Atomic transport dynamics in crossed optical dipole trap

TL;DR

This paper investigates the dynamics of cold atoms in a crossed optical dipole trap, revealing a novel phenomenon where atomic number initially increases due to loading effects, especially relevant in microgravity environments.

Contribution

It introduces a theoretical model capturing the competition between atomic loading and loss, and experimentally demonstrates the initial increase in atomic number under certain conditions.

Findings

Atomic number in the trap can initially increase due to loading.

Theoretical model aligns well with experimental data.

Predicted behaviors vary under different conditions.

Abstract

We study the dynamical evolution of cold atoms in crossed optical dipole trap theoretically and experimentally. The atomic transport process is accompanied by two competitive kinds of physical mechanics, atomic loading and atomic loss. The loading process normally is negligible in the evaporative cooling experiment on the ground, while it is significant in the preparation of ultra-cold atoms in the space station. Normally, the atomic loading process is much weaker than the atomic loss process, and the atomic number in the center region of the trap decreases monotonically, as reported in previous research. However, when the atomic loading process is comparable to the atomic loss process, the atomic number in the center region of the trap will initially increase to a maximum value and then slowly decrease, and we have observed the phenomenon first. The increase of atomic number in the center region of the trap shows the presence of the loading process, and this will be significant especially under microgravity conditions. We build a theoretical model to analyze the competitive relationship, which coincides with the experimental results well. Furthermore, we have also given the predicted evolutionary behaviors under different conditions. This research provides a solid foundation for further understanding of the atomic transport process in traps. The analysis of loading process is of significant importance for the preparation of ultra-cold atoms in a crossed optical dipole trap under microgravity conditions.