Use of an effective Schrödinger equation for calculating the vibrational energy spacings of H2+ and D2+

It is shown that for Hz and its isotopes, the clcctronic Schrddinger equation involving the ekctron rest mass me can be related m a simple way to that involving the electron reduced mass me = m&n, + mb)/(me + m, + mb) by a straight-forward scahng of all distances in the first of these equations by p

Many-body perturbation theory and coupled-cluster calculations for the energy and dipole moment of Hz0 are performed using different techniques to reduce the virtual space. The optimized virtual orbital space (OVOS) method is compared with frozen natural orbitals (FNO), defined from a relaxed densit

Recent independent experimental determinations. by Za.re and Valentini and their co-workers, of the HD product state distribution are consistent with a common set of surprkal parameters: h, = 2 and 0R in the range 3-5. Analysis of rhe computational results of Blais and Trublar su,, ~oests that a som

## Abstract A finite element method approach for solving the three‐dimensional Schrödinger equation expressed in hyperspherical coordinates is applied to the calculation of rovibrational states of H~2~O and D~2~O. Comparisons to experimental values and other theoretical calculations are offered.