Magnetic impurities in a strongly coupled superconductor

TL;DR

This paper investigates how magnetic impurities affect the superconducting properties of strongly coupled superconductors, revealing unique phenomena such as two critical temperatures for ferromagnetic exchange and the presence of in-gap bound states.

Contribution

It introduces a self-consistent approach combining Nagaoka equations with Migdal-Eliashberg theory to analyze magnetic impurity effects in strongly coupled superconductors, extending prior weak-coupling studies.

Findings

Only one pair of in-gap bound states observed.

Re-entrant superconductivity occurs with antiferromagnetic coupling.

Superconducting transition shows two critical temperatures with ferromagnetic exchange.

Abstract

We revisit certain aspects of a problem concerning the influence of carrier scattering induced by magnetic impurities in metals on their superconducting properties. Superconductivity is assumed to be driven by strong electron-phonon interaction. We use the self-consistent solution of the Nagaoka equations for the scattering matrix together with the Migdal-Eliashberg theory of superconductivity to compute the energy of the in-gap bound states, superconducting critical temperature and tunneling density of states for a wide range of values of the Kondo temperature and impurity concentrations. It is found that similar to the case of the weak coupling (BCS) superconductors there is only one pair of the bound states inside the gap as well as re-entrant superconductivity for the case of antiferromagnetic exchange coupling between the conduction electrons and magnetic impurities. In agreement with the earlier studies we find that the gapless superconductivity can be realized which in the case of antiferromagnetic exchange requires much smaller impurity concentration. Surprisingly, in contrast with the weakly coupled superconductors we find that superconducting transition exhibits two critical temperatures for the ferromagnetic exchange coupling.