(2+1)D topological phases with RT symmetry: many-body invariant, classification, and higher order edge modes

Abstract

It is common in condensed matter systems for reflection (R) and time-reversal (T) symmetry to both be broken while the combination RT is preserved. In this paper we study invariants that arise due to RT symmetry. We consider many-body systems of interacting fermions with fermionic symmetry groups Gf = Z2f × Z2RT, U(1)f Z2RT, and U(1)f × Z2RT. We show that (2+1)D invertible fermionic topological phases with these symmetries have a Z × Z8, Z2 × Z2, and Z2 × Z4 classification, respectively, which we compute using the framework of G-crossed braided tensor categories. We provide a many-body RT invariant in terms of a tripartite entanglement measure, and which we show can be understood using an edge conformal field theory computation in terms of vertex states. For Gf = U(1)f Z2RT, which applies to charged fermions in a magnetic field, the non-trivial value of the Z2 invariant requires strong interactions. For symmetry-preserving boundaries, the phases are distinguished by zero modes at the intersection of the reflection axis and the boundary. Additional invariants arise in the presence of translation or rotation symmetry.