Fourier-transform spectroscopy and global deperturbation treatment of the A1+u and b3u states of K2 in the entire bound energy range
Abstract
Rotationally-resolved Fourier-transform spectra of laser-induced fluorescence (LIF) A1+u b3u → X1+g of K2 molecules were recorded and analyzed yielding 4053 term values of spin-orbit (SO) coupled A b complex of 39K2 isotopologue with ca 0.01 cm-1 accuracy. Their compilation with 1739 term values from previously published sources allowed to cover the energy range [9955, 17436] cm-1 from the bottom of the lower-lying b3u state up to the vicinity of the atomic asymptote 4s\;2 S1/2 + 4p\;2 P1/2, with rotational quantum number J∈[0,149]. The experimental data were processed by a direct 6×6 coupled-channel (CC) deperturbation treatment, which accounted explicitly for both SO and electronic-rotational interactions between six states: A1+u(0), b3u(0,1,2), c3u(1), and B1u(1). The initial parameters of the global deperturbation model have been estimated in the framework of ab initio electronic structure calculations applying multi-referenced configuration-interaction and coupled-clusters methods. The interatomic potentials analytically defined for A and b states, as well as SO-splitting of the triplet b state and A b SO-coupling functions have been refined to fit 5792 term values of the 39K2 isotopologue, whereas the rest parameters were fixed on their ab initio values. The resulting mass-invariant parameters of the CC model reproduced the overall rovibronic term energies of the A b complex of 39K2 with the accuracy, which is well within the experimental errors. This deperturbation analysis provided the refined dissociation energy Tdis=17474.569(5) cm-1 and the long-range coefficient C3 = 5.501(4) ×105cm-1 A3 relevant to the non-relativistic atomic limit 4s+4p.
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