Superconductivity mediated by the antiferromagnetic spin-wave in chalcogenide iron-base superconductors

TL;DR

This paper proposes a model where superconductivity in iron-based chalcogenide superconductors is mediated by antiferromagnetic spin-wave excitations, explaining the coexistence of superconductivity and antiferromagnetism.

Contribution

It introduces a theoretical model showing how coherent spin wave excitations can mediate pairing, providing a natural explanation for experimental observations.

Findings

Superconductivity can be driven by antiferromagnetic spin-wave excitations.

The model accounts for coexistence of superconducting and antiferromagnetic orders.

Effective pairing potential derived under linear spin-wave approximation.

Abstract

The ground state of K$_{0.8+x}$Fe$_{1.6+y}$Se$_2$ and other iron-based selenide superconductors are doped antiferromagnetic semiconductors. There are well defined iron local moments whose energies are separated from those of conduction electrons by a large band gap in these materials. We propose that the low energy physics of this system is governed by a model Hamiltonian of interacting electrons with on-site ferromagnetic exchange interactions and inter-site superexchange interactions. We have derived the effective pairing potential of electrons under the linear spin-wave approximation and shown that the superconductivity can be driven by mediating coherent spin wave excitations in these materials. Our work provides a natural account for the coexistence of superconducting and antiferromagnetic long range orders observed by neutron scattering and other experiments.