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Surface raman ellipsometry
Journul of Electron Spectroscopy and Related Phenomena, 30 (1983) 43-50 Elsevier Scientific
Publishing Company,
FOURIER TRANSFORM SURFACE SPECIES
INFRARED
Amsterdam
43
- Printed in The Netherlands
REFLECTION-ABSORPTION
SPECTROSCOPY
OF
William G. Golden and David 0. Saperstein IBM INSTRUMENTS, INC., San Jose, CA
ABSTRACT We have been able to demonstrate progress in Fourier Transform Infrared Reflection-Absorption Spectroscopy (FT-IRRAS) by incorporating a switching circuit into the data acquisition electronics of an air-equilibrated IBW IR/98 FTIR Spectrometer such that it is possible to obtain simultaneously both reference and polarization modulated spectrum. These spectra ratio to produce good discrimination against gas-phase species. The operating principles of this approach and sample FT-IRRAS spectra of monolayer assemblies of cadmium arachidate adsorbed on silver will be discussed. INTRODUCTION The advantages conventional infrared further
of Fourier Transform
dispersive
techniques
spectroscopic the potential
Several
take advantage
described
by Greenler
Absorption
Spectroscopy
to achieve
improved
in ultrahigh
of the so-called
successful
for dispersion
modulation
grazing
monolayers
(7-14).
These
in dispersion
infrared,
Infrared
infrared range
technique
in dynamic
incidence
Infrared
photoelastic
(10).
circular
0368-2048/83/0000~000/$03.00
(PEM)
have
dichroism
(16,17) ratio
FTIR. our present efforts
monolayers
in the area of
Spectroscopy
of cadmium
arachidate
The spectra were recorded
modulator
modulators workers
range and signal-to-noise
open to the air, i.e. with atmospheric
using a ZnSe photoelastic
Several
Reflection-
to FTIR using the techniques
Reflection-Absorption
on silver are shown.
spectrometer
systems
rules first
IRRAS and vibrational
improvements
of Langmuir-Blodgett
assemblies
vacuum
incidence
selection
dynamic
In this paper we will describe
Spectra
i.r. at grazing
surface
(IRRAS),utilizes
instrumental
the photoelastic
Fourier Transform
to investigate
science applications.
(15).
One of the methods
over conventional
in a wide area of
spectra of thin films (l), Langmuir-Blodget established
efforts,
developed
(FTIR) over
the need exists
have used FTIR and dispersive
(2-6) and monolayers
and have demonstrated
However,
for FTIR in surface
workers
Spectroscopy
have long been utilized
applications.
to obtain vibrational
adapted
Infrared
(CdAA)
with the
CO2 and H20 present,
in the IBM IR/98.
0 1983 Elsevier Scientific
(FT-IRRAS).
New signal handling
Publishing Company
44 techniques acquired
are described
wherein
the sample and reference
spectra are
simultaneously.
EXPERIMENTAL The experimental modulation
technique
of the intensities of the reflected ratioed
approach
for dispersive
in which,
of the parallel
randomly
oriented oriented
modulation
dipole absorbances
involves
tional rotating of modulation
blade chopper
signals of interest. In FTIR,single
Michelson
interferometer
the Genzel design. mathematically
possible
separate
less than 10 KHz, it is quite possible dispersive
double modulation
Figure la depicts technique.
Other configurations
ventional
grazing
described
here (2-14).
were readily
incidence
available
easily within polarizer
experiment
the optical
in the usual fashion
to emulate,
utilizing
to produce
(19).
polarization
of operation
is then focused at grazing monolayer
of these devices
assembly
The signal from the detector Each channel
passed through
the conventional
preamplifier
is demodulated
monolayerc
could be performer' gold wire grid
modulator
were combined
infrared radiation.
(80°+
by using a standard
FTIR ac amplifier
(20).
5') onto the variable
signal processing is physically
separately.
con-
to the methods
can be found elsewhere
incidence
chopper.
for obtaining
A Perkin-Elmer
retro mirror assembly (Harrick Scientific). Figure lb shows a schematic of the FT-IRRAS
two channels.
a separate
applicable
modulated
can be
the
to test this FT-IRRAS
Langmuir-Blodgett
ZnSe photoelastic
The principles
ment.
