A magnetic excitation linking quasi-1D Chevrel-type selenide and arsenide superconductors

TL;DR

This study uncovers a magnetic excitation in quasi-1D Chevrel phases that links their unconventional electronic properties with related superconducting arsenides, suggesting a shared underlying physics despite structural differences.

Contribution

It reveals a magnetic excitation in In$_2$Mo$_6$Se$_6$ and Rb$_2$Mo$_6$Se$_6$, indicating a hidden connection between Chevrel phases and arsenide superconductors.

Findings

Discovery of a linear-dispersion magnetic excitation in non-superconducting samples.

Evidence of unconventional carriers with spin contributions in these materials.

Potential link in the physics of different classes of low-dimensional superconductors.

Abstract

The quasi-one-dimensional Chevrel phases, A$_2$Mo$_6$Se$_6$ (A = Tl, In, K, Rb, Cs), are of interest due to their atypical electronic properties. The Tl and In analogues undergo a superconducting transition whereas the alkali metal analogues show charge gapping of another, not well understood type. We report the results of inelastic neutron scattering on polycrystalline In$_2$Mo$_6$Se$_6$ ($T_c=2.85\,$K) and Rb$_2$Mo$_6$Se$_6$ (non-superconducting) samples, which reveal a column of intensity with linear dispersion from [0 0 1/2] to [0 0 1] in both compounds. The observed temperature and |$Q$| independence together suggest the presence of unconventional carriers with a spin contribution to the excitation. This is contrary to the prevailing model for these materials, which is that they are non-magnetic. The excitation has similar dispersion and $S(Q,E,T)$ behavior as one observed in the structurally related superconducting compounds A$_2$Cr$_3$As$_3$ and A$_2$Mo$_3$As$_3$ (A = K, Rb, Cs), which has been interpreted as magnetic in origin and related to Fermi surface nesting. The connection is unexpected because the calculated Fermi surface of the arsenides differs substantially from the A$_2$Mo$_6$Se$_6$ compounds, and many consider them distinct classes of materials. The new observation suggests a hidden link in the physics between both classes of superconductors, perhaps originating from their quasi-low-dimensional character.