Microwave Spectra, Structure, and Electric Dipole Moment of the Ar-Isocyanic Acid van der Waals Complex

Pulsed-beam Fourier transform microwave spectroscopy was used to observe and assign the rotational spectra of the argonketene van der Waals complex. Tunneling of the hydrogen or deuterium atoms splits the a-and b-type rotational transitions of H 2 CCO-Ar, H 2 13 CCO-Ar, H 2 C 13 CO-Ar, and D 2 CCO-A

Radiofrequency transitions within K = 2 asymmetry doublets have been observed for the CO2-CO van der Waals complex. A Stark effect measurement on the J = 2, K = 2 transition provides an electric dipole moment of µ = 0.2493(1) D. Combining this result with the permanent moment of CO, µCO = 0.1098 D,

The argon-acetaldehyde van der Waals dimer was studied by Fourier transform microwave spectroscopy. Two tunneling motions were observed in the spectrum, an inversion through a planar configuration and methyl internal rotation. A simple deperturbation technique was employed in order to obtain rotatio

Using a pulsed molecular beam microwave Fourier transform spectrometer, we measured the rotational spectrum of the 1.2 -difluorobenzene-argon van der Waals complex in the range from 7 to \(18 \mathrm{GHz}\). The rotational and centrifugal distortion constants were found to be \(A=\) \(1373.49072(9)

Laser-induced fluorescence spectra of Ne-and Ar-aniline complexes were observed with a resolution of 0.04 cm-l . By a simulation analysis of the rotational strucfures, the distances between the rare-gas atom and the aromatic ring of aniline were found fo be 3.35 f 0.04 and 3.50 + 0.04 4 in the X 'Al