Hyperfine spectroscopy and laser cooling of the fermionic isotopes 47Ti and 49Ti

Abstract

We report on magneto-optical trapping of the two fermionic isotopes of atomic titanium, 47Ti and 49Ti. Unlike the even mass-number isotopes, which were recently laser cooled, 47Ti and 49Ti have nonzero nuclear spins and, consequently, their atomic levels are split by hyperfine structure. Combining and comparing theoretical calculations and atomic beam-spectroscopy measurements, we determine the hyperfine structures and isotope shifts of the 3d24s2 a3F4→ 3d2(3P)4s4p(3Po) y5D4o optical-pumping transition at optical wavelength 391nm and the 3d3(4F)4s a5F5→ 3d3(4F)4p y5G6o laser-cooling transition at wavelength 498nm. With this information, we produce magneto-optical traps of both 47Ti and 49Ti by applying two additional tones of light to repump atoms to the maximum-spin states on the laser-cooling transition. Directly loading from the atomic flux of a titanium sublimation pump, we produce 47Ti and 49Ti traps with 731(190) and 1142(240) atoms, and with lifetimes of 330(15)ms and 310(8)ms, respectively.