Controllable enhancement of p-wave superconductivity via magnetic coupling to a conventional superconductor

Abstract

Unconventional superconductors are of high interest due to their rich physics, a topical example being topological edge-states associated with p-wave superconductivity. A practical obstacle in studying such systems is the very low critical temperature Tc that is required to realize a p-wave superconducting phase in a material. We predict that the Tc of an intrinsic p-wave superconductor can be significantly enhanced by coupling it via an atomically thin ferromagnetic layer (F) to a conventional s-wave or a d-wave superconductor with a higher critical temperature. We show that this Tc-boost is tunable via the direction of the magnetization in F. Moreover, we show that the enhancement in Tc can also be achieved using the Zeeman-effect of an external magnetic field. Our findings provide a way to increase Tc in p-wave superconductors in a controllable way and make the exotic physics associated with such materials more easily accessible experimentally.