High-Resolution Spectroscopy of 173Yb+ Ions

Abstract

Compared to other stable isotopes of Yb+, 173Yb+ has a richer hyperfine structure, which leads to more favorable clock transitions, spectroscopic techniques for probing new physics, and more sophisticated quantum computing architectures. However, to date, its electronic spectrum remains poorly characterized. Here, we report on efficient laser cooling, state preparation, and detection of a single trapped 173Yb+ ion. The previously unobserved 2\!S1/2 → 2\!D3/2 electric quadrupole transition at 436 nm is coherently excited, and the isotope shift between 171Yb+ and 173Yb+ on this transition is determined with an uncertainty of 1.4 Hz. Using microwave spectroscopy, we resolve the hyperfine structure (HFS) of the 2\!D3/2 state with a relative uncertainty below 10-8. From the HFS measurement data, we infer for 173Yb a nuclear magnetic octupole moment = -0.062(8)\,( b × μN) with uncertainty reduced by more than 2 orders of magnitude compared to previous studies. The data also allow us to determine hyperfine anomalies for the 2\!S1/2 and 2\!D3/2 states.