interaction by Kutepov and Kotliar [78] is also used for comparison. Unfortunately, none of these theories are available for graphene systems.…”

Section: Quasiparticle Propertiesmentioning

confidence: 99%

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Dynamically screened vertex correction to GW

2020

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Diagrammatic perturbation theory is a powerful tool for the investigation of interacting many-body systems, the self-energy operator encoding all the variety of scattering processes. In the simplest scenario of correlated electrons described by the GW approximation for the electron self-energy, a particle transfers a part of its energy to neutral excitations. Higher-order (in screened Coulomb interaction W ) self-energy diagrams lead to improved electron spectral functions (SFs) by taking more complicated scattering channels into account and by adding corrections to lower order self-energy terms. However, they also may lead to unphysical negative spectral functions. The resolution of this difficulty has been demonstrated in our previous works. The main idea is to represent the self-energy operator in a Fermi golden rule form which leads to a manifestly positive definite SF and allows for a very efficient numerical algorithm. So far, the method has only been applied to the three-dimensional electron gas, which is a paradigmatic system, but a rather simple one. Here we systematically extend the method to two dimensions including realistic systems such as monolayer and bilayer graphene. We focus on one of the most important vertex function effects involving the exchange of two particles in the final state. We demonstrate that it should be evaluated with the proper screening and discuss its influence on the quasiparticle properties.

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One-electron spectra and susceptibilities of the three-dimensional electron gas from self-consistent solutions of Hedin's equations

Cited by 34 publications

References 44 publications

A combined variational and diagrammatic quantum Monte Carlo approach to the many-electron problem

A combined variational and diagrammatic quantum Monte Carlo approach to the many-electron problem

Ground state properties of 3d metals from self-consistent GW approach

Dynamically screened vertex correction to GW

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