Vertex functions at finite momentum: Application to antiferromagnetic quantum criticality

TL;DR

This paper investigates the behavior of vertex functions at finite momentum near antiferromagnetic quantum critical points, revealing divergences linked to quasiparticle effective mass in a Hubbard model framework.

Contribution

It derives Ward identities for vertex functions at finite momentum and demonstrates their divergence at antiferromagnetic critical points, providing explicit calculations in 3D.

Findings

Vertex functions diverge at antiferromagnetic critical points.

Divergence of vertex functions correlates with quasiparticle effective mass.

Explicit calculation confirms proportionality to effective mass divergence.

Abstract

We analyze the three-point vertex function that describes the coupling of fermionic particle-hole pairs in a metal to spin or charge fluctuations at non-zero momentum. We consider Ward identities, which connect two-particle vertex functions to the self energy, in the framework of a Hubbard model. These are derived using conservation laws following from local symmetries. The generators considered are the spin density and particle density. It is shown that at certain antiferromagnetic critical points, where the quasiparticle effective mass is diverging, the vertex function describing the coupling of particle-hole pairs to the spin density Fourier component at the antiferromagnetic wavevector is also divergent. Then we give an explicit calculation of the irreducible vertex function for the case of three-dimensional antiferromagnetic fluctuations, and show that it is proportional to the diverging quasiparticle effective mass .