Hyperfine structure in the Ω=0+ ground state of bismuth iodide (Bil)

IF molecules were prepa.red in a miaowave disckuge by using C3FpI Cheptafluoro-2-iodopropane) or by the direct reaction X2 + F2 \_ The hyperfine structure of the rotational transitions f + 1 -f = 54 of the nirational level u' = 3 and 6 -5 of U' = 4 in the excited electronic state B 3 n e+ of IF has

A number of pure quadrupole resonances in the ground and \(v_{4}=1\) states of \(\mathrm{AsH}_{3}\) have been measured using the radiofrequency-infrared double-resonance technique in a \(\mathrm{CO}_{2}\) laser cavity. The ground state resonances were fitted together with all available radiofrequenc

The hyperfine structure of the \(J=1 \leftarrow 0\) rotational transition of \(\mathrm{CuCl}\) as well as the \(J=\) \(3 \leftarrow 2,2 \leftarrow 1\). and \(1 \leftarrow 0\) rotational transitions of \(\mathrm{CuBr}\) in the \(v=0\) vibrational level have been investigated using a microwave Fourier

A pump/probe microwave-optical double resonance experiment has been performed on calcium monohydroxide, \(\mathrm{CaOH}\), using the technique of laser ablation/supersonic expansion for production of the compound. Frequencies associated with the three lowest pure rotational transitions in the \((0,0