This work involves the analysis of a series of McMath Fourier Transform Infrared (FTIR) spectra of ozone broadened by mixing with air (four different pressures), nitrogen (three pressures), or oxygen (three pressures). Each spectrum covers the region from 2396 to 4057 cm(-1). This study focused on the 3 sub nu sub 3 band in t 3000 to 3060 cm(-1). The band is analyzed by first dividing its region into small intervals containing a few well isolated absorption lines of reasonable intensity. Each of these small intervals is fit by multiple iterations of the nonlinear least squares program until residuals (the difference between calculated and observed spectrum, as a percent of the strongest intensity in the interval) are minimized to a reasonable value which corresponds to the noise level of the measured spectrum. Position, intensity, and half-width are recorded for later analysis. From the measured half-widths, a pressure broadening coefficient was determined for each absorption line. Pressure shifts were determined by comparing observed line positions in the spectra of the diluted ozone samples to tabulated line positions determined from spectra of pure gas samples. Comparisons to other work on ozone indicate that the broadening and shift coefficients determined in this study are consistent with those determined in other spectral regions

Prochaska, Eleanor S.

English

The Molecular Spectroscopy Lab at NASA-Langley has been involved in a long term effort to carefully characterize the infrared spectra of small molecules of atmospheric interest, including methane, water vapor, ozone, and their isotopic counterparts. High resolution gas phase infrared spectra are obtained using both a tunable diode laser system, and the McMath Fourier transform spectrometer at the Kitt Peak Solar Observatory. Spectra are obtained at various pressures and temperatures for pure gas samples, and for samples containing mixtures of the species of interest in nitrogen, oxygen, or air. From these spectra, using a nonlinear least squares fitting technique, spectral parameters of position, intensity, and half-width were determined for varying laboratory conditions that approximate atmospheric conditions experienced in remote sensing situations. These parameters are of interest in theoretical studies of these species, as well as in allowing more accurate interpretation of remote sensing data. The current work involves the analysis of a series of McMath FTIR spectra of ozone broadened by mixing with air, nitrogen, or oxygen. Each spectrum covers the region from 2396 to 4057/cm. Each vibrational band is analyzed by first diving its region into small intervals containing a few well isolated absorption lines of reasonable intensity. Each of these small intervals is fit by multiple iterations of the nonlinear least square program until residuals are minimized to a reasonable value which corresponds to the noise level of the measured spectrum. Intervals for the 3 nu(sub 3) ozone band in the region from 3000 to 3060 wavenumbers are being examined

NASA Technical Reports Server

7.
N91-13336
Analysis of Pressure-Broadened Ozone Spectra
in the 3-#m Region
Eleanor S. Prochaska
Western Carolina University
Cullowhee, N.C.
The presence of a layer of photochemically produced ozone in
the stratosphere has been recognized for some time. This ozone
layer is vital to life on earth, as it provides a shield from
harmful ultraviolet radiation that is a normal component of
sunlight. During the mid 1980's, a deficit in the ozone layer was
observed over the Antarctic continent. Since that time, the need
to observe and monitor the ozone content in the stratosphere has
been the motivation of considerable scientific effort. More
recently, the effects of increased atmospheric ozone amounts at the
earth's surface have been found to be of significant environmental
concern. Spectroscopic methods are the basis for remote sensing
techniques to measure atmospheric content of many species,
including ozone, on global and regional scales. As technology
continues to improve, the understanding of the spectra of these
species becomes increasingly important in allowing accurate
retrieval of data obtained by remote sensing techniques.
The Molecular Spectroscopy Lab at NASA-Langley has been
involved in a long term effort to carefully and fully characterize
the infrared spectra of small molecules of atmospheric interest,
including methane, water vapor, ozone, and their isotopic
counterparts. High resolution gas phase infrared spectra are
obtained using both a tunable diode laser system, and the McMath
Fourier transform spectrometer at the Kitt Peak Solar Observatory.
Spectra are obtained at various pressures and temperatures for pure
gas samples, and for samples containing mixtures of the species of
interest in nitrogen, oxygen, or air. From these spectra, using a
non-linear least squares fitting technique, spectral parameters of
position, intensity and half-width have been determined for varying
laboratory conditions that approximate atmospheric conditions
experienced in remote sensing situations. These parameters are of
interest in theoretical studies of these species, as well as in
allowing more accurate interpretation of remote sensing data.
The current work in the lab involves the analysis of a series
of McMath FTIR spectra of ozone broadened by mixing with air,
nitrogen or oxygen. Each spectrum covers the region from 2396 to
4057 c_*. Each vibrational band is analysed by first dividing its
region into small (0.5 to 2.0 cm l) intervals containing a few well
isolated absorption lines of reasonable intensity. Each of these
small intervals is "fit" by multiple iterations of the non-linear
96
https://ntrs.nasa.gov/search.jsp?R=19910004023 2020-03-19T20:44:53+00:00Z
least squares program until residuals (difference between
calculated and observed spectrum, as percent of the strongest
intensity in the interval) are minimized to a "reasonable" value
which corresponds to the noise level of the measured spectrum.
Position, intensity and half-width are recorded for later analysis.
Half-widths are normalized for each pressure and a pressure
broadening coefficient is determined for each absorption line.
This summer, intervals for the 3p3 ozone band in the region
from 3000 to 3060 wavenumbers are being examined. In particular,
analysis of the region from 3000 to 3030 wavenumbers has been
completed for all ten experimental conditions, and broadening
coefficients have been found for over 200 lines of the 3v3 region
for the three broadening gases. The remaining 3030 to 3060
wavenumber region remains to be fitted before a final analysis of
line broadening in the 3_3 ozone band can be completed.
Appendices:
i.
2.
Ozone Broadening Experimental Conditions
Comparison of Halfwidths for 03 Line at 3010.9152 cm I.
(comparable results have been obtained for each line that has
been studied in the ozone 3_ region)
97
OZONEBROADENING
EXPERIMENTALCONDITIONS
Gas Mixture
03 in Air
Volume Mixing Ratio
4.16%
2.13
1.43
1.08
Pressure
105.0 torr
204.9
305.0
405.3
03 in N 2 4.54 105.1
2.33 205.1
1.57 304.2
03 in 02 5.18 106.3
2.67 206.2
1.80 306.4
All spectra were recorded using a 2 39 m cell at 26 + l°C
and 0.01 cm -I resolution•
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Analysis of pressure-broadened ozone spectra in the 3 micron region

