Continuous slowing of a gadolinium atomic beam

TL;DR

This paper introduces a novel method using a Quartz Crystal microbalance to characterize a gadolinium atomic beam's slowing process, providing a simple and effective tool for laser cooling experiments.

Contribution

It demonstrates the use of a QCM as a kinetic energy sensor to measure atomic beam velocity changes during laser cooling, offering a new approach for experimental characterization.

Findings

Achieved a 43.5% reduction in atom velocity.

Estimated electronic transition lifetime of 8.2 ns.

Validated QCM as a practical tool for laser cooling studies.

Abstract

The article presents the development of a new and innovative experimental method to fully characterize a solenoidal "spin-flip" Zeeman slower (ZS) using a Quartz Crystal $\mu$-balance (QCM) as a kinetic energy sensor. In this experiment, we focus a 447.1 nm laser into a counter-propagating beam of gadolinium (Gd) atoms in order to drive the dipole transition between ground $^{9}$D$^{0}_{2}$ state and $^{9}$D$_{3}$ excited state. The changes in the velocity of the beam were measured using a QCM during this process, as a novel and alternative method to characterize the efficiency of a 1 m-long spin-flip Zeeman slower. The QCM, normally used in solid-state physics, is continuously and carefully monitored to determine the change in its natural frequency of oscillation. These changes reveal a direct relation with changes in the deposition rate and the momentum exchanged between the QCM and Gd atoms. Hence, in terms of ultracold atom physics, it might be used to study the time-evolution of the velocity distribution of the atoms during the cooling process. By this method, we obtain a maximum atom average velocity reduction of (43.5 $\pm$ 6.4)$\%$ produced by our apparatus. Moreover, we estimate an experimental lifetime of $\tau_{e}$ = 8.2 ns for the used electronic transition, and then we compared it with the reported lifetime for 443.06 nm and 451.96 nm electronic transitions of Gd. These results confirm that the QCM offers an accessible and simple solution to take into account for laser cooling experiments. Therefore, a novel and innovative technique can be available for future experiments.