Physical Chemistry Third Edition

(C. Jardin) #1

22.4 The Rotation and Vibration of Polyatomic Molecules 937


symmetry number of BF 3 is 6 (three positions with one side of the molecule upward,
and three more positions with the other side up). For this molecule, only one-sixth
of the conceivable sets of values ofJ,K, andMcan occur. The symmetry number
of methane is 12 (three orientations with each of the four hydrogens upward). Only
one-twelfth of the conceivable sets of values ofJ,M, andKcan occur for methane.

Exercise 22.8
Find the symmetry numbers of the molecules in their equilibrium conformations:
a.Chloroform, CHCl 3
b.Water, H 2 O
c.Benzene, C 6 H 6

Vibrations of Polyatomic Molecules


In a polyatomic molecule there are several bond lengths and bond angles that can
oscillate about their equilibrium values. However, each bond length or bond angle
does not oscillate independently of the others. It turns out that there are collective
motions of some or all of the nuclei that can oscillate independently, callednormal
modes. Determining the normal modes is a complicated process, and we give only a
brief summary.^6 Some software packages such as CAChe and Spartan carry out the
process automatically. We assume that the molecule cannot rotate and is in a fixed
orientation. For the first nucleus, letq 1 be the displacement of the nucleus from its
equilibrium position in thexdirection, letq 2 be its displacement in theydirection,
andq 3 be its displacement in thezdirection. For the second nucleus, letq 4 ,q 5 , and
q 6 be similar displacements, and so on. There are 3nsuch variables if there aren
nuclei.
The Born–Oppenheimer energy acts as the vibrational potential energy. We assume
aharmonic potential energy. That is, we assume that the potential energy depends on
theqvariables in the following way:

EBOV(q 1 ,q 2 ,...,q 3 n)Ve+

1

2

∑^3 n

i 1

∑^3 n

j 1

bijqiqj (22.4-13)

where theb’s are constants. In addition to terms withij, “cross terms” occur in
whichij. The presence of the cross terms make theqcoordinates interfere with
each other so that they do not vibrate independently. Equation (22.4-13) is analogous
to Eq. (22.2-22) and will be a good approximation for small values of theq’s.

z

y

x







Figure 22.5 Three Angles to Spec-
ify the Orientation of a Nonlinear
Polyatomic Molecule.The anglesθ
andφare used to specify the orienta-
tion of one molecular axis. The angleψ
is used to specify the angle of rotation
about this axis.

We now find a transformation to a new set of coordinates such that each new coordi-
nate can oscillate independently from the other new coordinates. The potential energy
function must be given by a formula like that of Eq. (22.4-3) without cross terms.
The number of such coordinates turns out to be smaller than 3n, because the Born–
Oppenheimer energy of the molecule is independent of its location and orientation.
Three coordinates can be used to specify the location of the center of mass of the
molecule. For a linear or diatomic molecule, two angular coordinates specify the orien-
tation of the molecule. For a nonlinear molecule, three angular coordinates are required
to specify the orientation of the molecule, as shown in Figure 22.5. The anglesθand
φspecify the direction of an axis (as in spherical polar coordinates) and the angle
ψspecifies the angle of rotation about this axis. The Born–Oppenheimer energy can

(^6) E. B. Wilson, Jr., J. C. Decius, and P. C. Cross,Molecular Vibrations, McGraw-Hill, New York, 1955.

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