Scandium(III) hydride

For the scandium–hydrogen alloy, see Scandium hydride.
Scandium(III) hydride
Names
Other names
  • Scandane
  • Scandium(III) hydride
  • Scandium trihydride
Identifiers
43238-07-9 YesY
Jmol interactive 3D Image
PubChem 18172687
Properties
ScH
3
Molar mass 47.97973 g mol−1
Structure
C3v
Trigonal
Irregular tetrahedral
Related compounds
Related scandiums
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Infobox references

Scandium trihydride is an unstable molecular chemical compound with the chemical formula ScH3. It has been formed as one of a number of other molecular scandium hydride products at low temperature using laser ablation and identified by infrared spectroscopy.[1] Scandium trihydride has recently been the subject of DiracHartree–Fock relativistic calculation studies, which investigate the stabilities, geometries, and relative energies of hydrides of the formula MH3, MH2, or MH.

Properties and bonding

Scandium trihydride is a quastrigonal planar molecule with three equivalent Sc-H bonds. (C3v) structure an equilibrium distance between Sc and hydrogen of 182.0 pm, the bond angle is 119.2 degrees. By weight percent, the composition of scandium trihydride is 6.30% hydrogen and 93.70% scandium. In scandium trihydride, the formal oxidation states of hydrogen and scandium are -1 an +3 respectively, because of the electronegativity of scandium is lower than that of hydrogen. The stability of metal hydrides with the formula MH3 (M = Sc-Lu) increases as the atomic number of M increases.[1]

Early theoretical studies of ScH3 revealed that the molecule is unstable, the bulk substance is likely to be a colourless gas with a low activation energy toward the conversion into trimeric clusters due to the electron deficient nature of the monomer, not unlike the group 13 hydrides. One major difference, is that the dimer is the most stable cluster for group 13 hydrides. This can be attributed to the distortion caused by the d-orbitals. It cannot be made by methods used to synthesise BH3 or AlH3.

References

  1. 1 2 Wang, Xuefeng; Chertihin, George V.; Andrews, Lester (13 September 2002). "Matrix infrared spectra and DFT calculations of the reactive MHx (x = 1, 2, and 3), (H2)MH2, MH2+, and MH4 (M = Sc, Y, and La) species". The Journal of Physical Chemistry A 106 (40): 9213–9225. doi:10.1021/jp026166z. Retrieved 27 September 2012.
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