High-resolution Fourier transform and submillimeter-wave spectroscopy of the ν3 and 2 ν3 ← ν3 bands of 13CH3F

Using new high-resolution Fourier transform spectra recorded at the University of Denver in the 2-m region, a new and more extended analysis of the 2 1 ϩ 3 and 3 3 bands of nitrogen dioxide, located at 4179.9374 and 4754.2039 cm Ϫ1 , respectively, has been performed. The spin-rotation energy levels

The 3 1 and 3 1 ϩ 3 bands of propyne have been recorded at Doppler-limited resolution by Fourier transform spectroscopy and intracavity laser absorption spectroscopy, respectively. The two bands show a mostly unperturbed J rotational structure for each individual K subband. However, as a rule the K

High-resolution spectrum of the HDS molecule was recorded with the Bruker Fourier spectrometer in Oulu in the regions of the n 1 and 2n 1 /n 2 / n 3 absorption bands. Fine rotational structure of the n 1 band was analyzed with the model of an isolated vibrational state, while in the analysis of the

Using high-resolution Fourier transform spectra of monoisotopic \(\mathrm{H}_{2}{ }^{80} \mathrm{Se}\) recorded in the 1.8 and \(1.55-\mu \mathrm{m}\) regions. an extensive analysis of the \(2 \nu_{1}+\nu_{2}, \nu_{1}+\nu_{2}+\nu_{3}, 3 \nu_{1}, 2 \nu_{1}+\nu_{3}\), and \(\nu_{1}+\) \(2 v_{3}\) band

High-resolution Fourier transform spectra of a natural sample of hydrogen telluride and of monoisotopic H 2 130 Te have been recorded in the 3.2-4-0 mm spectral region where the 3n 2 , n 1 / n 2 , and n 2 / n 3 bands of this molecule absorb. The (030) rotational levels were least-squares fitted usin