Suppression of Superconductivity and Nematic Order in Fe1–ySe1–xSx(0 ≤ x≤ 1; y≤ 0.1) Crystals by Anion Height Disorder

Connections between crystal chemistry and critical temperature Tchave been in the focus of superconductivity, one of the most widely studied phenomena in physics, chemistry, and materials science alike. In most Fe-based superconductors, materials chemistry and physics conspire so that Tccorrelates with the average anion height above the Fe plane, i.e., with the geometry of the FeAs4or FeCh4(Ch = Te, Se, or S) tetrahedron. By synthesizing Fe1–ySe1–xSx(0 ≤ x≤ 1; y≤ 0.1), we find that in alloyed crystals Tcis not correlated with the anion height like it is for most other Fe superconductors. Instead, changes in Tc(x) and tetragonal-to-orthorhombic (nematic) transition Ts(x) upon cooling are correlated with disorder in Fe vibrations in the direction orthogonal to Fe planes, along the crystallographic c-axis. The disorder stems from the random nature of S substitution, causing deformed Fe(Se,S)4tetrahedra with different Fe–Se and Fe–S bond distances. Our results provide evidence of Tcand Tssuppression by disorder in anion height. The connection to local crystal chemistry may be exploited in computational prediction of new superconducting materials with FeSe/S building blocks.