On the Structure of Vacancy Ordered Superconducting Alkali Metal Iron Selenide

TL;DR

This study elucidates the crystal structure of vacancy-ordered alkali metal iron selenide superconductors, revealing key structural features and vacancy arrangements that correlate with their superconducting properties.

Contribution

It provides detailed structural characterization of superconducting alkali metal iron selenides, highlighting the role of vacancy ordering and alkali metal occupancy in superconductivity.

Findings

All samples have an almost identical vacancy-ordered supercell structure.

Vacancy arrangements and alkali metal occupancy influence the FeSe4 tetrahedral distortion.

Superconductivity correlates with specific vacancy and occupancy configurations.

Abstract

With single crystal X-ray diffraction studies, we compare the structures of three sample showing optimal superconductivity, K0.774(4)Fe1.613(2)Se2, K0.738(6)Fe1.631(3)Se2 and Cs0.748(2)Fe1.626(1)Se2. All have an almost identical ordered vacancy structure with a ({\sqrt}5 x {\sqrt}5 x 1) super cell. The tetragonal unit cell, space group I4/m, possesses lattice parameters at 250K of a = b = 8.729(2) {\AA} and c = 14.120(3) {\AA}, a = b = 8.7186(12) {\AA} and c = 14.0853(19) {\AA} and at 295 K, a = b = 8.8617(16) {\AA} and c = 15.304(3) {\AA} for the three crystals, respectively. The structure contains two iron sites; one is almost completely empty, whilst the other is fully occupied. There are similarly two alkali metal sites that are occupied in the range of 72.2(2) % to 85.3(3) %. The inclusion of alkali metals and the presence of vacancies within the structure allows for considerable relaxation of the FeSe4 tetrahedron, compared with members of the Fe(Te, Se, S) series, and the resulting shift of the Se - F - Se bond angles to less distorted geometry could be important in understanding the associated increase in the superconducting transition temperature. The structure of these superconductors distinguishes themselves from the structure of the non-superconducting phases by an almost complete absence of Fe on the (0 0.5 0.25) site as well as lower alkali metal occupancy that ensures an exact Fe2+ oxidation state, which are clearly critical parameters in the promotion of superconductivity.