An ab initio calculation of the rotation-vibration energies of the X̃2Σ+ state of CCH using the nonrigid bender Hamiltonian

For the % 'B,, g 'A, and 6 ' B, electronic states of the NH,+ molecular ion we have calculated ab initio points on the potential energy surfaces using a complete second-order configuration interaction calculation for the six valence electrons. For the % and fi states the rotation-vibration energies

A three-dimensional fit of ab initio MRD CI potential data has been made for the lowest two electronic states of the HNCl molecule (2 'A" and .& 'A'), and the corresponding vibrational frequencies and rotational energies have been computed using the non-rigid bender Hamiltonian. For the ground state

WC have calculated 64 points on the ground electronic state potential energy surface of the silyl radical (SiHs) using the MRD CI technique. This potential surface gives an inversion barrier of 1951 cm-' and an equilibrium geometry of re = 1.480 A and ae(HSiH) = 1 1 1 .?. Using the non-rigid inverto

On the basis of a previously published ab initio potential surface for the \(\mathrm{CO}\) dimer [A. van der Pol. A. van der Avoird and P. E. S. Wormer. J. Chem. Phys. 92, 7498-7504 (1990): the potential assumes fixed \([O\) bondlengths] we have calculated the \(J<3\) rotation-vibration energies bel