Possible phases of the spin-$1/2$ $XXZ$ model on a honeycomb lattice by boson-vortex duality

TL;DR

This paper uses boson-vortex duality to explore various phases of the frustrated spin-1/2 J1-J2 XXZ model on a honeycomb lattice, identifying symmetry-breaking and symmetric gapped phases consistent with numerical results.

Contribution

It introduces a duality-based framework to classify and understand the phases of the honeycomb J1-J2 XXZ model, including novel featureless paramagnetic states.

Findings

Identification of lattice symmetry-breaking gapped phases

Connection of vortex band structure to observed phases

Proposal of a featureless paramagnet at specific vortex conditions

Abstract

Motivated by recent numerical work, we use the boson-vortex duality to study the possible phases of the frustrated spin-$\frac{1}{2}$ $J_1-J_2$ XXZ models on the honeycomb lattice. By condensing the vortices, we obtain various gapped phases that either break certain lattice symmetry or preserve all the symmetries. The gapped phases breaking lattice symmetries occur when the vortex band structure has two minima. Condensing one of the two vortex flavors leads to an Ising ordered phase, while condensing both vortex flavors gives rise to a valence-bond-solid state. Both of those phases have been observed in the numerical studies of the $J_1-J_2$ XXZ honeycomb model. Furthermore, by tuning the band structure of vortex and condensing it at the $\Gamma$ point, we obtain a featureless paramagnet. But the precise nature of this featureless state is still unclear and needs future study.