Torsion-rotation absorption line assignments in the symmetric CH-stretch fundamental of methanol

The infrared spectrum of jet-cooled methanol in the CH-stretch fundamental region has been investigated by two sub-Doppler laser techniques: optothermally detected molecular-beam electric resonance and direct-absorption slit-jet spectroscopy. With the aid of microwave-infrared double resonance and g

The \(\mathrm{CH}_{3}\) asymmetric stretching region of methanol vapor has been investigated between 2900 and \(3200 \mathrm{~cm}^{-1}\) with a \(1.25-\mathrm{m}\) maximum path difference Fourier transform spectrometer. Thirteen \(P\) branches and eleven \(R\) branches were assigned ( 13 series repr

A theoretical model has been developed to account for certain features of both newly observed and previously reported CH 3bending subbands between 1450 and 1570 cm À1 in the high-resolution Fourier transform infrared spectrum of CH 3 OH [Can. J. Phys. 79 (2001) 435]. The features include (i) an appa

The absorption spectrum of methanol vapor has been recorded at room temperature from 3200 to 4200 cm Ϫ1 with a 1.24-M path-difference Fourier transform spectrometer. Over 10 000 transitions to the torsion-rotation states n, J, K of the OH stretching fundamental band 1 have been assigned, thereby gre

We record double resonance spectra of the 4ν 1 band of jet-cooled 13 C-methanol using single rotational state selection in the ν 1 fundamental and subsequent promotion of the selected molecules to the fourth vibrational level. We then detect transitions to the final excited states by infrared laser