Nematic Fluctuations and Electronic Correlations in Heavily Hole-Doped Ba1-xKxFe2As2 Probed by Elastoresistance
Abstract
This work investigates nematic fluctuations and electronic correlations in the hole-doped iron pnictide superconductor Ba1-xKxFe2As2 by means of longitudinal and transverse elastoresistance measurements over a wide doping range (0.63 < x < 0.98). For this purpose, the orbital character of the electronic response was revealed by decomposition of the elastoresistance into the A1g and B2g symmetry channels. It was shown that at lower doping levels nematic fluctuations in the B2g channel dominate, while for x > 0.68 the A1g channel becomes dominant and reaches a pronounced maximum at x ≈ 0.8 which indicates strong orbital-selective electronic correlations. Despite the dominance of the A1g signal at high doping, a weak contribution in the B2g channel persists, which can be interpreted as a remnant of nematic fluctuations. Model calculations based on a five-orbital tight-binding Hamiltonian with interactions attribute the observed enhancement in the A1g channel to an orbital-selective Kondo-like resonance, predominantly involving the dxy orbital. We discuss our results in relation to the evolution of the Sommerfeld coefficient reported in the literature and a reported change of the superconducting order parameter. All this indicates that for x > 0.68 qualitatively new physics emerges. Our findings suggest that electronic correlations in the strongly hole-doped regime play an important role in superconductivity, while the detectable weak nematic fluctuations may also be of relevance.
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