24 CHAPTER 1 Electronic Structure and Bonding • Acids and Bases
p atomic orbital
of oxygenp atomic orbital
of carbonπ∗ antibonding molecular orbitalπ bonding molecular orbitalEnergyFigure 1.8N
Side-to-side overlap of a porbital of
carbon with a porbital of oxygen
to form a bonding molecular
orbital and a antibonding
molecular orbital.
p*pNow let’s look at the molecular orbital diagram for side-to-side overlap of a por-
bital of carbon with a porbital of oxygen—the orbitals are the same, but they belong
to different atoms (Figure 1.8). When the two patomic orbitals combine to form mo-
lecular orbitals, they do so unsymmetrically. The atomic orbital of the more electro-
negative atom contributes more to the bonding molecular orbital, and the atomic
orbital of the less electronegative atom contributes more to the antibonding molecular
orbital. This means that if we were to put electrons in the bonding MO, they would be
more apt to be around the oxygen atom than around the carbon atom. Thus, both the
Lewis theory and molecular orbital theory tell us that the electrons shared by carbon
and oxygen are not shared equally—the oxygen atom of a carbon–oxygen bond has a
partial negative charge and the carbon atom has a partial positive charge.
Organic chemists find that the information obtained from MO theory, where valence
electrons occupy bonding and antibonding molecular orbitals, does not always yield the
needed information about the bonds in a molecule. The valence-shell electron-pair
repulsion (VSEPR) modelcombines the Lewis concept of shared electron pairs and
lone-pair electrons with the concept of atomic orbitals and adds a third principle:the
minimization of electron repulsion. In this model, atoms share electrons by overlappingppp ppp
Enegryσσ∗π∗ π∗ππFigure 1.7N
pOrbitals can overlap end-on to
form bonding and
antibonding molecular orbitals, or
can overlap side-to-side to form
bonding and antibonding
molecular orbitals. The relative
energies of the molecular orbitals
are s 6 p 6 p 6 s.
p*ps s*