Nonadiabatic energies of the ground state of the hydrogen molecule
- 1 August 1995
- journal article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 103 (5) , 1792-1799
- https://doi.org/10.1063/1.469753
Abstract
Possible sources of residual errors in the theoretical energies of the hydrogen molecule are investigated. Nonadiabatic corrections are computed for all bound, J≤10 X 1Σg+ ro-vibrational states of the six isotopic hydrogen molecules. The new results improve significantly the overall agreement with accurate experimental transition frequencies. In order to estimate the convergence errors of the Born–Oppenheimer energies generalized James–Coolidge functions with powers of the interelectronic distance, r12, up to 6 are used and the precision of the computations is increased. Except for the equilibrium separation, R=1.4011 bohr, the obtained potential energy curve is lower by a few thousandths of a wave number than any other reported variational result. This lowers the v=0 vibrational levels by 0.009 cm−1 and results in a dissociation energy of H2, D0=36118.069 cm−1.Keywords
This publication has 20 references indexed in Scilit:
- The equivalence of explicitly correlated Slater and Gaussian functions in variational quantum chemistry computations: The ground state of H2Chemical Physics Letters, 1994
- Extrapolated Born–Oppenheimer energy for the ground state of the hydrogen moleculeThe Journal of Chemical Physics, 1994
- Relativistic energies of the ground state of the hydrogen moleculeThe Journal of Chemical Physics, 1993
- Nonadiabatic energy corrections for the vibrational levels of the B and B′ 1Σ+u states of the H2 and D2 moleculesThe Journal of Chemical Physics, 1992
- Nonadiabatic eigenvalues and adiabatic matrix elements for all isotopes of diatomic hydrogenJournal of Molecular Spectroscopy, 1987
- Rotation-vibration spectrum of HT: Line position measurements of the 1-0, 4-0, and 5-0 bandsJournal of Molecular Spectroscopy, 1987
- The X 1Σ+g state vibration-rotational energies of the H2, HD, and D2 moleculesThe Journal of Chemical Physics, 1983
- Numerical integration of an inhomogeneous boundary value problemJournal of Computational Physics, 1981
- On the computation of dipole transitions in the HD molecule. Part IICanadian Journal of Physics, 1976
- Potential-Energy Curve for the B 1Σu+ State of the Hydrogen MoleculeThe Journal of Chemical Physics, 1966