Continuous loading of 1S0 calcium atoms into an optical dipole trap

Abstract

We demonstrate an efficient scheme for continuous trap loading based upon spatially selective optical pumping. We discuss the case of 1S0 calcium atoms in an optical dipole trap (ODT), however, similar strategies should be applicable to a wide range of atomic species. Our starting point is a reservoir of moderately cold (≈ 300 μK) metastable 3P2-atoms prepared by means of a magneto-optic trap (triplet-MOT). A focused 532 nm laser beam produces a strongly elongated optical potential for 1S0-atoms with up to 350 μK well depth. A weak focused laser beam at 430 nm, carefully superimposed upon the ODT beam, selectively pumps the 3P2-atoms inside the capture volume to the singlet state, where they are confined by the ODT. The triplet-MOT perpetually refills the capture volume with 3P2-atoms thus providing a continuous stream of cold atoms into the ODT at a rate of 107 s-1. Limited by evaporation loss, in 200 ms we typically load 5 × 105 atoms with an initial radial temperature of 85 μK. After terminating the loading we observe evaporation during 50 ms leaving us with 105 atoms at radial temperatures close to 40 μK and a peak phase space density of 6.8 × 10-5. We point out that a comparable scheme could be employed to load a dipole trap with 3P0-atoms.