H2+, HeH and H2: approximating potential curves, calculating rovibrational states

Abstract

Analytic consideration of the Bohr-Oppenheimer (BO) approximation for diatomic molecules is proposed: accurate analytic interpolation for potential curve consistent with its rovibrational spectra is found. It is shown that in the Bohr-Oppenheimer approximation for four lowest electronic states 1sσg and 2pσu, 2p πu and 3d πg of H2+, the ground state X2+ of HeH and the two lowest states 1+g and 3+u of H2, the potential curves can be analytically interpolated in full range of internuclear distances R with not less than 4-5-6 figures. Approximation based on matching the Taylor-type expansion at small R and a combination of the multipole expansion with one-instanton type contribution at large distances R is given by two-point Pad\'e approximant. The position of minimum, when exists, is predicted within 1\% or better. For the molecular ion H2+ in the Lagrange mesh method, the spectra of vibrational, rotational and rovibrational states (,L) associated with 1sσg and 2pσu, 2p πu and 3d πg potential curves is calculated. In general, 1sσg electronic curve contains 420 rovibrational states, which increases up to 423 when we are beyond BO approximation. For the state 2pσu the total number of rovibrational states (all with =0) is equal to 3, within or beyond Bohr-Oppenheimer approximation. As for the state 2pπu within the Bohr-Oppenheimer approximation the total number of the rovibrational bound states is equal to 284. The state 3dπg is repulsive, no rovibrational state is found. The ground state potential curve of the heteronuclear molecule HeH does not support rovibrational states. Accurate analytical expression for the potential curves of the hydrogen molecule H2 for the states 1+g and 3+u is presented.