Infrared diode laser and millimeter-wave spectroscopy of the NCl radical: Vibrational and isotopic dependences of molecular constants

Vib-rotational energy differences between the \(\dot{X}(010)^{3} \Pi(b)\) and \(\dot{X}(000)^{3} \Sigma^{-}\)states, and purerotational energy differences in the \(\bar{X}(010)^{3} \Pi(b)\) state of the CCO radical, were obtained from near-infrared absorption spectral data of the \(\tilde{A}(010)^{3

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 rotational spectral lines of HCCS and DCCS have been observed with a Fourier transform millimeter-wave spectrometer in combination with a pulsed discharge nozzle. The HCCS radical is produced by discharging a mixture of C 2 H 2 and CS 2 diluted in Ar. The DCCS radical is produced by using C 2 D

Infrared line positions, linestrengths, and pressure-broadening coefficients are required to determine absolute trace gas concentrations from high-resolution absorption spectra. We have measured these values for the infrared absorption lines in the ν 12 band (antisymmetric wag) of hydrazine between

The \(\dot{A}(010)^{3} \Sigma^{(-)}-\dot{X}(000)^{3} \Sigma^{-}, \dot{A}(010)^{3} \Sigma^{(-)}-\dot{X}(010)^{3} \Pi(b)\) and \(\dot{A}(010)^{3} \Sigma^{(+)}-\dot{X}(010)^{3} \Pi(b)\) subbands in the \(\dot{A}^{3} \Pi_{i}-\dot{X}^{3} \Sigma^{-}\)system of the \(\mathrm{CCO}\) radical have been reinve

FIG. 6. Plot of integrated absorption from 965.4774 to 965.6633 cm -1 versus hydrazine column density (number density times path length). The slope is the integrated line strength for this spectral region.