Orbital-Selective Band Structure Evolution in BaFe2-xMxAs2 (M = Cr, Co, Cu, Ru and Mn) Probed by Polarization-Dependent ARPES

Abstract

We present a systematic study of the evolution of the band structure in the Fe-based superconductor family BaFe2-xMxAs2 (M = Cr, Co, Cu, Ru and Mn) using polarization-dependent angle-resolved photoemission spectroscopy (ARPES). Low-substituted samples, with comparable spin-density wave transition temperatures (TSDW), were chosen to facilitate controlled comparisons. The sizes of the central hole pockets (α, β, and γ) remain largely unchanged across different substitutions, showing no clear correlation with either TSDW or the As height relative to the Fe planes. However, subtle trends are observed: a modest increase in the size of the ηX electron pocket correlates with the suppression of TSDW. Furthermore, the contraction of the ηX pocket appears to be linked to an increase in the As height relative to the Fe planes. Our results suggest that the suppression of TSDW is primarily driven by changes in the Fe-As bond length, with the effect being more pronounced in electronic states with planar character. These findings provide insight into the electronic structure of BaFe2-xMxAs2.