Lix(C5H5N)yFe2-zSe2: a defect resilient expanded-lattice high-temperature superconductor

Abstract

Two-dimensional iron-chalcogenide intercalates display a remarkable correlation of the interlayer spacing with the enhancement of the superconducting critical temperature (Tc). In this work, synchrotron x-ray absorption (XAS, at Fe and Se K edges) and emission (XES) spectroscopies, allow to discuss how the important rise of Tc (44 K) in the molecule intercalated Lix(C5H5N)yFe2-zSe2 relates to the electronic and local structure changes felt by the inorganic host upon doping (x). XES shows that widely-separated layers of edge-sharing FeSe4 tetrahedra, carry low-spin moieties with a local Fe magnetic moment slightly reduced compared to the parent β- Fe2-zSe2. Pre-edge XAS advises on the progressively reduced mixing of metal 3d-4p states upon lithiation. Doping-mediated local lattice modifications, probed by conventional Tc-optimization measures (cf. anion height and FeSe4 tetrahedra regularity), become less relevant when layers are spaced far away. On the basis of extended x-ray absorption fine structure, such distortions are compensated by a softer Fe-network that relates to Fe-site vacancies, alleviating electron-lattice correlations and superconductivity. Density functional theory (DFT) guided modification of isolated Fe2-zSe2 (z, vacant sites) planes, resembling the host layers, identify that Fe-site deficiency occurs at low energy cost, giving rise to stretched Fe-sheets, in accord with experiments. The robust high-Tc in Lix(C5H5N)yFe2-zSe2, arises from the interplay of electron donating spacers and the iron-selenide layers tolerance to defect chemistry, a tool to favorably tune its Fermi surface properties.