Magnetic scattering and electron pair breaking by rare-earth-ion substitution in BaFe2As2 epitaxial films

TL;DR

This study investigates how rare-earth ion substitution affects superconductivity in BaFe2As2 films, revealing magnetic scattering and pair-breaking effects that influence critical temperatures and superconducting properties.

Contribution

It provides new insights into magnetic pair-breaking mechanisms caused by rare-earth dopants in iron-based superconductors.

Findings

Superconductivity observed at 22.4 K for La-doping

Magnetic scattering increases with RE doping

Negative magnetoresistance indicates magnetic pair breaking

Abstract

The effect of electron doping by trivalent charge state rare-earth ion (RE = La, Ce, Pr, and Nd) substitutions on the superconductivity in BaFe2As2 was examined using epitaxial films. Each of the RE substitutions suppressed the resistivity anomaly associated with the magnetic/structural phase transitions, leading to the resistivity drops and superconductivity transitions. Bulk superconductivity was observed at the maximum onset critical temperature (Tconset) of 22.4 K for La-doping and 13.4 K for Ce-doping, while only broad resistivity drops were observed at 6.2 K for Pr-doping and 5.8 K for Nd-doping but neither zero resistivity nor distinct Meissner effect were observed at least down to 2 K. The decrease in Tconset with increasing the number of RE 4f electrons cannot be explained in terms of the crystalline qualities or crystallographic structure parameters of the BaFe2As2 films. It was clarified, based on resistivity-temperature analyses, that magnetic scattering became increasingly significant in the above order of the RE dopants. The negative magnetoresistance was enhanced by the Ce- and Pr-doping, implying that the decrease in Tc originates from magnetic pair breaking by interaction of the localized 4f orbitals in the RE dopants with the itinerant Fe 3d orbitals.