15min:

RICHARD J. LAVRICH, CHARLES R. TOROK AND MICHAEL J. TUBERGEN, Department of Chemistry, Kent State University, Kent, OH 44242.

Rotational spectra of the van der Waals complexes of 2-aminoethanol-water and 2-aminoethanol-argon have been recorded using a Fourier-transform microwave spectrometer. Eleven a-~and~b-type transitions were fit to the Watson A-reduction Hamiltonian for 2-aminoethanol-water yielding A~=~4886.29 (7) MHz, B = 3355.93 (8) MHz, and C = 2311.66 (4) MHz, and twelve a-, b-, and c-type transitions for 2-aminoethanol-argon were fit to A = 4986.16 (12) MHz, B = 1330.190 (7) MHz, and C = 1143.831 (6) MHz. The spectra are identified with ab initio structures of the two complexes. The 2-aminoethanol monomer has an intramolecular hydrogen bond from the hydroxyl group to the amine; the O~-~C~-~C~-~N torsional angle is 58^\circ and the O~-~N distance is 2.83 Å. The argon complex is based on the 2-aminoethanol monomer conformation, and the argon sits 3.91 Å~from the nitrogen and 3.49 Å~ from the oxygen. The 2-aminoethanol-water complex is stabilized by hydrogen bonds from the hydroxyl to the water oxygen and from water to the amino nitrogen. Formation of the intermolecular hydrogen bonds requires the O~-~C~-~C~-~N torsional angle to increase to 71^\circ, and the O~-~N distance increases to 3.04 Å. Rotational spectra of the ¹³C isotopomers of the 2-aminoethanol monomer have been recorded and enable a substitution structure of the heavy atoms to be determined.