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Autori principali: Ge, Anxiang, Ritz, Nepomuk, Walter, Elias, Aguirre, Santiago, von Delft, Jan, Kugler, Fabian B.
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2307.10791
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author Ge, Anxiang
Ritz, Nepomuk
Walter, Elias
Aguirre, Santiago
von Delft, Jan
Kugler, Fabian B.
author_facet Ge, Anxiang
Ritz, Nepomuk
Walter, Elias
Aguirre, Santiago
von Delft, Jan
Kugler, Fabian B.
contents A major challenge in the field of correlated electrons is the computation of dynamical correlation functions. For comparisons with experiment, one is interested in their real-frequency dependence. This is difficult to compute, as imaginary-frequency data from the Matsubara formalism require analytic continuation, a numerically ill-posed problem. Here, we apply quantum field theory to the single-impurity Anderson model (AM), using the Keldysh instead of the Matsubara formalism with direct access to the self-energy and dynamical susceptibilities on the real-frequency axis. We present results from the functional renormalization group (fRG) at one-loop level and from solving the self-consistent parquet equations in the parquet approximation. In contrast to previous Keldysh fRG works, we employ a parametrization of the four-point vertex which captures its full dependence on three real-frequency arguments. We compare our results to benchmark data obtained with the numerical renormalization group and to second-order perturbation theory. We find that capturing the full frequency dependence of the four-point vertex significantly improves the fRG results compared to previous implementations, and that solving the parquet equations yields the best agreement with the NRG benchmark data, but is only feasible up to moderate interaction strengths. Our methodical advances pave the way for treating more complicated models in the future.
format Preprint
id arxiv_https___arxiv_org_abs_2307_10791
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Real-frequency quantum field theory applied to the single-impurity Anderson model
Ge, Anxiang
Ritz, Nepomuk
Walter, Elias
Aguirre, Santiago
von Delft, Jan
Kugler, Fabian B.
Strongly Correlated Electrons
A major challenge in the field of correlated electrons is the computation of dynamical correlation functions. For comparisons with experiment, one is interested in their real-frequency dependence. This is difficult to compute, as imaginary-frequency data from the Matsubara formalism require analytic continuation, a numerically ill-posed problem. Here, we apply quantum field theory to the single-impurity Anderson model (AM), using the Keldysh instead of the Matsubara formalism with direct access to the self-energy and dynamical susceptibilities on the real-frequency axis. We present results from the functional renormalization group (fRG) at one-loop level and from solving the self-consistent parquet equations in the parquet approximation. In contrast to previous Keldysh fRG works, we employ a parametrization of the four-point vertex which captures its full dependence on three real-frequency arguments. We compare our results to benchmark data obtained with the numerical renormalization group and to second-order perturbation theory. We find that capturing the full frequency dependence of the four-point vertex significantly improves the fRG results compared to previous implementations, and that solving the parquet equations yields the best agreement with the NRG benchmark data, but is only feasible up to moderate interaction strengths. Our methodical advances pave the way for treating more complicated models in the future.
title Real-frequency quantum field theory applied to the single-impurity Anderson model
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2307.10791