The far infrared spectrum of 14N16O2
- 10 April 1988
- journal article
- research article
- Published by Taylor & Francis in Molecular Physics
- Vol. 63 (5) , 791-810
- https://doi.org/10.1080/00268978800100571
Abstract
High resolution Fourier transform spectra in the 8–200 cm-1 spectral region have been used to analyse the pure rotation spectrum of nitrogen dioxide. In this way, the spin rotation levels of the (000) state were accurately measured for Ka up to 14 and N up to 54. Using a hamiltonian which takes the spin-rotation and the hyperfine operators explicitly into account, it has been possible to derive a complete set of molecular parameters (rotational, spin-rotation and hyperfine constants) for the (000) state of 14N16O2 from these experimental data and from the available microwave measurements. Numerous perturbations due to the hyperfine Fermi contact operator were analysed as well as a local resonance [42 0 42, J = 41·5] ↔ [41 2 40, J = 41·5] due to the electron spin-rotation interaction. Finally, a synthetic spectrum of the (000) ← (000) band of 14N16O2 including all hyperfine transitions has been computed, covering the 0–235 cm-1 spectral region.Keywords
This publication has 21 references indexed in Scilit:
- Accurate rotational constants of CO, HCl, and HF: Spectral standards for the 0.3- to 6-THz (10- to 200-cm−1) regionJournal of Molecular Spectroscopy, 1987
- Far-infrared high-resolution Fourier transform spectrometerApplied Optics, 1987
- The pure rotation spectrum of nitrogen dioxide between 10 and 80 cm-1Molecular Physics, 1984
- High resolution molecular spectroscopy in the submillimeter regionInternational Journal of Infrared and Millimeter Waves, 1984
- The millimeter and submillimeter spectrum of NO2: A study of electronic effects in a nonsinglet light asymmetric rotorThe Journal of Chemical Physics, 1982
- A determination of the spin–rotation parameters for NO2 in the X̃ 2A1 state by microwave–optical double resonanceThe Journal of Chemical Physics, 1981
- Spin–rotation and hyperfine parameters for the (001) excited vibrational state of NO2 from infrared–radiofrequency double resonanceThe Journal of Chemical Physics, 1980
- Microwave spectrum of 14N 16O2 at 70 GHzThe Journal of Chemical Physics, 1974
- Millimeter-Wavelength Microwave Spectrum of Nitrogen DioxideThe Journal of Chemical Physics, 1966
- Microwave Spectrum of NO2: Fine Structure and Magnetic CouplingThe Journal of Chemical Physics, 1964