Vibronic Reassignment of theÃ1A′′ ←X̃1A′ Band System of Bromomethylene

The 000-000 and 3 1 0 bands of the 775-nm electronic transition of YC 2 ( Ã2 A 1 ← X2 A 1 ) have been studied at high resolution, using the laser-induced fluorescence from a supersonic jet expansion. Three types of experiment have been carried out. First, the complete rotational and hyperfine struct

We report the laser excitation and dispersed fluorescence spectra of the A ˜2E 4 X ˜2A 1 transition of the jet-cooled MgCH 3 radical. Improvements to the experiment have allowed the observation of 6 0 1 and 2 0 1 vibronic features not previously observed. Analyses of these bands, along with the prev

Magnetically tuned singlet-triplet perturbations in the 4 1 A ˜1A 2 -2 1 3 1 a ˜3A 2 system of thioformaldehyde, found in orthorotational states (I ϭ 1, the two hydrogen spins parallel) have been identified as being caused by vibronic spin-orbit coupling. This perturbation mechanism has been confirm

Rotationally resolved excitation spectra of the 0 0 0 and 33 1 0 bands of the Ã1 B 1u ← X 1 A g electronic transition of naphthalene were measured by a frequency-doubled single-mode tunable laser and a jet-cooled collimated molecular beam. The observed linewidth was 18 MHz, and the absolute wavenumb