Time-reversal and spatial reflection symmetry localization anomalies in (2+1)D topological phases of matter

Abstract

We study a class of anomalies associated with time-reversal and spatial reflection symmetry in (2+1)D topological phases of matter. In these systems, the topological quantum numbers of the quasiparticles, such as the fusion rules and braiding statistics, possess a Z2 symmetry which can be associated with either time-reversal (denoted Z2 T) or spatial reflections. Under this symmetry, correlation functions of all Wilson loop operators in the low energy topological quantum field theory (TQFT) are invariant. However, the theories that we study possess a severe anomaly associated with the failure to consistently localize the symmetry action to the quasiparticles, precluding even defining a notion of symmetry fractionalization. We present simple sufficient conditions which determine when Z2 T symmetry localization anomalies exist. We present an infinite series of TQFTs with such anomalies, some examples of which include USp(4)2 and SO(4)4 Chern-Simons (CS) theory. The theories that we find with these Z2 T anomalies can be obtained by gauging the unitary Z2 subgroup of a different TQFT with a Z4 T symmetry. We show that the anomaly can be resolved in several ways: (1) the true symmetry of the theory is Z4 T, or (2) the theory can be considered to be a theory of fermions, with T2 = (-1)Nf corresponding to fermion parity. Finally, we demonstrate that theories with the Z2 T localization anomaly can be compatible with Z2 T if they are "pseudo-realized" at the surface of a (3+1)D symmetry-enriched topological phase. The "pseudo-realization" refers to the fact that the bulk (3+1)D system is described by a dynamical Z2 gauge theory and thus only a subset of the quasiparticles are confined to the surface.