Since PEM's operate for the mid-IR
(18) and so the entire experiment
International
it is
in many respects,
adopted
IRRAS and are equally
In this case, however,
This radiation
Langmuir-Blodgett
(16).
have been d~onstrated
the FTIR sample chamber
and Hinds
frequency,
modulation
without
e.g. is
into the FTIR system, at a
experiment
arrangement
which
to produce the infrared
modulation
at ca. 50 to 100 KHz while the interferometer
produced
variations,
an interferogram
modulator
larger than the interferometer
(10).
in either a conventional
interferometer
produces
by the Fourier Transform
to produce a double modulation
of the
in analog mode
from the interferogram
or in one of several
a photoelastic
frequencies
demodulation
to a fixed mirror
of
(PEM) and a conven-
such that their respective
This mirror motion
By introducing
spectrum.
which
IRRAS this double
is produced and recorded
relative
demodulated
frequency much
chosen
modulator
beam spectra are obtained
of a mirror
(Ip-Is/Io+IS)in
In dispersive
enough to allow
The ratio
(I,) components
These signals are then
divide out leaving only the spectrum normal.
the use of a photoelastic
are different
by the motion
are collected. beam spectrum
along the surface
a double
both the sum and difference
(Ip) and perpendicular
infrared radiation
to produce a psuedo-double
dipoles
IRRAS incorporates
in analog mode,
angle arrange-
split into
The signal which
and filter circuits,
is
Ipf Is,
45 PFM
_...
switch to circuit zmple
-
and hold and AID
FTIR amplifiers
(b)
Fig.1. (a) Optical configuration of the PEM, polarizer, retro mirror attachment, and KBr plate in the IR/98 sample chamber; (b) schematic of the signal-handling electronics for simultaneous digitization of numerator and denominator signals. hereafter
called
contains
the denominator,
is first demodulated
numerator,
to produce an interferogram
the usual single
The other channel,
of the sample plus spectrometer.
with a phase sensitive
whose amplitude
beam interferogram
hereafter
called
amplifier
is proportional
the
(lock-in)
to Ip- Is.
A
high-pass filter is also employed to remove the large dc offset associated with this signal. is necessary
of the lock-in
amplifier,
time to respond by choosing
the lowest
sufficient
changes
feasible
numerator
interferogram,
dc output, must
lock-in
amplifier
position
cycles must
output
have sufficient This is accomplished
time Constant.
of the interferometer,
be accumulated
2)
a
to produce an accurate
of the value of (Ip-Is).
fashion
utilized
computer
an analog
is changed
and denominator
it is then necessary
spectrometer's
memory.
switch,
at each digital
laser interferometer)
channels
have been produced
to input both signals
The approach
viz. Fig. lb.
here is to
The state of the analog
data point (derived
such that numerator
produces,
in one mirror
data file which contains the digital ferograms
alternately
is this switching both sample
(numerator)
final sequence
and denominator
in either
signal amplitudes
software
This
an interferometer
information,
and denominator
i.e.
inter-
even or odd data addresses.
which allows
and reference
file to produce
and denominatol
has both numerator
of the data handling
the use of conventional the original
stored
technique
switch
from the FTIR's reference
scan of the interferometer,
both numerator
data file produced
in the
into the FTIR
we have adopted
are sent to the FTIR input (sample and hold and A/D) alternately. ideally
it
1) the output
because:
slowly,
of the interferogram.
step in the mirror
number of modulator
Once the numerator above
mirror
being a filtered
to amplitude
For each digitized
average
In order to produce a reliable
to scan the interferometer
for simultaneous
(denominator)
of this dual
collection
interferogram.
interferogram
It of The
involves
to split out the even and odd data from
two new files, each containing
one half of
46 the total number of data points recorded. interferograms
These numerator
are then Fast Fourier Transformed
and denominator
and ratioed
in the usual
fashion. The CdAA monolayer
assemblies
of their ease of fabrication are well characterized prepared
(no vacuum
systems
(3,4).
by the Langmuir-Blodgett
monolayer
were chosen
always established
system
to test the technique is required)
and because they
All of the CdAA assemblies
dipping
technique
with the carboxyiate
because
were
(21,22) with the first
group closest
to the Ag
substrate. The interferograms spectrometer 100 mirror against
at 4 cm
were recorded
-1
resolution
scans were co-added
the FT-IRRAS
spectrum
time was approximately
at an optical
all spectra
are obtained conditions.
Inc.
IR/98
of 0.235 cm/set.
spectrum
and then ratioed
Data acquisition
of a clean Ag substrate.
technique
atmospheric
velocity
for each FT-IRRAS
Since one of the goals of this work is
4 minutes.
to devise an FT-IRRAS
with an IBM Instruments,
which
is insensitive
with the spectrometer
to gas phase absorptions,
completely
open to ambient
RESULTS Figure 2 shows the polarization six monolayer
noted.
