Theory of Dirac Spin-Orbital Liquids: monopoles, anomalies, and applications to SU(4) honeycomb models

Abstract

Dirac spin liquids represent a class of highly-entangled quantum phases in two dimensional Mott insulators, featuring exotic properties such as critical correlation functions and absence of well-defined low energy quasi-particles. Existing numerical works suggest that the spin-orbital SU(4) symmetric Kugel-Khomskii model of Mott insulators on the honeycomb lattice realizes a Dirac spin-orbital liquid, described at low energy by (2+1)d quantum electrodynamics (QED3) with Nf=8 Dirac fermions. We generalize methods previously developed for SU(2) spin systems to analyze the symmetry properties and stability of the Dirac spin-orbital liquid. We conclude that the standard Dirac state in the SU(4) honeycomb system, based on a simple parton mean-field ansatz, is intrinsically unstable at low energy due to the existence of a monopole perturbation that is allowed by physical symmetries and relevant under renormalization group flow. We propose two plausible alternative scenarios compatible with existing numerics. In the first scenario, we propose an alternative U(1) Dirac spin-orbital liquid, which is similar to the standard one except for its monopole symmetry quantum numbers. This alternative U(1) state represents a stable gapless phase. In the second scenario, we start from the standard U(1) Dirac liquid and Higgs the U(1) gauge symmetry down to Z4. The resulting Z4 Dirac spin-orbital liquid is stable. We also discuss the continuous quantum phase transitions from the Z4 Dirac liquids to conventional symmetry-breaking orders, described by the QED3 theory with Nf=8 supplemented with a critical charge-4 Higgs field. We discuss possible ways to distinguish these scenarios in numerics. We also extend previous calculations of the quantum anomalies of QED3 and match with generalized lattice Lieb-Schultz-Mattis constraints.