Three-center four-electron bond

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The 3-center-4-electron bond is a model used to explain bonding in hypervalent molecules such as phosphorus pentafluoride, sulfur hexafluoride, the xenon fluorides, and the hydrogen difluoride ion.^[1]^[2] It is also known as the Pimentel-Rundle three-center model after the work published by George C. Pimentel in 1951,^[3] which built on concepts developed earlier by Robert E. Rundle for electron-deficient bonding.^[4]

The model considers bonding of three colinear atoms. For example in XeF₂, the linear F-Xe-F subunit is described by a set of three molecular orbitals (MOs) derived from colinear p-orbitals on each atom. The Xe-F bonds result from the combination of a filled p orbital in the central atom (Xe) with two half-filled p orbitals on the axial atoms (F), resulting in a filled bonding orbital, a filled non-bonding orbital, and an empty antibonding orbital. The two lower energy MO's are doubly occupied. The HOMO is localized on the two terminal atoms. This localization of charge is accommodated by the fact that the terminal ligands are highly electronegative in hypervalent molecules. The molecules PF₅ and SF₄ are described, according to this model, as having one 3-center-4-electron bond as well as three and two other more conventionally described bonds, respectively. In SF₆ and in the xenon fluorides, all bonds are described with the 3-center-4-electron model.

Bonding in the hypervalent molecule XeF2 according to the 3-center-4-electron bond model.

Bonding in the hypervalent molecule XeF₂ according to the 3-center-4-electron bond model.

The bonding in XeF₂ can also be shown qualitatively using resonant Lewis structures as shown below:

In this representation, the octet rule is not broken, the bond orders are 1/2, and there is increased electron density in the fluorine atoms. These results are consistent with the molecular orbital picture discussed above.

Older models for explaining hypervalency invoked d orbitals. As of 2008, these models still appear in some beginning level college texts; however, quantum chemical calculations suggest that d-orbital participation is negligible due to the large energy difference between the relevant p (filled) and d (empty) orbitals. Furthermore, a distinction should be made between "d orbitals" in the valence bond sense and "d functions" that are included in the QM calculation as polarization functions.^[5] The 3-center-4-electron bonding model has the advantage of dispensing with the need for d orbitals, which has led to its acceptance.^[6]

References

^ Greenwood, N. N.; Earnshaw, A. (1997). Chemistry of the Elements, 2nd Edition, Oxford:Butterworth-Heinemann. ISBN 0-7506-3365-4. p. 897.
^ Weinhold, F.; Landis, C. Valency and bonding, Cambridge, 2005; pp. 275-306.
^ Pimentel, G. C. The Bonding of Trihalide and Bifluoride Ions by the Molecular Orbital Method. J. Chem. Phys. 1951, 19, 446-448. doi:10.1063/1.1748245
^ Rundle, R. E. Electron Deficient Compounds. II. Relative Energies of "Half-Bonds". J. Chem. Phys 1949, 17, 671-675.doi:10.1063/1.1747367
^ E. Magnusson. Hypercoordinate molecules of second-row elements: d functions or d orbitals? J. Am. Chem. Soc. 1990, 112, 7940-7951.
^ Ramsden, C. A. Non-bonding molecular orbitals and the chemistry of non-classical organic molecules. Chem. Soc. Rev. 1994, 111-118.

v • d • e

Chemical bonds

"Strong"

Covalent bonds & Antibonding	Sigma bonds: 3c-2e (bent bond) · 3c-4e (Hydrogen bond, Dihydrogen bond, Agostic interaction) · 4c-2e Pi bonds: π backbonding · Conjugation · Hyperconjugation · Aromaticity · Metal aromaticity Delta bond: Quadruple bond · Quintuple bond · Sextuple bond Coordinate covalent bond · Hapticity

Ionic bonds	Cation-pi interaction · Salt bridge

Metallic bonds	Metal aromaticity

"Weak"

Hydrogen bond	Dihydrogen bond · Dihydrogen complex · Low-barrier hydrogen bond · Symmetric hydrogen bond · Hydrophile

Other noncovalent	van der Waals force · Mechanical bond · Halogen bond · Aurophilicity · Intercalation · Stacking · Entropic force · Chemical polarity

other

Disulfide bond · Peptide bond · Phosphodiester bond

Note: the weakest strong bonds are not necessarily stronger than the strongest weak bonds

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This page was last modified on 10 July 2008, at 09:54.

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