Syntheses and crystal structures of [Mg(HF) 2](SbF 6) 2 and [Ca(HF) 2](SbF 6) 2: new examples of HF acting as a ligand to metal centres

Abstract

[Mg(HF) 2](SbF 6) 2 and [Ca(HF) 2](SbF 6) 2 monocrystals were grown from the corresponding hexafluoroantimonates(V) dissolved in anhydrous hydrogen fluoride. [Mg(HF) 2](SbF 6) 2 crystallizes in the space group Pnma (no. 62) with a=1249.1(4) pm, b=1230.2(4) pm, c=699.1(2) pm, V=1.0742(6) nm 3, Z=4. Magnesium is octahedrally coordinated by six fluorine atoms from which two belong to two HF molecules. The structure can be represented by alternating rows of magnesium and antimony atoms running parallel to the c-axis. Magnesium atoms are connected by cis bridging Sb(2)F 6 units along the a-axis and by trans bridging Sb(1)F 6 units along the b-axis. In this way a three-dimensional network is formed. [Ca(HF) 2](SbF 6) 2 crystallizes in the space group P2 1/ n (no. 14) with a=935.2(3) pm, b=1088.7(3) pm, c=1104.8(3) pm, β=106.697(5)°, V=1.0774(5) nm 3, Z=4. The coordination sphere around the calcium atom consists of eight fluorine atoms which define the vertices of an Archimedean antiprism. The two HF molecules directly coordinate the calcium atom and their fluorine atoms are placed in the corners of different square faces of the Archimedean antiprism. The Ca–F(HF) distances are shorter than the Ca–F(Sb) distances. The Sb(1)F 6 and Sb(2)F 6 groups have four equatorial bridging fluorine atoms, while the Sb(3)F 6 groups have only two bridging trans F ligands. The Ca atoms in the [−1,0,1] plane are connected by equatorial F ligands of Sb(1)F 6 and Sb(2)F 6 units, forming a [Ca(SbF 6) +] n layer. These layers are connected by trans bridging Sb(3)F 6 groups. HF molecules occupy the space between these layers and additionally contribute to the connection between the layers by hydrogen bonding.