CdAA sample before ratioing
The presence
(Ip+Is).
modulation
against
spectrum
are removed
The resultantspectrumfor
by ratioing
six monolayers
the denominator
along with the spectrometer's numerator to denominator
carboxylate
stretch,
-1 , the asymmetric carboxylate the weaker band, at 1577 cm consistent
with the surface
is oriented
selection
rules,
spikes,
in Figure 3a,
spectra.
and
stretch,
i.e. the carboxylate
with its local C2 axis along the surface
sharp downward
spectrum should be
of CdAA is shown in Figure 3a.
band at 1432 cm -l, the symmetric
The strong
(Ip-Is) of the
of strong water vapor and CO2 absorbances
These unwanted gas phase absorptions
background
spectrum
due to water
normal
are group
(23).
The
vapor, arise from the
fact that when the original
interferogram
file is split into numerator
denominator
the amplitude
of the two are not equal.
amplitude
interferograms,
difference
When ratioed
is carried
these amplitude
to water vapor absorption For the purposes technique,resolution the spectral resolution
through
differences
spectra.
small errors corresponding
was decreased
the present capability in order to provide
errors due to gas-phase
and ratioing
produce
maxima.
of evaluating
that when the resolution
the FFT into the calculated
and
This
error
absorption.
is illustrated
is decreased
of the FT-IRRAS
better ratioing
This trade-off
of
between
in Figures 3b and 3c. Note -1 a substantial
(in the FFT) to 8 cm
41
Fig.2. Single beam polarization modulated spectrum of six monolayers of cadmium arachidate on silver. The large absorbances are due to carbon dioxide and water vapor present in the unevacuated spectrometer. improvement
in spectral
information
(e.g. the CH2 wag and twist progression
error
are not as well resolved). completely
is obtained,
-1 bands near 1321 cm -1 the data digitally to ca. 10 cm
Smoothing
blends the progression
but at a loss in spectral
bands but produces
a spectrum
with usable
signal-to-noise. Vonolayer
sensitivity
taking spectra resolution. symmetric
(1439 cm-') and asymmetric
was investigated
spectrum.
by -1
As in Figure 3, the
(1552 cm-') carboxylate
stretching
bands
seen.
In Figure 5 clearly
the FT-IRRAS
contamination
spectrum
of one monolayer
the presence of the symmetric
However,
stretches.
the broad downward
of the reference
Ag substrate
of CdAA on Ag, also
and asymmetric
features
it is clear that signal-to-noise
Otherwise, monolayer
technique
samples of CdAA on Ag at 10 cm
Figure 4 shows the two monolayer
are easily
exhibits
of the FT-IRRAS
of two and one monolayer
carboxylate
in this spectrum
by ambient ratio
are due to
hydrocarbons.
is sufficient
for sub-
spectroscopy.
One other
experimental
to FTIR instrumentation. calculated, is dependent
the apparent
result Because
is discussed
here as it is
peculiar
of the way in which the spectrum
sign of absorption
on the sign of the quality
bands due to surface
(Ip-Is).
is
species
This is because,
in the
48 (b)
fal 2
1432
I $3-4 Ip+l,
5%
1321
1577
I ' Jcx,
'a21
L
m
1
I
12DO 61 D 30 1600 UAVCNull8Lns en-1
2
21
Fig.3. FT-IRRAS spectrum of six monolayers of cadmium arachidate on Ag; calculated at 4cm-1 resolution a {b) calculated at 8 cm-1 resolution C calculated at 8 cm-l resolutio; and smoothed to ca. 10-l resolution: I{ computation computed
algorithm,
spectrum)
represented
the spectrum.
value of the interferogram
is taken so that all single beam spectra
as positive
which affect
component
the absolute
energy spectra.
Ip and Is equally
absorbed,
always
show positive
in the case where
However,
Consequently,
are stored and
all absorptions
normal absorption
in
Ip is the only polarization
the sign of the apparent
absorption
When Ip
on the sign of (Ip-Is).
(or the
1439
-
peak will depend will yield an apparent
1439
I
-1 Ip-‘S 'P + ‘s
1%
1552
I
IP -
1s
'P + 4
1320
Fig.4. FT-IkRAS spectrum of two Fig.5. FT-IRRAS spectrum of one _1 monolayers of CdAA on Ag calculated monolayer of CdAA on Ag at ca. 10 . at 8 cm-l and smoothed to ca. 10 cm-l.
49 "negative
pretation
For the case when Ip>>Is,
absorption."
will occur.
When
Ip>Is
is difficult.
considerations. illustrates
a discontinuity This effect
Table 1 summarizes
these rules
is due entirely these sign rules
By utilizing
(viz. Figure l.), the s ign of (Ip-Is)
normal
positive
will occur and spectral
absorption inter-
to instrumental for FT-IRRAS.
a KBr plate in the optical can be changed
(lo).
