23.3 Rotational and Vibrational Spectra of Diatomic Molecules 969
Fourier Transform Infrared Spectroscopy
Most modern infrared spectrometers use Fourier transform techniques rather than dis-
persion techniques. In a Fourier transform infrared spectrometer a pulse of infrared
radiation is passed through aninterferometer, as depicted in Figure 23.10.^9 The beam
splitter divides the beam into two beams of equal intensity, which are recombined after
being reflected by separate mirrors, one of which is movable. As this mirror moves, the
detector responds to changes in the intensity as the two beams interfere constructively
or destructively. The intensity of the pulse as a function of time is called aninterfero-
gram. As depicted in the figure, a single frequency produces a sinusoidal interferogram.
A pulse can be thought of as containing many frequencies, and an interferogram can
have a complicated appearance depending on the intensities of the various frequencies.
An interferogram is taken without a sample in position and another is taken with
the sample in position. The difference between the interferograms is a function of time
and can be represented by aFourier transform:
I(t)
1
√
2 π
∞∫
−∞
c(ω)eiωtdω (23.3-14)
Appendix B contains a brief introduction to Fourier series and transforms. Equation
(23.3-14) is analogous to a linear combination of basis functions, but with an integration
instead of a sum. The variableωis sometimes called the “circular frequency” of the
Fixed-position mirror
Beamsplitter
Sample
position
Detector
Single-frequency
source ()
Movable
mirror
5 0
I()
5 2
2
0 3
2
5 532
n 5~^1
n
c(n)
Spectrum
Interferogram
~n 0
~
~
Figure 23.10 The Radiation Path in a Fourier Transform Infrared Spectrophotometer
(Schematic).If only one wavelength is present, the sinusoidal interferogram at the lower
right is observed as the movable mirror in the Michelson–Morley interferometer changes its
position. The Fourier transform of this signal is a single sharp line, as shown at the lower
left. From W. D. Perkins,J. Chem. Educ., 63 , A5 (1986).
(^9) W. D. Perkins,J. Chem. Educ., 63 , A5 (1986); and 64 , A296 (1987).