Reducing number fluctuations in an ultracold atomic sample using Faraday rotation and iterative feedback
Abstract
We demonstrate a method to reduce number fluctuations in an ultracold atomic sample using real-time feedback. By measuring the Faraday rotation of an off-resonant probe laser beam with a pair of avalanche photodetectors in a polarimetric setup we produce a proxy for the number of atoms in the sample. We iteratively remove a fraction of the excess atoms from the sample to converge on a target proxy value in a way that is insensitive to environmental perturbations and robust to errors in light polarization. Using absorption imaging for out-of-loop verification, we demonstrate a reduction in the number fluctuations from to for samples at a temperature of 16.4 K over the time-scale of several hours which is limited by temperature fluctuations, beam pointing noise, and photon shot noise.
Cite
@article{arxiv.2102.01773,
title = {Reducing number fluctuations in an ultracold atomic sample using Faraday rotation and iterative feedback},
author = {R. Thomas and J. S. Otto and M. Chilcott and A. B. Deb and N. Kjærgaard},
journal= {arXiv preprint arXiv:2102.01773},
year = {2021}
}
Comments
This updated version is based on new data set