Figure
5
beam
Figure 6a shows
Fig.6. FT-IRRAS spectra of six monolayers of cadmium arachidate on Ag showing the dependence of the sutface species absorption on the sign od lip-Is); (a) Ip>Is, (b) Ip
of six monolayers
of CdAA when Ip>I s; Figure 6b is a spectrum
of the same sample but for f
1
FT-IRRAS
Sign of (IpcIsf:
RULES FOR THE SIGN OF ABSORPTION Apparent
BANDS
Sign of the Absorption
Band for:
Gas Phase Species
Surface
Positive
Negative-Linear with absorbance
+
Positive
Positive-Linear with absorbance
0
Positive
Not observed
Species
50 CONCLUSION We have demonstrated spectra of monolayer and sensitivity an understanding with doing
here the feasibility
of the special
surface absorptions;
the utilization
of the interferograms
of mirror
considerations
relaxes
surface
In addition,
has led to a useful rule for
from non-surface
of the switch circuit the constraints
since signal averaging
resolution
associated
rules for the sign of a surface absorption
an easy test for distinguishing
stability,
instrumental
FT-IRRAS
with reasonable
in a short period of time (ca. 4 minutes).
IRRAS with FTIR spectrometers
Finally,
of obtaining
amounts of surface species
bands.
in the data acquisition
associated
can be performed
provide
absorption
with experimental
to any desired
number
scans.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9.
P. A. Chollet, Thin Solid Films 52, 343 (1978), (b) R. G. Greenler, J. Chem. Phys. 50, 1963 (1968). 0. L. Allara and J. D. Swalen, J. Phys. Chem. 3, 2700 (1982). F. A. Burns, N. E. Schlotter, J. F. Rabolt and J. D. Swalen, IBM Instruments, Inc., Application Note No. 1 (1981). T. Ohnishi, A. Ishitani, H. Ischida, N. Yamamoto and H. Tsubomura, J. Phys. Chem. 82, 1989 (1978). W. Knoll, M. R. Philpott and W. G. Golden, J. Chem. Phys. 77_, 219 (1982). W. G. Golden, C. Snyder and B. Smith, J. Phys. Chem., to be published. A. Crossley and D. A. King, Surface Sci. 68, 528 (1977). at Surfaces, Ed. R. Caudano, M. D. Baker and M. A. Chesters, in: Vibr%ions et al., (Plenum Press, New York, 1982). H. PfniIr, D. Menzel, F. M. Hoffman, A. Ortega, and A. M. Bradshaw, Surface Sci. 93_, 431 (1980); A. Ortega, F. M. Hoffman and A. M. Bradshaw, Surface Sci. 119, 73 (1982).
(a)
W. G. Golden, D. S. Dunn and John Overend, J. Catal. 11, 395 (1981). R. Ryberg, in: Vibrations at Surfaces, Ed. R. Caudano, et al., (Plenum Press, New York, 19E). P. Hollins and J. Pritchard, in: Vibrational Spectroscopy of Adsorbates, 12. Ed. R. F. Willis, (Springer, New York, 1981). J. C. Campuzano and R. G. Greenler, Surface Sci. 83, 301 (1979). '1:. M. Kawai, T. Onishi and K. Tamaru, Appl. Surface xi. 8, 361 (1981). 15: (a.) R. G. Greenler, J. Chem. Phys. 2, 310 (1966). Tb.) S. A. Francis and A. H. Ellison, J. Opt. Sot. Amer. 49, 131 (1959). 16. L. A. Nafie and M. Diem, Appl. Spec'crosc. 33_, 130 (1979); L. A. Nafie, M. Diem and D. W. Vidrine, J. Am. Chem. Sot. 101, 496 (1979). 17. A. E. Dowry and C. Marcott, Appl. Spectrosc., to be published. 18. Samples supplied by M. Jurich and J. D. Swalen. 19. The potential for obtaining FT-IRRAS spectra of optical components is possible - care should be taken to isolate the spectrometer from polarization modulated light. 20. I. Chabay, Ph.D. thesis, University of Chicago, 1972; I. Chabay and G. Holzwarth, Appl. Opt. 14, 454 (1975). (a) G. Gaines, Insoluble Monolayers at Liquid Gas Interfaces, (Wiley, 21. New York, 1966);. Kay and P.T. Bagus,Ed., Topics in Surface 1::
22. 23.
~~n~~~fSumPrP~~ss~o~wS~~rk~e~g7~)~170 15 (1939), (b)K. B. Blodgett, ;hys. Rev. &, 391 (1939j.-' J. F. Rabolt, F. C. Burns, N. E. Schlotter and J. 0. Swalen, J. Chem. Phys., to be published.
