Temperature-dependent $s_\pm \leftrightarrow s_{++}$ transitions in the multiband model for Fe-based superconductors with impurities

TL;DR

This paper investigates how impurity scattering and temperature influence the transition between $s_ p$ and $s_{++}$ states in multiband models of iron-based superconductors, revealing a temperature-dependent phase diagram with reentrant behavior.

Contribution

It demonstrates the existence of a temperature-dependent $s_ p o s_{++}$ transition line and reentrant states in the phase diagram of iron-based superconductors with impurities.

Findings

Transition line in temperature-disorder phase diagram.

Reentrant $s_{++} o s_ p$ transition at certain impurity levels.

High impurity scattering leads to only the $s_{++}$ state at higher temperatures.

Abstract

We study the dependence of the superconducting gaps on both the disorder and the temperature within the two-band model for iron-based materials. In the clean limit, the system is in the $s_\pm$ state with the sign-changing gaps. Scattering by nonmagnetic impurities leads to the change of sign of the smaller gap thus resulting in a transition from the $s_{\pm}$ to the $s_{++}$ state with the sign-preserving gaps. We show here that the transition is temperature-dependent, thus, there is a line of $s_\pm \to s_{++}$ transition in the temperature-disorder phase diagram. There exists a narrow range of impurity scattering rates, where the disorder-induced $s_\pm \to s_{++}$ transition occurs at low temperatures, but then the low-temperature $s_{++}$ state transforms back to the $s_\pm$ state at higher temperatures. With increasing impurity scattering rate, temperature of such $s_{++} \to s_{\pm}$ transition shifts to the critical temperature $T_c$ and only the $s_{++}$ state is left for higher amount of disorder.