Square antiprismatic molecular geometry

Square antiprismatic molecular geometry
ExamplesXeF2−
8, ReF
8
Point groupD4d
Coordination number8
μ (Polarity)0

In chemistry, the square antiprismatic molecular geometry describes the shape of compounds where eight atoms, groups of atoms, or ligands are arranged around a central atom, defining the vertices of a square antiprism.[1] This shape has D4d symmetry and is one of the three common shapes for octacoordinate transition metal complexes, along with the dodecahedron and the bicapped trigonal prism.[2][3]

Like with other high coordination numbers, eight-coordinate compounds are often distorted from idealized geometries, as illustrated by the structure of Na3TaF8. In this case, with the small Na+ ions, lattice forces are strong. With the diatomic cation NO+, the lattice forces are weaker, such as in (NO)2XeF8, which crystallizes with a more idealized square antiprismatic geometry.

  • The distorted square antiprismatic [TaF8]3− anion in the Na3TaF8 lattice.[4]
    The distorted square antiprismatic [TaF8]3− anion in the Na3TaF8 lattice.[4]
  • The square antiprismatic [XeF8]2− anion in the lattice of nitrosonium octafluoroxenate(VI), (NO)2XeF8.[5]
    The square antiprismatic [XeF8]2− anion in the lattice of nitrosonium octafluoroxenate(VI), (NO)2XeF8.[5]
  • Structure of the Bi82+ cluster in the [Bi8](GaCl4)2.
    Structure of the Bi82+ cluster in the [Bi8](GaCl4)2.

Examples

  • XeF2−
    8
  • IF
    8
  • ReF
    8

Square prismatic geometry and cubic geometry

Square prismatic geometry (D4h) is much less common compared to the square antiprism. An example of a molecular species with square prismatic geometry (a slightly flattened cube) is octafluoroprotactinate(V), [PaF8]3–, as found in its sodium salt, Na3PaF8.[6] While local cubic 8-coordination is common in ionic lattices (e.g., Ca2+ in CaF2), and some 8-coordinate actinide complexes are approximately cubic, there are no reported examples of rigorously cubic 8-coordinate molecular species. A number of other rare geometries for 8-coordination are also known.[2]

References

  1. ^ D. L. Kepert (1978). "Aspects of the Stereochemistry of Eight-Coordination". Progress in Inorganic Chemistry. 24: 179–249. doi:10.1002/9780470166253.ch4. ISBN 9780470166253.
  2. ^ a b Jeremy K. Burdett; Roald Hoffmann; Robert C. Fay (1978). "Eight-Coordination". Inorganic Chemistry. 17 (9): 2553–2568. doi:10.1021/ic50187a041.
  3. ^ Wells A.F. (1984) Structural Inorganic Chemistry 5th edition Oxford Science Publications ISBN 0-19-855370-6
  4. ^ Langer, V.; Smrčok, L.; Boča, M. (2010). "Redetermination of Na3TaF8". Acta Crystallographica Section C. 66 (9): pi85–pi86. doi:10.1107/S0108270110030556. PMID 20814090.
  5. ^ Peterson, W.; Holloway, H.; Coyle, A.; Williams, M. (Sep 1971). "Antiprismatic Coordination about Xenon: the Structure of Nitrosonium Octafluoroxenate(VI)". Science. 173 (4003): 1238–1239. Bibcode:1971Sci...173.1238P. doi:10.1126/science.173.4003.1238. ISSN 0036-8075. PMID 17775218. S2CID 22384146.
  6. ^ Brown, D.; Easey, J. F.; Rickard, C. E. F. (1969). "Cubic co-ordination: crystal structure of sodium octafluoroprotactinate(V)". Journal of the Chemical Society A: Inorganic, Physical, Theoretical: 1161. doi:10.1039/j19690001161. ISSN 0022-4944.
  • v
  • t
  • e
Molecular geometry
  • VSEPR theory
  • Coordination number
Coordination number 2
  • Linear
  • Bent
Coordination number 3Coordination number 4Coordination number 5Coordination number 6Coordination number 7Coordination number 8Coordination number 9
  • Category