Theory of Dirac spin liquids on spin-S triangular lattice: possible application to α-CrOOH(D)

Abstract

Triangular lattice quantum antiferromagnet has recently emerged to be a promising playground for realizing Dirac spin liquids (DSLs) -- a class of highly entangled quantum phases hosting emergent gauge fields and gapless Dirac fermions. While previous theories and experiments focused mainly on S=1/2 spin systems, more recently signals of a DSL were detected in an S=3/2 system α-CrOOH(D). In this work we develop a theory of DSLs on triangular lattice with spin-S moments. We argue that in the most natural scenario, a spin-S system realizes a U(2S) DSL, described at low energy by gapless Dirac fermions coupled with an emergent U(2S) gauge field (also known as U(2S) QCD3). An appealing feature of this scenario is that at sufficiently large S, the U(2S) QCD becomes intrinsically unstable toward spontaneous symmetry breaking and confinement. The confined phase is simply the 120 coplanar magnetic order, which agrees with semiclassical (large-S) results on simple Heisenberg-like models. Other scenarios are nevertheless possible, especially at small S when quantum fluctuations are strong. For S=3/2, we argue that a U(1) DSL is also theoretically possible and phenomenologically compatible with existing measurements. One way to distinguish the U(3) DSL from the U(1) DSL is to break time-reversal symmetry, for example by adding a spin chirality term Si·(Sj×Sk) in numerical simulations: the U(1) DSL becomes the standard Kalmeyer-Laughlin chiral spin liquid with semion/anti-semion excitation; the U(3) DSL, in contrast, becomes a non-abelian chiral spin liquid described by the SU(2)3 topological order, with Fibonacci-like anyons.