The a3+ state of KCs revisited: hyperfine structure analysis and potential refinement

Abstract

Laser-induced fluorescence spectra of the c3+(vc,Jc=Nc)→ a3+(va,Na = Jc 1) transitions excited from the ground X1+ state of 39K133Cs molecule were recorded with Fourier-transform spectrometer IFS125-HR (Bruker) at the highest achievable spectral resolution of 0.0063 cm-1. Systematic study of the hyperfine structure (HFS) of the a3+ state for levels with va ∈ [0, 27] and Na ∈ [24, 90] shows that the splitting monotonically increases with va. The spectroscopic study was supported by ab initio calculations of the magnetic hyperfine interaction in X1+ and a3+ states. The discovered variation of the electronic matrix elements with the internuclear distance R is in a good agreement with the observed va-dependencies of the HFS. Overall set of available experimental data on the a3+ state was used to improve the potential energy curve particularly near a bottom, providing the refined dissociation energy De=267.21(1) cm-1. The ab initio HFS matrix elements, combined with the empirical X1+ and a3+ PECs in the framework of the invented coupled-channel deperturbation model, reproduce the experimental term values of both ground states within 0.003 cm-1 accuracy up to their common dissociation limit.