Doping dependence of heat transport in the iron-arsenide superconductor Ba(Fe$_{1-x}$Co$_x$)$_2$As$_2$: from isotropic to strongly $k$-dependent gap structure

TL;DR

This study investigates how the superconducting gap structure in Ba(Fe$_{1-x}$Co$_x$)$_2$As$_2$ evolves with doping, revealing a transition from isotropic to strongly $k$-dependent gaps without nodes, depending on Co concentration.

Contribution

It provides detailed measurements of thermal conductivity across doping levels, demonstrating the doping-dependent evolution of the superconducting gap structure in this material.

Findings

No zero-energy quasiparticles at any doping level.

Gap remains isotropic in underdoped regime.

Gap becomes strongly $k$-dependent in overdoped regime.

Abstract

The temperature and magnetic field dependence of the in-plane thermal conductivity $\kappa$ of the iron-arsenide superconductor Ba(Fe$_{1-x}$Co$_x$)$_2$As$_2$ was measured down to $T \simeq 50$ mK and up to $H = 15$ T as a function of Co concentration $x$ in the range 0.048 $ \leq x \leq $ 0.114. In zero magnetic field, a negligible residual linear term in $\kappa/T$ as $T \to 0$ at all $x$ shows that there are no zero-energy quasiparticles and hence the superconducting gap has no nodes in the $ab$-plane anywhere in the phase diagram. However, the field dependence of $\kappa$ reveals a systematic evolution of the superconducting gap with doping $x$, from large everywhere on the Fermi surface in the underdoped regime, as evidenced by a flat $\kappa (H)$ at $T \to 0$, to strongly $k$-dependent in the overdoped regime, where a small magnetic field can induce a large residual linear term, indicative of a deep minimum in the gap magnitude somewhere on the Fermi surface. This shows that the superconducting gap structure has a strongly $k$-dependent amplitude around the Fermi surface only outside the antiferromagnetic/orthorhombic phase.