Breakdown of the Landau-Fermi liquid in Two Dimensions due to Umklapp Scattering

TL;DR

This paper investigates how Umklapp scattering causes a breakdown of Landau-Fermi liquid behavior in a two-dimensional Hubbard model, revealing an insulating spin liquid state with unique pairing and magnetic properties.

Contribution

It demonstrates that Umklapp processes near saddle points induce an insulating spin liquid phase, a novel insight into non-Fermi liquid behavior in 2D correlated systems.

Findings

Umklapp scattering drives strong coupling instabilities.

Identification of an insulating spin liquid with pairing and magnetic correlations.

Fermi surface near saddle points enhances pairing and Umklapp interactions.

Abstract

We study the renormalization group flow of the interactions in the two-dimensional t-t' Hubbard model near half filling in a N-patch representation of the whole Fermi surface. Starting from weak to intermediate couplings the flows are to strong coupling with different character depending on the choice of parameters. In a large parameter region elastic Umklapp scatterings drive an instability which on parts of the Fermi surface exhibits the key signatures of an insulating spin liquid (ISL), as proposed by Furukawa et al., rather than a conventional symmetry-broken state. The ISL is characterized by both strong d-wave pairing and antiferromagnetic correlations, however it is insulating due to the vanishing local charge compressibility and a spin liquid because of the spin gap arising from the pairing correlations. We find that the ISL is a consequence of a Fermi surface close to the saddle points at the Brillouin zone boundaries which provides an intrinsic and mutually reinforcing coupling between pairing and Umklapp channels.