Superconductivity in a two-dimensional repulsive Rashba gas at low electron density

Abstract

We study the superconducting instability and the resulting superconducting states in a two-dimensional repulsive Fermi gas with Rashba spin-orbit coupling at low electron density (namely the Fermi energy EF is lower than the energy ER of the Dirac point induced by Rashba coupling). We find that superconductivity is enhanced as the dimensionless Fermi energy εF (εF EF/ER) decreases, due to the following two reasons. First, the density of states at εF increases as 1/εF. Second, the particle-hole bubble becomes more anisotropic, resulting in an increasing effective attraction. The superconducting state is always in the total angular momentum jz=+2 (or jz=-2) channel with Chern number C=4 (or C=-4), breaking time reversal symmetry spontaneously. Although a putative Leggett mode is expected due to the two-gap nature of the superconductivity, we find that it is always damped. More importantly, once a sufficiently large Zeeman coupling is applied to the superconducting state, the Chern number can be tuned to be 1 and Majorana zero modes exist in the vortex cores.