Relativistic recoil as a key to the fine-structure puzzle in muonic 90Zr

Abstract

The long-standing fine-structure anomaly in muonic 90Zr is resolved through a rigorous treatment of the relativistic-recoil effect. From a fit of ab initio QED calculations of the muonic 90Zr spectrum to precision measurements performed four decades ago, we extract a significantly more precise root-mean-square (rms) charge radius with 6-fold improvement in quality of the fit. A 2-parameter Fermi (2pF) distribution is assumed to model the nuclear charge density and yields a best-fit value of rms charge radius of rrms[90Zr]=4.2732(7) fm (2 /DoF = 0.995), in agreement with the previous muonic spectroscopy value, but a factor 6 more precise, and 3σ larger than the accepted literature value. Additionally, the same analysis has been performed for 120Sn, where the extracted value of rrms[120Sn]=4.6518(34) fm (2 /DoF = 0.88) is consistent with the accepted value. These results confirm our assumption that the muonic fine-structure puzzle arose from an incomplete treatment of QED effects and their uncertainties.

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