Double resonance observation of the (2ν3, E) state in methane

Seveml vibration-rotation lines involiins the infrared-inactive (3~3, Al) stretching state of methane have been recorded by the double resonance technique\_ The vibrational energ (8975.34 cm-') has been round to agce with local-mode predictions. As was the case for several other Al vibrational state

Several vibration-rotation lines involving the infrared-inactive (3u,, F, ) stretching state of methane have been recorded by the double-resonance technique. The energies of the rotational sublevels of (3v,, F, ) are well represented for J< 3 by a first-order Conlis Hamiltonian. The vibrational ene

Double-resonance spectra were recorded for several rotatiomd sublevels of the (21) The observed vibrational energy is 5968.1 cm-', \_ 3, Al) vibrational level of methane. m good agreement with local-mode theory\_ The effective rotational constant for this level was found to be 5.31 cm-' . This unex

Two (A/, AK) = (2. -I)-lype vibralionally induced romlionnl transitions in Ihe us state 01 CDF, have been observed by CO2 laser-microwave double resonance. The observed microwave frequencies. combined with rhe available spoxroscopic dam. yield C, = 5673.214@5) MHz and D,, = 4.4(15) kHr.

Infrared laser-microwave double resonance spectroscopy has been used to observe tunneling transitions in the nu1 and nu3 hydrogen stretching states of NH3 . Inversion frequencies in 15 rotational states of nu1 and 6 rotational states of nu3 were measured to accuracies of ±25 kHz. Comparisons between