Flux Response of Rotation-Invariant Topological Insulators

Abstract

Threading magnetic flux into topological phases can induce bound states that reveal intrinsic properties of the ground state. In a 3D Z2 topological insulator, a quantized π flux traps a pair of 1D helical modes, whereas a trivial insulator hosts none. In this work, we show that in the presence of even-fold rotation symmetry Cn, a 3D band insulator features a refined Z2 × Z2 classification of the flux response. Specifically, it can host two distinct types of helical flux-bound modes that are distinguished by their angular momentum. When both types of flux modes coexist, the system is not a strong topological insulator, but a Cn-protected topological crystalline insulator. Building on this result, we propose that flux-threaded nanowires of such topological phase provide a natural platform for realizing 1D crystalline topological superconductors with multiple Cn-protected Majorana modes.