Revised $^3$He nuclear charge radius due to electronic hyperfine mixing

arXiv - PHYS - Atomic Physics Pub Date : 2024-09-14 DOI:arxiv-2409.09279

Xiao-Qiu Qi, Pei-Pei Zhang, Zong-Chao Yan, Li-Yan Tang, Ai-Xi Chen, Ting-Yun Shi, Zhen-Xiang Zhong

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Abstract

The significant discrepancy in the difference of squared nuclear charge radii $\Delta R^2$ of $^{3,4}$He 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 $^3$He 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 $-0.0064~\rm{fm}^2$ in $\Delta R^2$, shifting from $1.0757(15)~\mathrm{fm}^2$ to $1.0693(15)~\mathrm{fm}^2$ as determined by Werf {\it et al.}, significantly reducing the discrepancy with the value of $1.0636(31)~\mathrm{fm}^2$ determined by $\mu\rm{He}^+$, and aligning with the result of $1.069(3)$ $\mathrm{fm}^2$ 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 $^{3}$He by $-0.0017~\rm{fm}$, aligning the revised value of $1.9715(11)~\mathrm{fm}$ with the value of $1.97007(94)~\mathrm{fm}$ determined by $\mu^3\rm{He}^+$ within $1\sigma$. Our results offer crucial insights into resolving discrepancy in $\Delta R^2$ for $^{3,4}$He and determining the charge radius of $^3$He.

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因电子超细混合而修订的 $^3$He 核电荷半径

从电子原子能级或渺子原子能级得到的$^{3,4}$He的核电荷半径平方的差异很大，这是一个难题。在本文中，我们展示了通过把超精细相互作用引起的对角线外混合效应包括进来，可以解决这个难题。我们的发现表明，来自$^3$He的$n,^3\!S$和$n,^1\!S$态（$n>2$）的超细混合效应导致$2,^1\!S-2\,^3\!S$转变的同位素位移发生了$1.37$千赫的调整，超过了当前不确定性的7$因子。这导致了 $Delta R^2$ 中 $-0.0064~\rm{fm}^2$ 的变化，从 Werf {\it et al.}，大大减少了与 $\mu\rm{He}^+$ 确定的 1.0636(31)~\mathrm{fm}^2$ 值的差异，并与从 2,^3\!S-2,^3\!P$转变中得到的 1.069(3)$$\mathrm{fm}^2$ 值保持一致。这一调整将导致$^{3}$He的绝对核电荷半径发生$-0.0017~\rm{fm}$的明显变化，从而使修订后的值$1.9715(11)~mathrm{fm}$与通过$\mu^3\rm{He}^+$确定的值$1.97007(94)~mathrm{fm}$保持在1\sigma$以内。我们的结果为解决$^{3,4}$He的$\Delta R^2$差异以及确定$^3$He的充电器半径提供了重要的启示。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Atomic Physics

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