Publishing Company,
FOURIER TRANSFORM SURFACE SPECIES
INFRARED
Amsterdam
43
- Printed in The Netherlands
REFLECTION-ABSORPTION
SPECTROSCOPY
OF
William G. Golden and David 0. Saperstein IBM INSTRUMENTS, INC., San Jose, CA
ABSTRACT We have been able to demonstrate progress in Fourier Transform Infrared Reflection-Absorption Spectroscopy (FT-IRRAS) by incorporating a switching circuit into the data acquisition electronics of an air-equilibrated IBW IR/98 FTIR Spectrometer such that it is possible to obtain simultaneously both reference and polarization modulated spectrum. These spectra ratio to produce good discrimination against gas-phase species. The operating principles of this approach and sample FT-IRRAS spectra of monolayer assemblies of cadmium arachidate adsorbed on silver will be discussed. INTRODUCTION The advantages conventional infrared further
of Fourier Transform
dispersive
techniques
spectroscopic the potential
Several
take advantage
described
by Greenler
Absorption
Spectroscopy
to achieve
improved
in ultrahigh
of the so-called
successful
for dispersion
modulation
grazing
monolayers
(7-14).
These
in dispersion
infrared,
Infrared
infrared range
technique
in dynamic
incidence
Infrared
photoelastic
(10).
circular
0368-2048/83/0000~000/$03.00
(PEM)
have
dichroism
(16,17) ratio
FTIR. our present efforts
monolayers
in the area of
Spectroscopy
of cadmium
arachidate
The spectra were recorded
modulator
modulators workers
range and signal-to-noise
open to the air, i.e. with atmospheric
using a ZnSe photoelastic
Several
Reflection-
to FTIR using the techniques
Reflection-Absorption
on silver are shown.
spectrometer
systems
rules first
IRRAS and vibrational
improvements
of Langmuir-Blodgett
assemblies
vacuum
incidence
selection
dynamic
In this paper we will describe
Spectra
i.r. at grazing
surface
(IRRAS),utilizes
instrumental
the photoelastic
Fourier Transform
to investigate
science applications.
(15).
One of the methods
over conventional
in a wide area of
spectra of thin films (l), Langmuir-Blodget established
efforts,
developed
(FTIR) over
the need exists
have used FTIR and dispersive
(2-6) and monolayers
and have demonstrated
However,
for FTIR in surface
workers
Spectroscopy
have long been utilized
applications.
to obtain vibrational
adapted
Infrared
(CdAA)
with the
CO2 and H20 present,
in the IBM IR/98.
0 1983 Elsevier Scientific
(FT-IRRAS).
New signal handling
Publishing Company
44 techniques acquired
are described
wherein
the sample and reference
spectra are
simultaneously.
EXPERIMENTAL The experimental modulation
technique
of the intensities of the reflected ratioed
approach
for dispersive
in which,
of the parallel
randomly
oriented oriented
modulation
dipole absorbances
involves
tional rotating of modulation
blade chopper
signals of interest. In FTIR,single
Michelson
interferometer
the Genzel design. mathematically
possible
separate
less than 10 KHz, it is quite possible dispersive
double modulation
Figure la depicts technique.
Other configurations
ventional
grazing
described
here (2-14).
were readily
incidence
available
easily within polarizer
experiment
the optical
in the usual fashion
to emulate,
utilizing
to produce
(19).
polarization
of operation
is then focused at grazing monolayer
of these devices
assembly
The signal from the detector Each channel
passed through
the conventional
preamplifier
is demodulated
monolayerc
could be performer' gold wire grid
modulator
were combined
infrared radiation.
(80°+
by using a standard
FTIR ac amplifier
(20).
5') onto the variable
signal processing is physically
separately.
con-
to the methods
can be found elsewhere
incidence
chopper.
for obtaining
A Perkin-Elmer
retro mirror assembly (Harrick Scientific). Figure lb shows a schematic of the FT-IRRAS
two channels.
a separate
applicable
modulated
can be
the
to test this FT-IRRAS
Langmuir-Blodgett
ZnSe photoelastic
The principles
ment.
