Many-body topological invariants in fermionic symmetry protected topological phases: Cases of point group symmetries

Abstract

We propose the definitions of many-body topological invariants to detect symmetry-protected topological phases protected by point group symmetry, using partial point group transformations on a given short-range entangled quantum ground state. Partial point group transformations gD are defined by point group transformations restricted to a spatial subregion D, which is closed under the point group transformations and sufficiently larger than the bulk correlation length . By analytical and numerical calculations,we find that the ground state expectation value of the partial point group transformations behaves generically as GS | gD | GS [ i θ+ γ - α Area(∂ D)d-1 ]. Here, Area(∂ D) is the area of the boundary of the subregion D, and α is a dimensionless constant. The complex phase of the expectation value θ is quantized and serves as the topological invariant, and γ is a scale-independent topological contribution to the amplitude. The examples we consider include the Z8 and Z16 invariants of topological superconductors protected by inversion symmetry in (1+1) and (3+1) dimensions, respectively, and the lens space topological invariants in (2+1)-dimensional fermionic topological phases. Connections to topological quantum field theories and cobordism classification of symmetry-protected topological phases are discussed.