A Magneto-Optical Trap of Titanium Atoms

Abstract

We realize laser cooling and trapping of titanium (Ti) atoms in a mangeto-optical trap (MOT). While Ti does not possess a transition suitable for laser cooling out of its 3d24s2 a3F ground term, there is such a transition, at an optical wavelength of λ=498nm, from the long-lived 3d3(4F)4s a5F5 metastable state to the 3d3(4F)4p y5Go6 excited state. Without the addition of any repumping light, we observe MOTs of metastable 46Ti, 48Ti, and 50Ti, the three stable nuclear-spin-zero bosonic isotopes of Ti. While MOTs can be observed when loaded directly from our Ti sublimation source, optical pumping of ground term atoms to the a5F5 state increases the loading rate by a factor of 120, and the steady-state MOT atom number by a factor of 30. At steady state, the MOT of 48Ti holds up to 8.30(26)×105 atoms at a maximum density of 1.3(4)×1011cm-3 and at a temperature of 90(15)μ K. By measuring the decay of the MOT upon suddenly reducing the loading rate, we place upper bounds on the leakage branching ratio of the cooling transition (≤2.5× 10-6) and the two-body loss coefficient (≤2×10-10cm3s-1). Our approach to laser cooling Ti can be applied to other transition metals, enabling a significant expansion of the elements that can be laser cooled.