Testing quantum electrodynamics in the lowest singlet states of beryllium atom

Abstract

High-precision results are reported for the energy levels of 21S and 21P states of the beryllium atom. Calculations are performed using fully correlated Gaussian basis sets and taking into account the relativistic, quantum electrodynamics (QED), and finite nuclear mass effects. Theoretical predictions for the ionization potential of the beryllium ground state 75\,192.699(7) and the 21P → 21S transition energy 42\,565.441(11) are compared to the known but less accurate experimental values. The accuracy of the four-electron computations approaches that achieved for the three-electron atoms, which enables determination of the nuclear charge radii and precision tests of QED.