c18 JWBS043-Rogers September 13, 2010 11:29 Printer Name: Yet to Come
PROBLEMS AND EXAMPLES 301
The spectral input to this calculation is the line separation
2 B= 3 .8604 cm−^1 = 386 .04 m−^1
soB= 193 .02 m−^1. This is multiplied bycto obtain the frequency in s−^1 and
bond lengthrin pm:
I=
h
4 π^2 ( 2 Bc)
=
2. 799 × 10 −^44
B
=
2. 799 × 10 −^44
193. 02
= 1. 450 × 10 −^46
r^2 =
1. 450 × 10 −^46
1. 138 × 10 −^26
= 1. 27 × 10 −^20
r= 1. 129 × 10 −^10 m= 112 .9pm
Example 18.2 The Dipole Moment of Sulfur Dioxide
Sulfur dioxide, SO 2 , has a total molar polarization of 68.2 cm^3 mol−^1 at 298 K and
56.0 cm^3 mol−^1 at 398 K. What is the dipole moment of SO 2?
Solution 18.2 The inverse of the lower temperature is 0.00336 and the in-
verse of the upper temperature is 0.00251. The molar polarizations are 68.2 and
56.0 cm^3 mol−^1. The slope of the curve of molar polarization vs. the inverse of
Tis 1. 44 × 104 cm^3 Kmol−^1. (Probably for historical reasons, the nonstandard unit
system of erg cm is often used.) The experimental slope is related to the dipole
moment as
slope=
4 πNAμ^2
9 kB
= 1. 44 × 104
Solving forμ^2 , we get
μ^2 =
9 kB
4 πNA
slope= 1. 641 × 10 −^47
(
1. 44 × 104
)
It is convenient at this point to change the units ofkBfrom J K−^1 to erg K−^1 .This
requires multiplication by 10^7 to give
μ^2 = 1. 641 × 10 −^40
(
1. 44 × 104
)
= 2. 363 × 10 −^36
μ=
√
2. 363 × 10 −^36 = 1. 54 × 10 −^18 = 1 .54 D
Problem 18.1
The molecule^1 H^35 Cl absorbs light atλ= 2. 991 × 10 −^4 cm= 2. 991 × 10 −^6 m. Tak-
ing^1 H^35 Cl to be a harmonic oscillator, what are the differences in energy between