996 23 Optical Spectroscopy and Photochemistry
The specific rotation often has different signs for two wavelengths between which a
spectral line occurs. Specific rotations of many substances have often been tabulated for
a single wavelength, usually the yellow sodium “D lines” at 589.0 and 589.6 nm, and the
wavelength dependence has often been ignored. However, additional information about
the stereochemical configuration of molecules can be obtained from the dependence of
the specific rotation on wavelength, which is calledoptical rotatory dispersion(ORD).
The absorptivity of an optically active substance can also differ for right-polarized
and left-polarized photons. This phenomenon is calledcircular dichroism(CD), and
is also studied as a function of wavelength. Until the 1970s, only ultraviolet and vis-
ible light were used for ORD and CD. Since then techniques have been developed
for infrared circular dichroism spectroscopy, which is usually calledvibrational circu-
lar dichroism(VCD). In addition, techniques have been invented for determining the
differences in scattering of left- and right-polarized light, and Raman optical activity
(ROA) is now being studied.^28
In addition to the types of spectroscopy that we have discussed, many other types
and techniques of spectroscopy have been developed. A lot of work is being done in
making rapid spectroscopic observations to study molecular species that have short
lifetimes. Almost any issue ofThe Journal of Chemical Physicsor theJournal of
Physical Chemistrycontains one or more articles reporting on spectroscopic techniques
that we have not discussed.
PROBLEMS
Section 23.8: Other Types of Spectroscopy
23.51By analogy with the photoelectron spectrum of N 2 ,
predict what the photoelectron spectrum of O 2 would
look like.
23.52By analogy with the photoelectron spectrum of N 2 ,
predict what the photoelectron spectrum of C 2 would
look like.
Summary of the Chapter
Electromagnetic radiation that is absorbed or emitted by atoms or molecules gives
information about energy level differences through the Bohr frequency rule
Ephotonhν
hc
λ
Eupper−Elower
Each pair of energy levels does not necessarily lead to a spectral line for emission
or absorption. Selection rules tell whether a transition with emission or absorption of
radiation can occur between a given pair of energy levels.
Transitions between rotational states lead to emission or absorption in the microwave
region. For diatomic and linear polyatomic molecules with permanent dipole moments,
the selection rule is
∆J± 1
(^28) S. C. Stinson,Chem. Eng. News, 63 (45), 21 (Nov. 11, 1985).