Physics picture from neutron scattering study on Fe-based superconductors

TL;DR

This paper reviews neutron scattering studies on Fe-based superconductors, highlighting magnetic orders, orbital effects, phase coexistence, and the role of structural factors in superconductivity, providing insights into their pairing mechanisms.

Contribution

It introduces the orbital ordering mechanism for structural and magnetic transitions and links local structural features to superconducting properties in Fe-based materials.

Findings

Multiple antiferromagnetic orders not explained by SDW mechanism.

Orbital ordering as a common mechanism for structural and magnetic transitions.

Superconducting resonance peak observed, informing pairing symmetry.

Abstract

Neutron scattering, with its ability to measure the crystal structure, the magnetic order, and the structural and magnetic excitations, plays an active role in investigating various families of Fe-based high-Tc superconductors. Three different types of antiferromag- netic orders have been discovered in the Fe plane, but two of them cannot be explained by the spin-density-wave (SDW) mechanism of nesting Fermi surfaces. Noticing the close relation between antiferromagnetic order and lattice distortion in orbital ordering from previous studies on manganites and other oxides, we have advocated orbital or- dering as the underlying common mechanism for the structural and antiferromagnetic transitions in the 1111, 122 and 11 parent compounds. We observe the coexistence of antiferromagnetic order and superconductivity in the (Ba,K)Fe2 As2 system, when its phase separation is generally accepted. Optimal Tc is proposed to be controlled by the local FeAs4 tetrahedron from our investigation on the 1111 materials. The Bloch phase coherence of the Fermi liquid is found crucial to the occurrence of bulk superconductiv- ity in iron chalcogenides of both the 11 and the 245 families. Iron chalcogenides carry a larger staggered magnetic moment (> 2{\mu}B /Fe) than that in iron pnictides (< 1{\mu}B /Fe) in the antiferromagnetic order. Normal state magnetic excitations in the 11 supercon- ductor are of the itinerant nature while in the 245 superconductor the spin-waves of localized moments. The observation of superconducting resonance peak provides a cru- cial piece of information in current deliberation of the pairing symmetry in Fe-based superconductors.