Double Majorana vortex zero modes in superconducting topological crystalline insulators with surface rotation anomaly

Abstract

The interplay of time-reversal and n-fold rotation symmetries (n=2,4,6) is known to bring a new class of topological crystalline insulators (TCIs) having n surface Dirac cones due to surface rotation anomaly. We show that the proximity-induced s-wave superconductivity on the surface of these TCIs yields a topological superconducting phase in which two Majorana zero modes are bound to a vortex, and that n-fold rotation symmetry (n=2,4,6) enriches the topological classification of a superconducting vortex from Z2 to Z2×Z2. Using a model of a three-dimensional high-spin topological insulator with s-wave superconductivity and two-fold rotation symmetry, we show that, with increasing chemical potential, the number of Majorana zero modes at one end of a vortex changes as 210 through two topological vortex phase transitions. In addition, we show that additional magnetic-mirror symmetry further enhances the topological classification to Z × Z