Lifetime of edge modes at rough surfaces of chiral superconductors

Abstract

We study the effect of diffuse surface scattering on the edge modes in two-dimensional chiral superconductors with time-reversal symmetry-breaking Cooper pairs, each carrying angular momentum m (m = 1,2,3, ·s). To elucidate the diffuse scattering effect, we formulate the inverse lifetime = /τ corresponding to the broadening of the surface density of states (SDOS) for the edge mode. This derivation uses random S-matrix theory, which allows us to describe the surface effect in a unified way from the specular to the diffuse limit within the quasiclassical theory framework of superconductivity. We find that in the chiral states with m ≥ 2 is larger than that in the chiral p-wave state (m = 1) because of the multiple edge mode branches in former superconducting states (the number of which equals m). Diffuse scattering between the different branches causes a significant broadening of SDOS. In contrast, the edge mode in the chiral p-wave state is robust to diffuse scattering because only a single edge mode branch exists. We also discuss SDOS at the diffuse limit, where the description in terms of is not useful. The diffuse scattering effect on SDOS can be understood qualitatively in terms of destructive interference analogous to that caused by impurity scattering in unconventional superconductors.