Bulk-boundary correspondence of (1+1)D symmetric gapped phases

Abstract

We develop an operator-algebraic framework for boundary conditions and bulk-boundary correspondence in one-dimensional gapped phases with categorical symmetry. Working directly in the thermodynamic limit, we construct half-infinite fusion spin chains and commuting-projector boundary Hamiltonians from a unitary fusion category C, an indecomposable semisimple right C-module category M, a Q-system Q∈C specifying the bulk phase, and a right Q-module K∈MQ, regarded as an object of MQop, specifying the boundary. We prove that these Hamiltonians have unique ground states and that the resulting realization functor MQop is an equivalence, so simple boundary conditions are classified by simple objects of MQ and general boundary conditions by their finite direct sums. We also give a microscopic formulation of the boundary symmetry topological field theory using DHR bimodules of the boundary quasi-local algebra. For a half-infinite fusion spin chain, the boundary DHR category is monoidally equivalent to (CM)rev, and the canonical action of the bulk DHR category on it agrees with the categorical action of Z1(Crev). Finally, we identify the action of the boundary DHR category on boundary conditions with the categorical action of (CM)rev on MQop. This yields a one-dimensional bulk-boundary correspondence: the enriched monoidal category describing the bulk is the enriched center of the enriched category describing the boundary.