Observation of Electric-Dipole Transitions in the Laser-Cooling Candidate Th-

Abstract

Despite the fact that the laser cooling method is a well-established technique to obtain ultra-cold neutral atoms and atomic cations, it has so far never been applied to atomic anions due to the lack of suitable electric-dipole transitions. Efforts of more than a decade currently has La- as the only promising candidate for laser cooling. Our previous work [Tang et al., Phys. Rev. Lett. 123, 203002(2019)] showed that Th- is also a potential candidate. Here we report on a combination of experimental and theoretical studies to determine the relevant transition frequencies, transition rates, and branching ratios in Th-. The resonant frequency of the laser cooling transition is determined to be /c = 4118.0 (10) cm-1. The transition rate is calculated as A=1.17x104 s-1. The branching fraction to dark states is very small, 1.47x10-10, thus this represents an ideal closed cycle for laser cooling. Since Th has zero nuclear spin, it is an excellent candidate to be used to sympathetically cool antiprotons in a Penning trap.