The hydrogen molecule H2 in inclined configuration in a weak magnetic field

Abstract

Highly accurate variational calculations, based on a few-parameter, physically adequate trial function, are carried out for the hydrogen molecule in inclined configuration, where the molecular axis forms an angle θ with respect to the direction of a uniform constant magnetic field B, for B=0,\, 0.1,\, 0.175 and 0.2\,a.u. Three inclinations θ=0,\,45,\,90 are studied in detail with emphasis to the ground state 1g. Diamagnetic and paramagnetic susceptibilities are calculated (for θ=45 for the first time), they are in agreement with the experimental data and with other calculations. For B=0,\, 0.1 and 0.2\,a.u. potential energy curves E vs R are built for each inclination, they are interpolated by simple, two-point Pad\'e approximant Pade[2/6](R) with accuracy of not less than 4 significant digits. Spectra of rovibrational states are calculated for the first time. It was found that the optimal configuration of the ground state for B ≤ Bcr=0.178\,a.u. corresponds always to the parallel configuration, θ=0, thus, it is a 1g state. The state 1g remains bound for any magnetic field, becoming metastable for B > Bcr, while for Bcr < B < 12\,a.u. the ground state corresponds to two isolated hydrogen atoms with parallel spins.