Abstract
Microscopically controlled neutral atoms in optical tweezers and lattices have led to exciting advances in the study of quantum information and quantum many-body systems. The light shifts of atomic levels from the trapping potential in these systems can result in detrimental effects such as fluctuating dipole force heating, inhomogeneous detunings, and inhibition of laser cooling, which limits the atomic species that can be manipulated. In particular, these light shifts can be large enough to prevent loading into optical tweezers directly from a magneto-optical trap. We implement a general solution to these limitations by loading, as well as cooling and imaging the atoms with temporally alternating beams, and present an analysis of the role of heating and required cooling for single atom tweezer loading. Because this technique does not depend on any specific spectral properties, it should enable the optical tweezer platform to be extended to nearly any atomic or molecular species that can be laser cooled and optically trapped.
Highlights
Interacting neutral atoms with quantum controls are a powerful platform for studies of quantum information and quantum many-body physics
We load single atoms of cesium (Cs) and sodium (Na) from magneto-optical traps, and demonstrate the effectiveness of modulation when applied to single atom traps where the conventional loading method [1] fails due to light shifts
2 We find that the resonant light can be modulated at all times and still yield a dense MOT with temperature 2Tdopp, and that polarization gradient cooling (PGC) with modulated beams yields temperatures similar to those achieved with unmodulated (CW) beams
Summary
These light shifts can be large enough to prevent and DOI.
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