An optimized single-beam dark optical trap

Summary form only given. Blue-detuned optical traps confine neutral atoms mostly in the dark, therefore reducing the perturbations induced by the trapping light on the atoms. Recently, traps based on a single laser beam were demonstrated, providing greater experimental simplicity and enabling dynamical changes of the trap geometry and strength. However, all these traps have a large difference in the potential strength in the radial and axial directions, resulting in a very inefficient use of the available laser power, and a poor loading efficiency from the magneto-optical trap. In this work we present a novel optical scheme to generate an optimal trap, which maximizes the trap depth, and greatly reduces the light-induced perturbations to the atoms. This is achieved by surrounding a dark volume with a light envelope having (a) an almost minimal surface area for a given volume, (b) the minimal wall thickness allowed by diffraction, and (c) an almost constant wall height on every point on the envelope. The stiffness of the walls, combined with the large detuning allowed by the efficient distribution of light intensity, yield a very low photon scattering rate for the trapped atoms.