Abstract
FeSe is classed as a Hund’s metal, with a multiplicity of d bands near the Fermi level. Correlations in Hund’s metals mostly originate from the exchange parameter J, which can drive a strong orbital selectivity in the correlations. The Fe-chalcogens are the most strongly correlated of the Fe-based superconductors, with dxy the most correlated orbital. Yet little is understood whether and how such correlations directly affect the superconducting instability in Hund’s systems. By applying a recently developed ab initio theory, we show explicitly the connections between correlations in dxy and the superconducting critical temperature Tc. Starting from the ab initio results as a reference, we consider various kinds of excursions in parameter space around the reference to determine what controls Tc. We show small excursions in J can cause colossal changes in Tc. Additionally we consider changes in hopping by varying the Fe-Se bond length in bulk, in the free standing monolayer M-FeSe, and M-FeSe on a SrTiO3 substrate (M-FeSe/STO). The twin conditions of proximity of the dxy state to the Fermi energy, and the strength of J emerge as the primary criteria for incoherent spectral response and enhanced single- and two-particle scattering that in turn controls Tc. Using c-RPA, we show further that FeSe in monolayer form (M-FeSe) provides a natural mechanism to enhance J. We explain why M-FeSe/STO has a high Tc, whereas M-FeSe in isolation should not. Our study opens a paradigm for a unified understanding what controls Tc in bulk, layers, and interfaces of Hund’s metals by hole pocket and electron screening cloud engineering.
Highlights
Iron-pnictogen and iron-chalcogen based superconductors (IBS) are classed as Hund’s metals, meaning correlations mostly originate from the Hund’s exchange parameter J
A unified picture of the origins of superconductivity in FeSe emerges from evidence drawn from several parametric studies of FeSe around a high-fidelity ab initio theory
Superconducting glue mainly originates from low-energy spin fluctuations concentrated in a region near the antiferromagnetic ordering vector
Summary
Iron-pnictogen and iron-chalcogen based superconductors (IBS) are classed as Hund’s metals, meaning correlations mostly originate from the Hund’s exchange parameter J. In recent years a consensus has evolved that strong Hund’s correlations drive the ubiquitous bad metallicity observed in their phase diagrams [1,2]. Such metals have a multiplicity of bands near the Fermi level EF; in particular FeSe [3,4,5] has all five Fe d states active there. The role of Hund’s exchange J is explored in determining the orbital-selectivity [7] and triplet pairing in Uranium based superconductors [8]. Very little is known whether Hund’s correlation can generate glue for superconducting pairing and control Tc in singlet-pairing channel
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