Hyperfine structure of the molecular ion H2+

Frequencies of allo&ed zero-field hyperfme transitions between N = 1 and N = 2 nuclear rotational levels of I$ have been calculated to high accuracy. Agreement with experiment is to within 0.7 MHz for all the observed transitions, but the accuracy of the present calculations is considerably higher,

Refined variational calculations of the first-and second-order hyperfine interaction coefficients dl and d2 have been performed for the hydrogen-molecute-ion. The electronic matrix elements were carefully stabilized for each coefficient separately and the vibration-rotation wavefunctions calculated

The Zpa, u=O, N=2-lsa, v= 18, N=3 transition in Hz hasbeen observed at 156632.8 MHz. This transition shows a cbaracteristic structure which we assign in terms of hyperfine, fme and electronic g/u symmetry-breaking effects.

The J = 1 \* 0 transition ol the molecular ion HN; has been observed in laboratory WI& a resoluhon sufficiently high II allow Lhe meaSuremen of the transition IrequencieE of all seven of the quadrupole hyperhne components produced by bolh lhS outer and inner mlrogen nuclei. The cemral hne frequency.

Very high resolution measurements of hyperfinc structure on the P(l3) and R(15). 43--O, '11o+ -'xi transitions in iodine 127 were tnade using laser molecular beam spectroscopy. The observed linewidth was 30tkHz (fwhm) giving a resolution of 5 X lo-'o. The observed spectrum was fitted to obtain a qua