Exploring multichannel superconductivity in ThFeAsN
Abstract
We investigate theoretically the superconducting state of the undoped Fe-based superconductor ThFeAsN. Using input from calculations, we solve the Fermi-surface based, multichannel Eliashberg equations for Cooper-pair formation mediated by spin and charge fluctuations, and by the electron-phonon interaction (EPI). Our results reveal that spin fluctuations alone, when coupling only hole-like with electron-like energy bands, can account for a critical temperature up to with an -wave superconducting gap symmetry, which is a comparatively low with respect to the experimental value . Other combinations of interaction kernels (spin, charge, electron-phonon) lead to a suppression of due to phase frustration of the superconducting gap. We qualitatively argue that the missing ingredient to explain the gap magnitude and in this material is the first-order correction to the EPI vertex. In the noninteracting state this correction adopts a form supporting the gap symmetry, in contrast to EPI within Migdal's approximation, i.e., EPI without vertex correction, and therefore it enhances tendencies arising from spin fluctuations.
Cite
@article{arxiv.2103.16928,
title = {Exploring multichannel superconductivity in ThFeAsN},
author = {Fabian Schrodi and Fairoja Cheenicode Kabeer and Alex Aperis and Peter M. Oppeneer},
journal= {arXiv preprint arXiv:2103.16928},
year = {2021}
}