High-accuracy Rb$_{2}^+$ interaction potentials based on coupled cluster calculations
Abstract
This work discusses a protocol for constructing highly accurate potential energy curves (PECs) for the lowest two states of Rb, i.e. and , using an additivity scheme based on coupled-cluster theory. The approach exploits the findings of our previous work [J. Schnabel, L. Cheng and A. K\"ohn, J. Chem. Phys. 155, 124101 (2021)] to avoid the unphysical repulsive long-range barrier occurring for symmetric molecular ions when perturbative estimates of higher-order cluster operators are employed. Furthermore, care was taken to reproduce the physically correct exchange splitting of the and PECs. The accuracy of our computational approach is benchmarked for ionization energies of Rb and for spectroscopic constants as well as vibrational levels of the triplet state of Rb\textsubscript{2}. We study high-level correlation contributions, high-level relativistic effects and inner-shell correlation contributions and find very good agreement with experimental reference values for the atomic ionization potential and the binding energy of Rb in the triplet state. Our final best estimate for the binding energy of the Rb state including zero-point vibrational contributions is with an estimated error bound of . This value is smaller than the experimentally inferred lower bond of [Bellos et al., Phys. Rev. A 87, 012508 (2013)] and will require further investigation. For the state a shallow potential with and an error bound of is computed.
Keywords
Cite
@article{arxiv.2206.10016,
title = {High-accuracy Rb$_{2}^+$ interaction potentials based on coupled cluster calculations},
author = {Jan Schnabel and Lan Cheng and Andreas Köhn},
journal= {arXiv preprint arXiv:2206.10016},
year = {2022}
}