Hyperfine structure of low-lying vibrational levels in the B electronic state of molecular iodine
- 1 September 1989
- journal article
- Published by Optica Publishing Group in Journal of the Optical Society of America B
- Vol. 6 (9) , 1656-1659
- https://doi.org/10.1364/josab.6.001656
Abstract
The hyperfine structures of the weak lines R(69) in the 3–4 band and P(84) in the 5–5 band of the B ← X electronic transition in molecular 127I2 at λ = 657 nm have been detected by the method of FM saturation spectroscopy. Frequency separations between the hyperfine components were measured, and the hyperfine coupling constants for the electric quadrupole interaction and the magnetic spin-rotation interaction were determined. For low vibrational levels of the B state, eQqB depends linearly on the vibrational energy of the level νB according to eQqB (MHz) = −0.01721G(νB) (cm−1) − 484.89. ΔC is almost constant for νB values smaller than 6.Keywords
This publication has 24 references indexed in Scilit:
- Identification of hyperfine structure components of the iodine molecule at 640 nm wavelengthOptics Communications, 1985
- 127I2-Stabilized 3He-22Ne Laser at 640 nm WavelengthIEEE Transactions on Instrumentation and Measurement, 1985
- Hyperfine Structure and Hyperfine Coupling Constant of Molecular IodineJapanese Journal of Applied Physics, 1984
- High precision saturation spectroscopy of 127I2 with argon lasers at 5 145 Å and 5 017 Å : I — Main resonancesJournal de Physique, 1981
- Re-evaluation of the hyperfine coupling constants forB−Xtransitions inI2Physical Review A, 1980
- Laser fluorescence state selected and detected molecular beam magnetic resonance in I2The Journal of Chemical Physics, 1980
- Hyperfine structure of the R(98), 58-1 line of 127I2 at 514.5 nmChemical Physics Letters, 1979
- Hyperfine Interactions in Molecular IodinePhysical Review A, 1972
- Hyperfine Structure in the Visible Molecular-Iodine Absorption SpectrumPhysical Review Letters, 1969
- IODINE HYPERFINE STRUCTURE OBSERVED IN SATURATED ABSORPTION AT 633 nmApplied Physics Letters, 1969