Orbital fluctuation mechanism for superconductivity in iron-based compounds

TL;DR

This paper proposes that orbital fluctuations in a multi-band framework serve as the pairing mechanism for superconductivity in iron-based compounds, emphasizing the role of non-universal order parameters influenced by band structure details.

Contribution

It introduces a SU(4) theoretical model for two-orbital systems, analyzing the coupling of spin and orbital fluctuations in iron-based superconductors.

Findings

Orbital and spin fluctuations are strongly coupled.

The superconducting order parameter symmetry is highly non-universal.

Identified parameters controlling fluctuation coupling and pairing interactions.

Abstract

We propose orbital fluctuations in a multi-band ground state as the superconducting pairing mechanism in the new iron-based materials. We develop a general SU(4) theoretical framework for studying a two-orbital model and discuss a number of scenarios that may be operational within this orbital fluctuation paradigm. The orbital and spin symmetry of the superconducting order parameter is argued to be highly non-universal and dependent on the details of the underlying band structure. We introduce a minimal two-orbital model for the Fe-pnictides characterized by non-degenerate orbitals that strongly mix with each other. They correspond to the iron "d_xy" orbital and to an effective combination of "d_zx" and "d_zy", respectively. Using this effective model we perform RPA calculations of susceptibilities and effective pairing interactions. We find that spin and orbital fluctuations are, generally, strongly coupled and we identify the parameters that control this coupling as well as the relative strength of various channels.