Theoretical Evidence for the Formation of Rotational Energy Level Clusters in the Vibrational Ground State of PH3.

has been used to determine effective bending potentials and reduced masses for C 3 in the lowest stretching vibrational states by performing a Born-Oppenheimer separation of the bending and stretching motions. These calculations were based on a potential energy function obtained in a least-squares f

The present paper reports experimental evidence for the "cluster effect" (i.e., the formation of nearly degenerate, four-member groups of rotation-vibration energy levels at high rotational excitation) in the \(v_{1} / \nu_{3}\) vibrational states of the \(\mathrm{H}_{2}{ }^{80} \mathrm{Se}\) molecu

Using recently published potential energy surfaces, rovibrational energy levels are computed for the ground electronic states of H O and NO , using three-2 2 Ž . dimensional discrete variable representation DVR algorithms. Calculations are presented for H O to demonstrate the accuracy of these algor

A representation of the effective rotational Hamiltonian in the form of optimum versions of a rational series of the perturbation theory is suggested for nonisolated molecular states. This representation is used to analyze the most complete set of precise transition frequencies in the rotational spe

We studied the hyperfine components of the ( J ϭ 10-9, Kl ϭ 9) rotational transition in the v 6 ϭ 1 excited vibrational state of CH 3 I, using collinear infrared and mm-wave radiations. The Doppler-free double-resonance technique allowed an accurate determination of the collisional broadening parame

## Abstracts of Papers to Appear in Future Issues Block Spin Renormalization Group for Dipole Gas and (V()'. K. GAWEDZKI. IHES,