N92-13856
Analysis of Pressure-Broadened Ozone Spectra
in the 3-_m Region
Eleanor S. Prochaska
Department of Mathematicsand Computer Science
Western Carolina University
Cullowhee, N.C.
The presence of a layer of photochemically produced ozone in
the stratosphere has long been recognized as vital to life on
earth, as it provides a shield from the harmful ultraviolet
component of sunlight. A deficit in the ozone layer was observed
over Antarctica in the mid 1980's, motivating considerable effort
to improve and standardize methods of measuring and monitoring
ozone in the atmosphere. More recently, increased atmospheric
ozone at the earth's surface has been found to be of significant
environmental concern. Spectroscopic methods are the basis for
remote sensing techniques to measure atmospheric content of many
chemical species, including ozone, on both global and regional
scales. As technology continues to improve, the understanding of
the spectra of these species becomes increasingly important in
accurate retrieval of atmospheric composition data obtained by
remote sensing techniques.
The Molecular Spectroscopy Lab at NASA-Langley has been
involved in a long term effort to carefully and fully characterize
the infrared spectra of small molecules of atmospheric interest,
including methane, water vapor, carbon dioxide, and ozone, and
their isotopic counterparts. High resolution gas phase infrared
spectra are obtained using both a tunable diode laser system, and
the McMath Fourier transform spectrometer at the Kitt Peak Solar
Observatory. Spectra are obtained at various sample pressures and
temperatures, both for pure gas samples, and for samples containing
mixtures of the species of interest diluted in nitrogen, oxygen, or
air. Air-diluted samples simulate the atmosphere at different
altitudes, by varying temperature and pressure. Nitrogen- and
oxygen-diluted samples allow theoretical studies of the
interactions of ozone with these air components individually.
Spectral parameters are modeled to the observed spectra by a non-
linear least squares fitting technique. Position, intensity and
half-width are determined for each well-isolated feature of
reasonable intensity in the spectra. These parameters are of
interest in theoretical studies, as well as in allowing more
accurate interpretation of remote sensing data.
This work involves the analysis of a series of McMath FTIR
spectra of ozone broadened by mixing with air (four different
pressures), nitrogen (three pressures), or oxygen (three
pressures). Each spectrum covers the region from 2396 to 4057 cm -I.
This study has focused on the 3p3 band in t 3000 to 3060 cm "!
186
https://ntrs.nasa.gov/search.jsp?R=19920004638 2020-03-17T13:45:12+00:00Z
region. The band is analysed by first dividing its region into
small (0.5 to 2.0 cm "I) intervals containing a few well isolated
absorption lines of reasonable intensity. Each of these small
intervals is "fit" by multiple iterations of the non-linear least
squares program until residuals (difference between calculated and
observed spectrum, as a percent of the strongest intensity in the
interval) are minimized to a "reasonable" value which corresponds
to the noise level of the measured spectrum. Position, intensity
and half-width are recorded for later analysis.
From the measured half-widths, a pressure broadening
coefficient has been determined for each absorption line. These
broadening coefficients are shown in Figure 1 as a function of
lower state rotational quantum number. The broadening coefficients
show a slight decrease with increasing rotational quantum number.
Pressure shifts have been determined by comparing observed line
positions in the spectra of the diluted ozone samples to tabulated
line positions determined from spectra of pure gas samples.
Pressure shifts are shown as a function of quantum number in Figure
2, and show little dependence on rotational quantum number.
Broadening and shift coefficients for this absorption band have not
been examined before, but comparisons can be made to similar
studies of other ozone bands. In particular, it is noteworthy that
the observed shifts for the 3_ band are on the order of three
times the shifts for the Pl band (I), showing a dependence on the
energy of the vibration, as Pl occurs at about ii00 cm "I and 3_ at
about 3000 cm "I. It is also of interest that the broadening
coefficient for air is between those of nitrogen and oxygen. In
particular, the broadening coefficient for air can be expressed as
a weighted average of those for nitrogen and oxygen, where the
weighting coefficients are those of the relative abundance of each
gas in air. Comparisons to other work on ozone (2,3,4,5) indicate
that the broadening and shift coefficients determined in this study
are consistent with those determined in other spectral regions.
(I) M. A. H. Smith, C. P. Rinsland, V. Malathy Devi, D. Chris
Benner, and K. B. Thakur, J. Opt. Soc. Amer. B. 5, 585-592 (1988).
(2) M. N. Spencer and C. Chackerian, Jr., J. Mol. Spectrosc. 146,
135-142 (1991).
(3) J. J. Plateaux, S. Bouazza, and A. Barbe, J. Mol. Spectrosc.
146, 314-325 (1991).
(4) A. Barbe, S. Bouazza, and J. J. Plateaux, Applied Optics
30(18), 2431-2436 (1991).
(5) J.M. Hartmann, C. Camy-Peyret, J. M. Flaud, J. Bonamy, and D.
Robert, J. Quant. Spectrosc. Radiat. Transfer 40___, 489-495
(1988).
187
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189


Analysis of pressure-broadened ozone spectra in the 3 micron region

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