Since PEM's operate for the mid-IR
(18) and so the entire experiment
International
it is
in many respects,
adopted
IRRAS and are equally
In this case, however,
This radiation
Langmuir-Blodgett
(16).
have been d~onstrated
the FTIR sample chamber
and Hinds
frequency,
modulation
without
e.g. is
into the FTIR system, at a
experiment
arrangement
which
to produce the infrared
modulation
at ca. 50 to 100 KHz while the interferometer
produced
variations,
an interferogram
modulator
larger than the interferometer
(10).
in either a conventional
interferometer
produces
by the Fourier Transform
to produce a double modulation
of the
in analog mode
from the interferogram
or in one of several
a photoelastic
frequencies
demodulation
to a fixed mirror
of
(PEM) and a conven-
such that their respective
This mirror motion
By introducing
spectrum.
which
IRRAS this double
is produced and recorded
relative
demodulated
frequency much
chosen
modulator
beam spectra are obtained
of a mirror
(Ip-Is/Io+IS)in
In dispersive
enough to allow
The ratio
(I,) components
These signals are then
divide out leaving only the spectrum normal.
the use of a photoelastic
are different
by the motion
are collected. beam spectrum
along the surface
a double
both the sum and difference
(Ip) and perpendicular
infrared radiation
to produce a psuedo-double
dipoles
IRRAS incorporates
in analog mode,
angle arrange-
split into
The signal which
and filter circuits,
is
Ipf Is,
45 PFM
_...
switch to circuit zmple
-
and hold and AID
FTIR amplifiers
(b)
Fig.1. (a) Optical configuration of the PEM, polarizer, retro mirror attachment, and KBr plate in the IR/98 sample chamber; (b) schematic of the signal-handling electronics for simultaneous digitization of numerator and denominator signals. hereafter
called
contains
the denominator,
is first demodulated
numerator,
to produce an interferogram
the usual single
The other channel,
of the sample plus spectrometer.
with a phase sensitive
whose amplitude
beam interferogram
hereafter
called
amplifier
is proportional
the
(lock-in)
to Ip- Is.
A
high-pass filter is also employed to remove the large dc offset associated with this signal. is necessary
of the lock-in
amplifier,
time to respond by choosing
the lowest
sufficient
changes
feasible
numerator
interferogram,
dc output, must
lock-in
amplifier
position
cycles must
output
have sufficient This is accomplished
time Constant.
of the interferometer,
be accumulated
2)
a
to produce an accurate
of the value of (Ip-Is).
fashion
utilized
computer
an analog
is changed
and denominator
it is then necessary
spectrometer's
memory.
switch,
at each digital
laser interferometer)
channels
have been produced
to input both signals
The approach
viz. Fig. lb.
here is to
The state of the analog
data point (derived
such that numerator
produces,
in one mirror
data file which contains the digital ferograms
alternately
is this switching both sample
(numerator)
final sequence
and denominator
in either
signal amplitudes
software
This
an interferometer
information,
and denominator
i.e.
inter-
even or odd data addresses.
which allows
and reference
file to produce
and denominatol
has both numerator
of the data handling
the use of conventional the original
stored
technique
switch
from the FTIR's reference
scan of the interferometer,
both numerator
data file produced
in the
into the FTIR
we have adopted
are sent to the FTIR input (sample and hold and A/D) alternately. ideally
it
1) the output
because:
slowly,
of the interferogram.
step in the mirror
number of modulator
Once the numerator above
mirror
being a filtered
to amplitude
For each digitized
average
In order to produce a reliable
to scan the interferometer
for simultaneous
(denominator)
of this dual
collection
interferogram.
interferogram
It of The
involves
to split out the even and odd data from
two new files, each containing
one half of
46 the total number of data points recorded. interferograms
These numerator
are then Fast Fourier Transformed
and denominator
and ratioed
in the usual
fashion. The CdAA monolayer
assemblies
of their ease of fabrication are well characterized prepared
(no vacuum
systems
(3,4).
by the Langmuir-Blodgett
monolayer
were chosen
always established
system
to test the technique is required)
and because they
All of the CdAA assemblies
dipping
technique
with the carboxyiate
because
were
(21,22) with the first
group closest
to the Ag
substrate. The interferograms spectrometer 100 mirror against
at 4 cm
were recorded
-1
resolution
scans were co-added
the FT-IRRAS
spectrum
time was approximately
at an optical
all spectra
are obtained conditions.
Inc.
IR/98
of 0.235 cm/set.
spectrum
and then ratioed
Data acquisition
of a clean Ag substrate.
technique
atmospheric
velocity
for each FT-IRRAS
Since one of the goals of this work is
4 minutes.
to devise an FT-IRRAS
with an IBM Instruments,
which
is insensitive
with the spectrometer
to gas phase absorptions,
completely
open to ambient
RESULTS Figure 2 shows the polarization six monolayer
noted.
