Revised 3He nuclear charge radius due to electronic hyperfine mixing

Abstract

The significant discrepancy in the difference of squared nuclear charge radii R2 of 3,4He obtained from electronic-atom or muonic-atom energy levels is a puzzle. In this paper, we show that the tension is resolved by including off-diagonal mixing effects due to the hyperfine interaction. Our findings indicate that the hyperfine mixing effect from the n\,3\!S and n\,1\!S states (n>2) of 3He leads to a -1.37 kHz adjustment in the isotope shift of the 2\,1\!S-2\,3\!S transition, surpassing the current uncertainty by a factor of 7. This results in a change of -0.0064~fm2 in R2, shifting from 1.0757(15)~fm2 to 1.0693(15)~fm2 as determined by Werf et al., significantly reducing the discrepancy with the value of 1.0636(31)~fm2 determined by μHe+, and aligning with the result of 1.069(3) fm2 obtained from the 2\,3\!S-2\,3\!P transition. This adjustment will result in a noticeable change in the absolute nuclear charge radius of 3He by -0.0017~fm, aligning the revised value of 1.9715(11)~fm with the value of 1.97007(94)~fm determined by μ3He+ within 1σ. Our results offer crucial insights into resolving discrepancy in R2 for 3,4He and determining the charge radius of 3He.