Potential energy curve for the a3u+ state of lithium dimer with Slater-type orbitals

Abstract

We report state-of-the-art ab initio calculations of the potential energy curve for the a3u+ state of the lithium dimer conducted to achieve spectroscopic accuracy (<1cm-1) without any prior adjustment to fit the corresponding experimental data. The nonrelativistic clamped-nuclei component of the interaction energy is calculated with a composite method involving six-electron coupled cluster and full configuration interaction theories combined with basis sets of Slater-type orbitals ranging in quality from double- to sextuple-zeta. To go beyond the nonrelativistic Born-Oppenheimer picture we include both the leading-order relativistic and adiabatic corrections, and find both of these effects to be non-negligible within the present accuracy standards. The potential energy curve developed by us allowed to calculate molecular parameters (De, D0, ωe etc.) for this system, as well as the corresponding vibrational energy levels, with an error of only a few tenths of a wavenumber (0.2-0.4\,cm-1). We also report an ab initio value for the scattering length of two 2S lithium atoms which determines the stability of the related Bose-Einstein condensate.