Molecular jet study and calculations of the vibronic structure of the aniline-benzene van der Waals complex

Rotational coherence spectroscopy has been used to measure rotational constants for four isotopomers of the aromatlc-aromatic dimer petylene-benzene. Possibilities for the vibrationally averaged dimer geometry have been deduced from the measured values. In the geometries the benzene moiety is close

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

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

Four van der Waals vibrational states of the (benzene-Ar)\* cation are selectively excited by resonanmenhanced two-photon ionization and detected with the delayed pulsed field threshold ionization technique. Selection of different intermediate van der Waals states in the 6'(S,) state of the neutral

Molecular volumes for hydrocarbons, amino acids, peptides, and 14 globular proteins were calculated by techniques using van der Waals radii and by semiempirical molecular orbital methods. The resulting values were compared to experimentally determined volumes. The values obtained by methods employin

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)