IR-spectroscopy of the atmosphere

Abstract

The infrared technique of measuring trace gases in the air has been evolving for many years, with rapid progress during the last ten years. Air pollution research requires such measurements for mixing ratios as low as 10−10. This calls for long optical paths, such as the path from a high altitude observing point to a setting sun. At ground level the best way to achieve a long enough path is to use J.U. White's 3-mirror multiple-pass cell. The infrared method has had its greatest success in the study of the upper atmosphere using balloon-borne spectrometers aimed at the sun. Measurements through the upper atmosphere do not have significant interference from water vapor. At ground level, however, the water vapor absorbs nearly everywhere in the spectrum, and it is necessary to detect the trace gases by the small perturbations they make on the water vapor spectrum. The Fourier transform (FT) spectrometer has been responsible for recent progress. For studies in the lower atmosphere one can obtain superb spectra by combining an FT instrument of about 0.1 cm−1 resolution with a White cell made from mirrors of modest size. Nitrogen-cooled detectors should be used. The path may be in the open air. With an FT instrument, signal fluctuations caused by air turbulence do not appear to introduce noise into the spectrum. This is a result of the multiplexing and the high frequency modulation. Pollutants that have been measured by infrared in ambient air have included HNO3, HNO2, NH3, O3, CO, CO2, SO2, NO, NO2, H2CO, HCOOH, hydrocarbons, peroxy nitrates, HCl and HF. Further study should extend this list.