Bonding and Geometry of OCF(3)(-), ONF(3), and Related Molecules in Terms of the Ligand Close Packing Model.

Abstract

The nature of the bonding in OCF(3)(-) and the isoelectronic molecule ONF(3) has been the subject of much discussion for many years, because these species appear to have unusual bond lengths and angles. We have reinvestigated the nature of the bonding in these and some related molecules by analyzing their calculated electron density distributions. The results show that the bonding in the series OBF(3)(2)(-), OCF(3)(-), ONF(3) ranges from predominately ionic in OBF(3)(2)(-) to predominately covalent in ONF(3) and that the interligand distances are consistent with the close packing of the ligands around the central atom. The AO bonds (A = B, C, N) are double bonds ranging in nature from a very ionic B=O bond to a predominately covalent N=O double bond, but all three are strong and short so that, in accordance with the ligand close packing (LCP) model, the AF bonds are correspondingly long. Also consistent with this model the bonds in a three-coordinated AOF(2) molecule are shorter than those in the corresponding AOF(3) molecule. Protonation of the doubly bonded oxygen, which converts the A=O bond to a single A-OH bond in each case, considerably lengthens the A-O bond, and the bond angles accordingly adopt values much closer to the tetrahedral angle. The difficulties of trying to describe the bonding in these molecules in terms of Lewis structures are discussed.