20.4 Heteronuclear Diatomic Molecules 853
2 p
2 s
1 s
Li atomic
orbitals
Molecular
orbitals
H atomic
orbitals
1 s
2
1
3
Orbital energy (schematic)
Figure 20.14 Correlation Diagram for the Lithium Hydride Molecule.
nonbonding electrons and two bonding electrons for a single bond, in contrast with the
He 2 molecule, which has two bonding and two antibonding electrons, for a bond order
of zero.
Hybrid Orbitals
We would like to have a simple method of predicting roughly what an optimized
orbital wave function for a given molecule should be without doing any calculations.
The SCF results for LiH suggest a pattern that we can use for such predictions. We
want to construct a wave function that is approximately the same as that of Eq. (20.4-5)
but contains linear combinations of no more than two atomic orbitals.
The 1σLCAOMO is nearly the same as the 1slithium orbital, so we replace this
LCAOMO by the 1slithium orbital, a nonbonding orbital. The 2σorbital contains
three atomic orbitals with coefficients that are appreciably nonzero. The coefficients
of the 2slithium and 2pzlithium orbitals in the 2σLCAOMO are roughly the same
magnitude with opposite signs. To a usable approximation, we will replace these two
atomic orbitals by ahybrid atomic orbital:
ψ 2 sp(1)c 1 (−ψ 2 s+ψ 2 pz) (20.4-6)
wherec 1 is a normalizing constant that can be shown to be equal to
√
1 /2. The desig-
nation 2spmeans that the new atomic orbital is a linear combination of the 2sanda2p
orbital, and the 1 subscript indicates that this is the first orbital of this type. Since we
can define two independent linear combinations from two functions, there is another
2 sphybrid orbital:
ψ 2 sp(2)c 2 (−ψ 2 s−ψ 2 pz) (20.4-7)