Diode Laser Spectroscopy of the ν13 Band of Benzene Cooled in a Supersonic Jet

The diode-laser absorption spectrum of the 19a band of the chlorobenzene molecule cooled in a supersonic jet is presented and transitions from low J, K a , and K c values (0 -14) are reported. The C 6 H 5 35 Cl band center has been found at 0 ϭ 1483.894 cm Ϫ1 and rotational constants for the upper s

## FIG. 2. Boltzmann plot for the 12 band of benzene observed in a supersonic jet. The symbols ‚, ᮀ, , ƒ, E, U, OE, s, and F correspond to K ϭ 1-9 in the ground state. For K ϭ 0, ϩ and ϫ are assigned to even and odd J, respectively.

High resolution infrared spectra of the n 5 and n 10 bands of C 2 F 6 in a supersonic jet have been measured using a diode laser spectrometer. The well resolved vibration-rotation lines of these two bands were obtained. The spectra were analyzed using a standard Hamiltonian for a prolate symmetric r

High-resolution diode laser spectroscopy was applied to measure absolute line intensities in the 9.8-mm n 14 band of benzene 12 C 6 H 6 . A new data treatment had to be developed to derive single line parameters from the strongly overlapped lines. This procedure includes a self-deconvolution and an

The n 3 fundamental band (C-N stretch) and four associated hot bands of I 13 CN have been recorded in the 2130 cm 01 region using a diode laser spectrometer. The analysis of the five infrared bands has been supported by the measurements of new millimeter-wave rotational lines for the 00 0 0, 01 1 0,

The UV spectrum of the 6(1)0 S1 <-- S0 vibronic transition of benzene, located at 259 nm, was recorded by means of a combination of a cw laser doubling unit and a molecular beam apparatus. A typical linewidth of 27 MHz was observed, limited only by residual Doppler broadening in the supersonic beam.