Theory for the Rydberg states of helium: Results for 2 n 35 and comparison with experiment for the singlet and triplet P-states
Abstract
High precision variational calculations in Hylleraas coordinates are presented for all singlet and triplet P-states of helium up to principal quantum number n = 35 with a uniform accuracy of 1 part in 1022 for the nonrelativistic energy. Mass polarization, relativistic and quantum electrodynamic effects are included to achieve a final accuracy of 1 kHz or better for the ionization energy of the Rydberg states of 4He in the range 24 n 35. The results are combined with 11 transition frequency measurements of Clausen et al. Phys. Rev. A 111, 012817 (2025) to obtain complementary measurements of the ionization energy of the 1s2s\;3S1 state that do not depend on quantum defect extrapolations to the series limit. The result from the triplet spectrum yields an ionization energy of 1152 842 742.728(6) MHz, which agrees with but is larger than the experimental value by 14 17 kHz. However, it confirms a much larger 9σ discrepancy of 0.4680.055 MHz with the theoretical ionization energy of Patk\'os et al. Phys. Rev. A 103, 042809 (2021). The results provide a test of the quantum defect extrapolation method at the level of 17 kHz. This revised version contains an additional table of spin-dependent matrix elements of the Breit interaction in the appendix for 24 n 35. (12 pages, 1 figure).
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