Orbital-dependent effects of electron correlations in microscopic models for iron-based superconductors

TL;DR

This paper reviews recent theoretical advances on how electron correlations affect different orbitals in multiorbital models of iron-based superconductors, highlighting orbital-selective Mott transitions and their relation to superconductivity.

Contribution

It provides a comprehensive review of orbital-dependent electron correlation effects and phase diagrams in multiorbital models for iron-based superconductors, emphasizing the role of Hund's coupling and vacancies.

Findings

Orbital-dependent Mott transitions occur in models of iron-based superconductors.

Orbital-selective Mott phases are stabilized near the Mott transition.

Vacancies in alkaline iron selenides promote Mott insulating behavior.

Abstract

The bad metal behavior in the normal state of the iron-based superconductors suggests an intimate connection between the superconductivity and a proximity to a Mott transition. At the same time, there is strong evidence for the multi-orbital nature of the electronic excitations. It is then important to understand the orbital-dependent effects of electron correlations. In this paper we review the recent theoretical progresses on the metal-to-insulator transition in multiorbital models for the iron-based superconductors. These include studies of models that contain at least the 3d xy and 3d xz/yz models, using a slave-spin technique. For commensurate filling corresponding to that of the parent iron pnictides and chalcogenideds, a Mott transition generally exists in all these models. Near the Mott transition, a strongly correlated metal exhibiting bad metal features and strong orbital selectivity is stabilized due to the interplay of Hund's coupling and orbital-degeneracy breaking. Particularly for the alkaline iron selenides, the ordered vacancies effectively reduce the kinetic energy, thereby pushing the system further into the Mott-insulating regime; in the metallic state, there exists an orbital-selective Mott phase in which the iron 3d xy orbital is Mott localized while the other 3d orbitals are still itinerant. An overall phase diagram for the alkaline iron selenides has been proposed, in which the orbital-selective Mott phase connects between the superconducting phase and the Mott-insulating parent state.