Interaction-induced topological phase transition and Majorana edge states in low-dimensional orbital-selective Mott insulators

It is known that superconductivity induced on a topological insulator's surface can lead to exotic Majorana modes. In this context, iron-based high critical temperature superconductors are among the main candidates to host such exotic phenomenon. Moreover, it is commonly believed that the Coulomb interaction is vital for the magnetic and superconducting properties of these systems. This work bridges these two perspectives and shows that the Coulomb interaction can also drive a trivial superconductor with orbital degrees of freedom into the topological phase. Namely, we show that above some critical value of the Hubbard interaction, identified by the change in entropy behaviour, the system simultaneously develops spiral spin order, a highly unusual triplet amplitude in superconductivity, and, remarkably, Majorana fermions at the edges of the system.