CdAA sample before ratioing
The presence
(Ip+Is).
modulation
against
spectrum
are removed
The resultantspectrumfor
by ratioing
six monolayers
the denominator
along with the spectrometer's numerator to denominator
carboxylate
stretch,
-1 , the asymmetric carboxylate the weaker band, at 1577 cm consistent
with the surface
is oriented
selection
rules,
spikes,
in Figure 3a,
spectra.
and
stretch,
i.e. the carboxylate
with its local C2 axis along the surface
sharp downward
spectrum should be
of CdAA is shown in Figure 3a.
band at 1432 cm -l, the symmetric
The strong
(Ip-Is) of the
of strong water vapor and CO2 absorbances
These unwanted gas phase absorptions
background
spectrum
due to water
normal
are group
(23).
The
vapor, arise from the
fact that when the original
interferogram
file is split into numerator
denominator
the amplitude
of the two are not equal.
amplitude
interferograms,
difference
When ratioed
is carried
these amplitude
to water vapor absorption For the purposes technique,resolution the spectral resolution
through
differences
spectra.
small errors corresponding
was decreased
the present capability in order to provide
errors due to gas-phase
and ratioing
produce
maxima.
of evaluating
that when the resolution
the FFT into the calculated
and
This
error
absorption.
is illustrated
is decreased
of the FT-IRRAS
better ratioing
This trade-off
of
between
in Figures 3b and 3c. Note -1 a substantial
(in the FFT) to 8 cm
41
Fig.2. Single beam polarization modulated spectrum of six monolayers of cadmium arachidate on silver. The large absorbances are due to carbon dioxide and water vapor present in the unevacuated spectrometer. improvement
in spectral
information
(e.g. the CH2 wag and twist progression
error
are not as well resolved). completely
is obtained,
-1 bands near 1321 cm -1 the data digitally to ca. 10 cm
Smoothing
blends the progression
but at a loss in spectral
bands but produces
a spectrum
with usable
signal-to-noise. Vonolayer
sensitivity
taking spectra resolution. symmetric
(1439 cm-') and asymmetric
was investigated
spectrum.
by -1
As in Figure 3, the
(1552 cm-') carboxylate
stretching
bands
seen.
In Figure 5 clearly
the FT-IRRAS
contamination
spectrum
of one monolayer
the presence of the symmetric
However,
stretches.
the broad downward
of the reference
Ag substrate
of CdAA on Ag, also
and asymmetric
features
it is clear that signal-to-noise
Otherwise, monolayer
technique
samples of CdAA on Ag at 10 cm
Figure 4 shows the two monolayer
are easily
exhibits
of the FT-IRRAS
of two and one monolayer
carboxylate
in this spectrum
by ambient ratio
are due to
hydrocarbons.
is sufficient
for sub-
spectroscopy.
One other
experimental
to FTIR instrumentation. calculated, is dependent
the apparent
result Because
is discussed
here as it is
peculiar
of the way in which the spectrum
sign of absorption
on the sign of the quality
bands due to surface
(Ip-Is).
is
species
This is because,
in the
48 (b)
fal 2
1432
I $3-4 Ip+l,
5%
1321
1577
I ' Jcx,
'a21
L
m
1
I
12DO 61 D 30 1600 UAVCNull8Lns en-1
2
21
Fig.3. FT-IRRAS spectrum of six monolayers of cadmium arachidate on Ag; calculated at 4cm-1 resolution a {b) calculated at 8 cm-1 resolution C calculated at 8 cm-l resolutio; and smoothed to ca. 10-l resolution: I{ computation computed
algorithm,
spectrum)
represented
the spectrum.
value of the interferogram
is taken so that all single beam spectra
as positive
which affect
component
the absolute
energy spectra.
Ip and Is equally
absorbed,
always
show positive
in the case where
However,
Consequently,
are stored and
all absorptions
normal absorption
in
Ip is the only polarization
the sign of the apparent
absorption
When Ip
on the sign of (Ip-Is).
(or the
1439
-
peak will depend will yield an apparent
1439
I
-1 Ip-‘S 'P + ‘s
1%
1552
I
IP -
1s
'P + 4
1320
Fig.4. FT-IkRAS spectrum of two Fig.5. FT-IRRAS spectrum of one _1 monolayers of CdAA on Ag calculated monolayer of CdAA on Ag at ca. 10 . at 8 cm-l and smoothed to ca. 10 cm-l.
49 "negative
pretation
For the case when Ip>>Is,
absorption."
will occur.
When
Ip>Is
is difficult.
considerations. illustrates
a discontinuity This effect
Table 1 summarizes
these rules
is due entirely these sign rules
By utilizing
(viz. Figure l.), the s ign of (Ip-Is)
normal
positive
will occur and spectral
absorption inter-
to instrumental for FT-IRRAS.
a KBr plate in the optical can be changed
(lo).
