Abstract

The intense excitation of an Ar⁺ laser operating at 514 nm enhances the grating ghosts and general stray light within most double monochromators at wavelengths close to the exciting line. The I₂ filter technique provides an effective means of reducing this interference and, in so doing, makes possible the measurement of Raman bands close to the exciting line. However, at an instrument resolution less than 3 cm⁻¹, the I₂ absorption spectrum seriously interferes with the Raman spectrum. Ratioing the Raman spectrum with a white light absorption spectrum of I₂ removes the I₂ absorption lines. However, with slit widths <3 cm⁻¹, the wavelength reproducibility of the monochromator on successive scans is not high enough to insure successful ratioing. A technique is described for obtaining, approximately within the same time interval, the Raman spectra and white light spectrum at each wavelength that data are acquired. This procedure accurately removes the I₂ absorption spectrum.

© 1978 Optical Society of America

High-dispersion astronomical spectroscopy with holographic and ruled diffraction gratings

Dainis Dravins
Appl. Opt. 17(3) 404-414 (1978)

High resolution Fourier transform spectrometer (0.005 cm⁻¹) for the 0.6–100-μm spectral range

A. A. Balashov, V. S. Bukreev, N. G. Kultepin, I. N. Nesteruk, E. B. Perminov, V. A. Vagin, and G. N. Zhizhin
Appl. Opt. 17(11) 1716-1722 (1978)

Pressure and temperature dependence of Freon-12 absorption coefficients for CO₂ waveguide laser radiation

Charles N. Harward
Appl. Opt. 17(7) 1018-1022 (1978)

Vacuum ultraviolet 6-m monochromator

J. H. Carver, G. N. Haddad, T. I. Hobbs, B. R. Lewis, and D. G. McCoy
Appl. Opt. 17(3) 420-429 (1978)

Laser optoacoustic absorption spectra for various explosive vapors

R. A. Crane
Appl. Opt. 17(13) 2097-2102 (1978)