Valence-Shell Electron-Pair Repulsion (VSEPR) Model
Considerations in Apply the Model
The bond angles for highly symmetric molecules are usually nice round numbers such as 90° or 120°. If one or more of the electron groups in the VSEPR Model is a lone pair, the molecule may have lower symmetry. In this case, the bond angles might be slightly different from those for highly symmetric molecules.
For example, water has NEG = 4, which corresponds with a tetrahedral arrangement of electron groups. Two of the electron groups are lone pairs and two are σ bonds to hydrogen atoms. For perfect tetrahedral geometry, the bond angle is cos-1(-⅓) = 109.5°. However, the experimental H-O-H bond angle in water is 104.5°.
Fortunately, such deviations are easily understood and predictable based upon the three considerations explained below. Note that these concepts lead to only qualitative (not quantitative) predictions.
1. Lone Pairs Occupy More Space than Bonding Pairs
When a pair of electrons is confined to a σ bonding orbital, the electron density is concentrated in the region between the bonded atoms.
A lone pair of electrons, however, is associated with a single atom and occupies more space around the atom.
Because a lone pair of electrons requires more space than a bonding pair, the molecular geometry distorts to afford the lone pair more room, with the result that bond angles are smaller than those of the ideal geometry.
In the case of water, the two lone pairs push the bonding pairs closer together, yielding a smaller bond angle. The white lines shown at right display the ideal 109.5° angle. The experimental H-O-H bond angle is only slightly smaller, but the effect is noticeable.
The VSEPR Model does not allow one to predict how much smaller the bond angle will be, only that the the HOH bond angle is < 109.5°.Ideal Bond Angle: 109.5° (white lines)
Experimental Bond Angle: 104.5°
This effect is clearly observed by comparison of the F-P-F bond angles in PF3 and OPF3. The white lines in the boxes below show the ideal bond angle of 109.5°.
In PF3 the lone pair on the phosphorus pushes the P-F bonding electrons away from itself, resulting in a F-P-F bond angle of 97.8°, which is appreciably smaller than the ideal bond angle of 109.5°.
In OPF3, the lone pair is replaced with a P-O bond, which occupies less space than the lone pair in PF3. Consequently there is less distortion of the P-F bonds, and the F-P-F bond angle is 107°. (The P=O bond occupies only slightly more space than a P-F bond.)
Ideal F-P-F Bond Angle: 109.5° (white lines)
Experimental F-P-F Bond Angle: 97.8°
Ideal F-P-F Bond Angle: 109.5° (white lines)
Experimental F-P-F Bond Angle: 107°
2. Avoid 90° Interactions between Lone Pairs
Because lone pairs occupy more space than σ bonding pairs, locate lone pairs in positions with the most space. The greatest source of repulsion is from 90° interactions. 120° interactions involve very little repulsion, even for lone pair - lone pair interactions.
First Priority: Minimize 90° lone pair - lone pair repulsions.
Second Priority: Minimize 90° lone pair - σ bonding pair repulsions.
The trigonal bipyramidal geometry (NEG = 5) has two different sites: axial and equitorial. There is more room in the equitorial positions, because there are only two 90° interactions (with the axial positions). Each axial position has three 90° interactions. 90° interactions are very strong; 120° interactions are much weaker. For this reason, lone pairs occupy equitorial positions.
PCl5 has NEG = 5 and no lone pairs, consequently the molecule has a perfect trigonal bipyramidal geometry, as seen at left below.
SF4 also has NEG = 5, but in this case there is a lone pair. The lone pair is placed in an equitorial position. Because the lone pair occupies more space than bonding pairs in the molecule, the bond angles are all smaller than for PCl5.
Equitorial-Equitorial Cl-P-Cl Bond Angle: 120°
Equitorial-Axial Cl-P-Cl Bond Angle: 90°
Experimental Equitorial-Equitoral F-P-F Bond Angle: 103.8°
Experimental Equitorial-Axial F-P-F Bond Angle: 88.4°
3. Think Creatively about Hybridization
The most basic hybridization scheme for ammonia (NH3) involves mixing the nitrogen atomic 2s, 2px, 2py, and 2pz orbitals to yield a new set of sp3 hybrid atomic orbitals. Each orbital is equivalent and oriented at the corners of a tetrahedron. One can think of a sp3 hybrid orbital as having 25.0% s character and 75.0% p character.
However, it is not necessary for each of the hybrid orbitals to be equivalent or that the s and p orbitals need be combined in integer proportions. (Recall that hybrid orbitals are just mathematical functions constructed from the the mathematical functions for the native s, p and d orbitals.)
For a molecule like CH4, it makes sense that each hybrid orbital has identical s and p character, because each hybrid orbital is involved in an identical C-H bond. But for NH3, the hybrid orbital accommodating the lone pair might be expected to have a different composition than the hybrid orbitals associated with the N-H bonds. As the formulation of the hybrid orbitals differ from sp3, the geometries of the orbitals differ from tetrahedral.
The results of ab initio quantum mechanical calculations (mp2/cc-pTVZ) for NH3, PH3 and AsH3 are shown in the table to the right. The hybrid orbitals are constructed from the NBO formalism.
For NH3, the hybrid orbitals for both the bonding pairs and lone pairs are each very close to sp3, which predicts a trigonal pyramidal geometry with 109.5° bond angles. Note, though, that the nitrogen lone pair has slightly more s character and slightly less p character than the σ bonding orbitals, consistent with the lone pair occuping more space than a σ bonding pair.
As the central atom changes from N to P to As, the hybrid orbital for the lone pair has more and more s character and less and less p character. Conversely, the hybrid orbitals used for bonding have more and more p character. In fact, the H-As-H bond angle of 91.8° is close to the 90.0° expected for pure p character (that is, no hybridization at all).
The small size of the hydrogen atom (and hence σ bonds to it) and the relatively large size of phosphorus and arsenic result in little repulsion between the bonding electron groups, even when at 90°. The molecular geometries are all trigonal pyramidal, as predicted by the VSEPR Model, but the bond angles are much smaller than 109.5°.
| Property | NH3 | PH3 | AsH3 | |
|---|---|---|---|---|
| Bond Hybridization | s character | 25.2% | 15.8% | 14.4% |
| p character | 74.7% | 83.2% | 85.0% | |
| hybridization | sp2.97 | sp5.25 | sp5.91 | |
| Lone Pair Hybridization | s character | 24.5% | 52.4% | 56.8% |
| p character | 74.7% | 83.2% | 85.0% | |
| hybridization | sp3.09 | sp0.91 | sp0.76 | |
| Bond Length (Å) | calculated | 1.011 | 1.412 | 1.500 |
| experimental | 1.015 | 1.42 | 1.519 | |
| Bond Angle | calculated | 105.9° | 93.7° | 92.8° |
| experimental | 106.6° | 93.8° | 91.83° | |
H-N-H Bond Angle: 106.6°
H-P-H Bond Angle: 93.8°
H-As-H Bond Angle: 91.83°
© Copyright 2012, 2014, 2023 David N. Blauch