Rotational Spectroscopy as a Tool to Study Vibration-Rotation Interaction: Investigations of 13CH3CN and CH313CN up to v8 = 2 and a Search for v8 = 2 Transitions toward Sagittarius B2(N)

Abstract

Methyl cyanide, CH3CN, is present in diverse regions in space, in particular in the warm parts of star-forming regions where it is a common molecule. Rotational transitions of 13CH3CN and CH313CN in their v8 = 1 lowest excited vibrational states (E vib ≈ 520 K) are quite prominent in Sagittarius B2(N). In order to be able to search for transitions of the next higher vibrational state v8 = 2, we recorded spectra of samples enriched in 13CH3CN and CH313CN up to v8 = 2 in the 35 to 1091~GHz region and reinvestigated existing spectra of CH3CN in its natural isotopic composition between 1085 and 1200 GHz. Perturbations caused by near-degeneracies in K = 4 of v8 = 20 and K = 2 of v8 = 2-2 yielded accurate information on the energy spacing of 22.93 and 21.79 cm-1 between the l-components of 13CH3CN and CH313CN, respectively. Fermi-type interaction between K = 13 and 14 of v8 = 1-1 and v8 = 2+2 probe the energy differences between the two states of both isotopomers. In addition, a K 2, l 1 interaction between the ground vibrational state of 13CH3CN and v8 = 1+1 provides information on their energy spacing. Furthermore, we obtained improved or extended ground state rotational transition frequencies of 13CH313CN and extensive data for 13CH3C15N and CH313C15N. Finally, we report the results of our search for transitions of 13CH3CN and CH313CN in their v8 = 2 states toward Sagittarius B2(N).