Flattening a trapped atomic gas using a programmable optical potential in a feedback loop
Abstract
We present a method for producing a flat, large-area Fermi gas of Li with a uniform area density. The method uses a programmable optical potential within a feedback loop to flatten the in-plane trapping potential for atoms. The optical potential is generated using a laser beam, whose intensity profile is adjusted by a spatial light modulator and optimized through measurements of the density distribution of the sample. The resulting planar sample exhibits a uniform area density within a region of about 480 m in diameter and the standard deviation of the trap bottom potential is estimated to be 6.1 nK, which is less than 20 of the transverse confinement energy. We discuss a dimensional crossover toward 2D regime by reducing the number of atoms in the planar trap, including the effect of the spatial variation of the transverse trapping frequency in the large-area sample.
Cite
@article{arxiv.2404.00238,
title = {Flattening a trapped atomic gas using a programmable optical potential in a feedback loop},
author = {Sol Kim and Kyuhwan Lee and Jongmin Kim and Y. Shin},
journal= {arXiv preprint arXiv:2404.00238},
year = {2024}
}
Comments
8 pages, 6 figures