Metrology in a two-electron atom: The ionization energy of metastable triplet helium (2\,3S1)

Abstract

Helium (He) is the ideal atom to perform tests of ab-initio calculations in two-electron systems that consider all known effects, including quantum-electrodynamics and nuclear-size contributions. Recent state-of-the-art calculations and measurements of energy intervals involving the He 2\;3S1 metastable state reveal discrepancies at the level of 7\,σ that require clarification both from the experimental and theoretical sides. We report on a new determination, with unprecedented accuracy, of the ionization energy EI\,(2\;3S1) of the (1s)(2s)\;3S1 metastable state of He. The measurements rely on a new approach combining interferometric laser-alignment control, SI-traceable frequency calibration and imaging-assisted Doppler-free spectroscopy. With this approach we record spectra of the np Rydberg series in a highly-collimated cold supersonic beam of metastable He generated by a cryogenic valve and an electric discharge. Extrapolation of the Rydberg series yields a new value of the ionization energy (EI\,(2\;3S1)/h= 1\,152\,842\,742.7082(55)stat(25)sys\,MHz) that deviates by 9\,σ from the most precise theoretical result (1\,152\,842\,742.231(52)\;MHz), reported by Patk\'os, Yerokhin and Pachucki [Phys. Rev. A. 103, 042809 (2021)], confirming earlier discrepancies between experiment and theory in this fundamental system.