Simultaneous Determination of Multiple Nuclear Parameters of 229Th Using Highly Charged Ions

Abstract

Development of a 229Th nuclear optical clock requires precise and model-insensitive nuclear-structure parameters, which presently suffer from limited accuracy and poor consistency. We propose a joint spectroscopy scheme using two highly charged 229Th ions with J=1/2 electronic ground states, where the lowest electronic excitation energy of each ion far exceeds the nuclear transition energy. This configuration effectively forms a three-level system comprising the electronic ground state and the nuclear ground (g) and isomeric (m) states, resulting in strongly enhanced nuclear hyperfine mixing. Within this framework, a unified analysis of precision measurements on both ions enables the simultaneous determination of five key nuclear parameters without relying on external nuclear inputs: the magnetic dipole moments μg and μm, the bare-nucleus transition energy ωn, the charge-radius difference δ r2gm, and the M1 transition matrix element TM1. With this approach, the uncertainties in ωn and δ r2gm are estimated to be reduced by factors of 3 and 2, respectively, relative to their current uncertainties. %compared with current values. This work could provide a useful benchmark for nuclear theory and serve as a foundation for future development of a 229Th-based nuclear optical clock.