Non-separable frequency dependence of two-particle vertex in interacting fermion systems

TL;DR

This paper develops flow equations capturing the full frequency dependence of two-particle vertices in interacting fermion systems, revealing complex fluctuation behaviors and stabilizing the Fermi liquid state.

Contribution

It introduces a method to accurately account for the full frequency dependence of vertices in fermionic systems, improving understanding of instabilities and fluctuation channels.

Findings

Frequency dependence is essential for accurate vertex representation.

Charge instability at finite frequency can be suppressed by self-energy feedback.

Self-energy exhibits Fermi liquid behavior despite complex vertex dependencies.

Abstract

We derive functional flow equations for the two-particle vertex and the self-energy in interacting fermion systems which capture the full frequency dependence of both quantities. The equations are applied to the hole-doped two-dimensional Hubbard model as a prototype system with entangled magnetic, charge and pairing fluctuations. Each fluctuation channel acquires substantial dependencies on all three Matsubara frequencies, such that the frequency dependence of the vertex cannot be accurately represented by a channel sum with only one frequency variable in each term. At the temperatures we are able to access, the leading instabilities are mostly antiferromagnetic, with an incommensurate wave vector. However, at large doping, a divergence in the charge channel occurs at a finite frequency transfer, if the vertex flow is computed without self-energy feedback. This enigmatic instability was already observed in a calculation by Husemann et al. [Phys. Rev. B 85, 075121 (2012)], who used an approximate separable ansatz for the frequency dependence of the vertex. We identify a simple mechanism for this instability in terms of a random phase approximation for the charge channel with a frequency dependent effective magnetic interaction as input. In spite of the strong momentum and frequency dependence of the vertex, the self-energy has a Fermi liquid form. At the moderate interaction strength where our approach is applicable, we obtain a moderate reduction of the quasi-particle weight and a sizable decay rate with a pronounced momentum dependence. Nevertheless, the self-energy feedback into the vertex flow turns out to be crucial, as it suppresses the unphysical finite frequency charge instability.