The High-Precision Millimeter-Wave Spectrum of32SO2,32SO2(ν2), and34SO2

Laser-induced excitation spectra of the two bands a ˜3B 1 -X ˜1A 1 , 2 0 1 and 1 0 1 of 32 SO 2 and 34 SO 2 have been recorded in a supersonic jet at a resolution of 0.015 cm Ϫ1 . The rotational and electron-spin fine structure has been analyzed for both isotopic species. Analysis of the rotational

The high-resolution infrared spectrum of the 8 band of SO 2 F 2 ( as SF 2 ) centered at 887.2 cm Ϫ1 has been recorded with a resolution of 2.4 ϫ 10 Ϫ3 cm Ϫ1 . More than 8000 transitions of the C-type band with ⌬K a ϭ Ϯ1 (and in addition some ⌬K a ϭ Ϯ3 transitions) have been assigned. Microwave and m

Precise frequencies for the 1 11 -2 02 transition of 33 SO 2 and SO 17 O in natural isotopic abundance have been obtained near 12 GHz by microwave Fourier transform spectroscopy in order to yield improved hyperfine constants. Nuclear spin-rotation coupling constants have been determined experimental

Chlorine nitrate is a molecule of interest in atmospheric studies because of its role as a reservoir species, removing both chlorine and nitrogen species from catalytic cycles of ozone destruction. The ground and ν 9 vibrational states have been previously studied in the millimeter and submillimeter

The room temperature infrared spectra of the a-type n 1 / n 3 , n 1 / n 2 / n 3 0 n 2 , and 2n 1 / n 3 bands of 32 SO 2 and the n 1 / n 3 band of 34 SO 2 have been recorded using a difference-frequency laser spectrometer and completely analyzed. It is possible to reproduce the rotational energy leve