Testing fundamental interactions on the helium atom
Abstract
We critically examine the current status of theoretical calculations of the energies, the fine structure, and the isotope shift of the lowest-lying states of helium, searching for unresolved discrepancies with experiments. Calculations are performed within the quantum electrodynamics expansion in powers of the fine structure constant and the electron-to-nucleus mass ratio . For energies, theoretical results are complete through orders and , with the resulting accuracy ranging from to ~MHz for the states. The fine-structure splitting of the state is predicted with a much better accuracy, 1.7~kHz, as a consequence of a calculation of the next-order effect. An excellent agreement of the theoretical predictions with the recent measurements of the fine structure provides one of the best tests of the bound-state QED in few-electron systems and determines the fine-structure constant with an accuracy of 31~ppb. The isotope shift between He and He is treated theoretically with a sub-kHz accuracy, which allows for a high-precision determination of the differences of the nuclear charge radii . Several such determinations, however, yield results that are in a 4 disagreement with each other, what remains unexplained. Apart from this, we find no significant discrepancies between theory and experiment for the helium atom. In the future, a calculation of the next-order effect for energy levels will enable determinations of the nuclear charge radii from atomic transition frequencies with an accuracy better than 1\%. Combined with the complementary determinations from muonic atoms, this will provide a sensitive test of universality in electromagnetic interactions of leptons and contribute to the solution of the proton charge radius puzzle.
Cite
@article{arxiv.1704.06902,
title = {Testing fundamental interactions on the helium atom},
author = {Krzysztof Pachucki and Vojtěch Patkóš and Vladimir Yerokhin},
journal= {arXiv preprint arXiv:1704.06902},
year = {2017}
}
Comments
9 pages, 1 figure