The ground electronic state of CS: the potential curve and associated Born-Oppenheimer rovibrational spectrum

Abstract

Basics of the Born-Oppenheimer (B-O) approximation are reviewed. Assuming the domain of applicability of B-O approximation is limited to 4 significant digits (s.d.) in energy spectrum, where mass, relativistic and QED corrections do NOT contribute, it is shown that for carbon monosulfide C\, S the potential curve V(R) for the electronic ground state X1+ can be constructed analytically in the form of two-point Pade approximant 1R\ P(5,10)(R) in the whole range of internuclear distances R ∈ [0,∞). Pade approximant is fixed by taking into account the turning points with 4 s.d. accuracy, found by Coxon and Hajigeorgiou (2023), and asymptotics at small and large internuclear distances, By solving two-body radial nuclear Schr\"odinger equation with the potential V(R) (with standard centrifugal potential included) in the Lagrange Mesh method, the whole B-O rovibrational spectrum for 12 C\,32 S diatomic molecule (taken as a particular example) is found: the 14562 rovibrational energy states with angular momentum Lmax=289 and vibrational quantum number max 82 with accuracy 10-4 hartree in energy. It is shown that the experimentally observed transition energies are reproduced within 3-5 s.d. Critical analysis of existing theoretical (phenomenological) results on the rovibrational spectrum is carried out and its comparison with present ones is made.