Preparation, characterization and DFT+U study of the polar Fe-based phase BaFeZnInS containing = 5/2 zigzag chains

The polar magnetic chalcogenide phase Ba 5 Fe 2 ZnIn 4 S 15 was synthesized and its structure was solved by single crystal XRD. It is the first member with a 3d magnetic metal (Fe 3+ ) in the Pb 5 ZnGa 6 S 15 -type structure family of wide bandgap materials with non-linear optical properties. The three-dimensional framework possesses a low dimensional magnetic character through the presence of weakly interacting zig-zag chains made of corner-sharing FeS 4 tetrahedra forming chain 1, [FeS 2 ] − ∞ . The latter chains are separated by InS 4 tetrahedra providing weak magnetic super-super exchanges between them. The framework is also constituted by chain 2, [In 3 Zn 1 S 9 ] 7− ∞ (chain of T2-supertetrahedra) extended similarly to chain 1 along the direction c and connected through InS 4 tetrahedra. Symmetry analysis shows that the intrinsic polarization observed in this class of materials is mostly due to the anionic framework. Preliminary magnetic measurements and density functional theory calculations suggest dominating antiferromagnetic interactions with strong super-exchange coupling within the Fe-chains. The polar chalcogenide phase Ba 5 Fe 2 ZnIn 4 S 15 possesses weakly interacting magnetic zig-zag chains made of corner-sharing Fe 3+ S 4 thus forming an AFM S = 5/2 spin chain system. The intrinsic polarization is mostly due to the anionic framework.