Figure
5
beam
Figure 6a shows
Fig.6. FT-IRRAS spectra of six monolayers of cadmium arachidate on Ag showing the dependence of the sutface species absorption on the sign od lip-Is); (a) Ip>Is, (b) Ip
of six monolayers
of CdAA when Ip>I s; Figure 6b is a spectrum
of the same sample but for f
1
FT-IRRAS
Sign of (IpcIsf:
RULES FOR THE SIGN OF ABSORPTION Apparent
BANDS
Sign of the Absorption
Band for:
Gas Phase Species
Surface
Positive
Negative-Linear with absorbance
+
Positive
Positive-Linear with absorbance
0
Positive
Not observed
Species
50 CONCLUSION We have demonstrated spectra of monolayer and sensitivity an understanding with doing
here the feasibility
of the special
surface absorptions;
the utilization
of the interferograms
of mirror
considerations
relaxes
surface
In addition,
has led to a useful rule for
from non-surface
of the switch circuit the constraints
since signal averaging
resolution
associated
rules for the sign of a surface absorption
an easy test for distinguishing
stability,
instrumental
FT-IRRAS
with reasonable
in a short period of time (ca. 4 minutes).
IRRAS with FTIR spectrometers
Finally,
of obtaining
amounts of surface species
bands.
in the data acquisition
associated
can be performed
provide
absorption
with experimental
to any desired
number
scans.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9.
P. A. Chollet, Thin Solid Films 52, 343 (1978), (b) R. G. Greenler, J. Chem. Phys. 50, 1963 (1968). 0. L. Allara and J. D. Swalen, J. Phys. Chem. 3, 2700 (1982). F. A. Burns, N. E. Schlotter, J. F. Rabolt and J. D. Swalen, IBM Instruments, Inc., Application Note No. 1 (1981). T. Ohnishi, A. Ishitani, H. Ischida, N. Yamamoto and H. Tsubomura, J. Phys. Chem. 82, 1989 (1978). W. Knoll, M. R. Philpott and W. G. Golden, J. Chem. Phys. 77_, 219 (1982). W. G. Golden, C. Snyder and B. Smith, J. Phys. Chem., to be published. A. Crossley and D. A. King, Surface Sci. 68, 528 (1977). at Surfaces, Ed. R. Caudano, M. D. Baker and M. A. Chesters, in: Vibr%ions et al., (Plenum Press, New York, 1982). H. PfniIr, D. Menzel, F. M. Hoffman, A. Ortega, and A. M. Bradshaw, Surface Sci. 93_, 431 (1980); A. Ortega, F. M. Hoffman and A. M. Bradshaw, Surface Sci. 119, 73 (1982).
(a)
W. G. Golden, D. S. Dunn and John Overend, J. Catal. 11, 395 (1981). R. Ryberg, in: Vibrations at Surfaces, Ed. R. Caudano, et al., (Plenum Press, New York, 19E). P. Hollins and J. Pritchard, in: Vibrational Spectroscopy of Adsorbates, 12. Ed. R. F. Willis, (Springer, New York, 1981). J. C. Campuzano and R. G. Greenler, Surface Sci. 83, 301 (1979). '1:. M. Kawai, T. Onishi and K. Tamaru, Appl. Surface xi. 8, 361 (1981). 15: (a.) R. G. Greenler, J. Chem. Phys. 2, 310 (1966). Tb.) S. A. Francis and A. H. Ellison, J. Opt. Sot. Amer. 49, 131 (1959). 16. L. A. Nafie and M. Diem, Appl. Spec'crosc. 33_, 130 (1979); L. A. Nafie, M. Diem and D. W. Vidrine, J. Am. Chem. Sot. 101, 496 (1979). 17. A. E. Dowry and C. Marcott, Appl. Spectrosc., to be published. 18. Samples supplied by M. Jurich and J. D. Swalen. 19. The potential for obtaining FT-IRRAS spectra of optical components is possible - care should be taken to isolate the spectrometer from polarization modulated light. 20. I. Chabay, Ph.D. thesis, University of Chicago, 1972; I. Chabay and G. Holzwarth, Appl. Opt. 14, 454 (1975). (a) G. Gaines, Insoluble Monolayers at Liquid Gas Interfaces, (Wiley, 21. New York, 1966);. Kay and P.T. Bagus,Ed., Topics in Surface 1::
22. 23.
~~n~~~fSumPrP~~ss~o~wS~~rk~e~g7~)~170 15 (1939), (b)K. B. Blodgett, ;hys. Rev. &, 391 (1939j.-' J. F. Rabolt, F. C. Burns, N. E. Schlotter and J. 0. Swalen, J. Chem. Phys., to be published.