High Resolution Spectrum of the (3–0) Band of theb1Σ+g–X3Σ−gRed Atmospheric System of Oxygen

The b1Sigma+g-X3Sigma-g (1,0) band of 16O17O, 16O18O, 18O2, 17O18O, and 17O2 isotopomers was investigated employing the technique of cavity-ring-down spectroscopy. More than 400 transition frequencies of magnetic dipole lines were determined with a typical uncertainty of 0.01 cm-1. This work results

We investigated the resonant magneto-optic spectra of the electronic band b 1 S / g -X 3 S 0 g of the oxygen molecule. The theoretical analysis was made on the basis of the Zeeman effect of the magnetic-dipole transition. The oxygen molecules were assumed to be subjected to an externally applied mag

The oxygen b 1 S / g -X 3 S 0 g electronic spectrum (the atmospheric system) has been recorded at high resolution in both emission and absorption on the same Fourier transform spectrometer but with independent calibration methods used in each case. After correction for the known pressure shift of th

Emission spectra of the b 1 ⌺ ϩ 3 X 3 ⌺ Ϫ and a 1 ⌬ 3 X 3 ⌺ Ϫ transitions of SO in the near-infrared spectral region were studied at high spectral resolution with a Fourier-transform spectrometer. The 0 -0 band of the b 3 X system was measured at high signal/noise and four magnetic dipole branches w

Chemiluminescence spectra of the \(a^{3} \Sigma^{+}\left(a_{1}\right) \rightarrow \mathrm{X}^{1} \Sigma^{+}\left(\mathrm{X}^{+}\right)\)transitions of BiP and BiAs in the near-infrared spectral region have been measured at high resolution with a Fourier-transform spectrometer. Analyses of the spectr