<i>In situ</i> equalization of single-atom loading in large-scale optical tweezer arrays
Kai-Niklas Schymik, Bruno Ximenez, Étienne Bloch, Davide Dreon, Adrien Signoles, Florence Nogrette, Daniel Barredo, Antoine Browaeys, Thierry Lahaye
Abstract
We report on the realization of large assembled arrays of more than 300 single $^{87}\mathrm{Rb}$ atoms trapped in optical tweezers in a cryogenic environment at $\ensuremath{\sim}4$ K. For arrays with ${N}_{\mathrm{a}}=324$ atoms, the assembly process results in defect-free arrays in $\ensuremath{\sim}37%$ of the realizations. To achieve this high assembling efficiency, we equalize the loading probability of the traps within the array using a closed-loop optimization of the power of each optical tweezer, based on the analysis of the fluorescence time traces of atoms loaded in the traps.
Topics & Concepts
Optical tweezersRealization (probability)TweezersAtom (system on chip)FluorescenceMaterials sciencePhysicsAtomic physicsMolecular physicsOpticsComputer scienceMathematicsEmbedded systemStatisticsCold Atom Physics and Bose-Einstein CondensatesQuantum Information and CryptographyOrbital Angular Momentum in Optics