SU(2) gauge theory of the Hubbard model and application to the honeycomb lattice

TL;DR

This paper develops an SU(2) gauge theory formalism for Hubbard models, proposing the honeycomb lattice as a candidate for a spin liquid near the Mott transition, and predicts observable signatures in numerical simulations.

Contribution

It introduces the SU(2) slave-rotor formalism for Hubbard models and applies it to the honeycomb lattice, identifying an algebraic spin liquid phase near the Mott transition.

Findings

Identification of an SU(2) algebraic spin liquid with gapless Dirac fermions

Proposal of the honeycomb lattice Hubbard model as a spin liquid candidate

Detection signatures include antiferromagnetic and valence-bond correlations

Abstract

Motivated by recent experiments on the triangular lattice Mott-Hubbard system kappa-(BEDT-TTF)2Cu2(CN)3, we develop a general formalism to investigate quantum spin liquid insulators adjacent to the Mott transition in Hubbard models. This formalism, dubbed the SU(2) slave-rotor formulation, is an extension of the SU(2) gauge theory of the Heisenberg model to the case of the Hubbard model. Furthermore, we propose the honeycomb lattice Hubbard model (at half-filling) as a candidate for a spin liquid ground state near the Mott transition; this is an appealing possibility, as this model can be studied via quantum Monte Carlo simulation without a sign problem. The pseudospin symmetry of Hubbard models on bipartite lattices turns out to play a crucial role in our analysis, and we develop our formalism primarily for the case of a bipartite lattice. We also sketch its development for a general Hubbard model. We develop a mean-field theory and apply it to the honeycomb lattice. On the insulating side of the Mott transition, we find an SU(2) algebraic spin liquid (ASL), described by gapless S = 1/2 Dirac fermions (spinons) coupled to a fluctuating SU(2) gauge field. We construct a low-energy effective theory describing the ASL phase, the conducting semimetal phase and the Mott transition between them. This physics can be detected in numerical simulations via the simultaneous presence of substantial antiferromagnetic and valence-bond solid correlations. Our analysis suggests that both a third-neighbor electron hopping, and/or pseudospin-breaking terms such as a nearest-neighbor density interaction, may help to stabilize a spin liquid phase.