used the energy of the unfilled orbitals to pr
edict relative electronegativities in Chapter 3!
Using the relative energies of atoms X, A, B, and C in Figure 6.24, we conclude that atom C is the most electronegative atom and atom A is the least electronegative. The bond dipole of the AX bond points toward atom X beca
use X is more electronegative than A,
but it points toward atom C in the XC bond because atom C is more electronegative than atom X. Example 6.8
Indicate which representation best describes the interaction of p orbitals in each of the following O-X bonds. Assume the oxygen orbital is on the left in each case.(a)
(b)
(c)
O-F bond Oxygen is less electronegative than fluorine, soits p orbital is higher in energy and wouldcontribute less to the MO. Figure (a) would be the best representation.Note that the sizeof the p orbital in the MO indicates the contribution to the MO, notthe size of the atom.Oxygen is larger than F, but itcontributes less to the MO, so its p orbital is shown smallerin the figure. O-N bond Oxygen is more electronegative than nitrogen,so its p orbital is at lower energy wouldcontribute more to the MO. Figure (c) would be the best representation. O-O bond The atoms are identical, so their contributionswould be identical as shown in Figure (b).MOs FOR SIMPLEπ SYSTEMS
So far, we have discussed the MO’s formed by interacting only two atoms, but all of the atoms in a molecule can be involved in a si
ngle MO. Computers are used to determine the
MO’s of complicated molecules, so we limit our discussion to the
MO’s of some simple π
molecules to show how MO theory deals
with delocalized bonds. The discussion also
points out the importance of symmetry in molecular systems.
The number and placement of the nodal planes is the key factor in generating the
(^) π
MOs in the systems we will examine. In th
e following rules for creating MO’s, we use N
to denote the number of AOs used to construct the MOs.
Chapter 6 Molecular Structure & Bonding
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