Impurity effect as a probe for the pairing symmetry of graphene-based superconductors

Abstract

The single impurity effect on the graphene-based superconductor is studied theoretically. Four different pairing symmetries are discussed. Sharp resonance peaks are found near the impurity site for the d+id-wave pairing symmetry and the p+ip-wave pairing symmetry when the chemical potential is large. As the chemical potential decreases, the in-gap states are robust for the d+id pairing symmetry while they disappear for the p+ip pairing symmetry. Such in-gap peaks are absent for the fully gapped extended s-wave pairing symmetry and the nodal f-wave pairing symmetry. The existence of the in-gap resonance peaks can be explained well based on the sign-reversal of the superconducting gap along different Fermi pockets and by analyzing the denominator of the T-matrix. All of the features can be accessed by the experiments, which provide a useful probe for the pairing symmetry of graphene-based superconductors.