Doppler Shift Mitigation in a Chip-Scale Atomic Beam Clock
Abstract
Chip-scale microwave atomic systems based on thermal atomic beams offer a promising approach to realize low-power and low-drift clocks for timing holdover applications. Miniature beam clocks are expected to suppress many of the shifts that commonly limit existing chip-scale atomic clocks based on coherent population trapping, including collisional shifts and some light shifts. However, the beam geometry can amplify some challenges such as Doppler shifts, which generate a strong sensitivity to laser frequency variation. Using a cm-scale 87Rb atom beam clock, we identify a surprisingly strong competition between Doppler shifts and resonant light shifts arising from asymmetric decay in the clock spectroscopy {\Lambda}-system. Leveraging this competition between Doppler and resonant light shifts, we demonstrate clock operation at specific, convenient experimental parameters consistent with zero sensitivity to laser frequency variation and white-noise-limited clock frequency averaging for 1000 s of integration.
Cite
@article{arxiv.2512.04905,
title = {Doppler Shift Mitigation in a Chip-Scale Atomic Beam Clock},
author = {Alexander Staron and Gabriela Martinez and Nicholas Nardelli and Travis Autry and John Kitching and William McGehee},
journal= {arXiv preprint arXiv:2512.04905},
year = {2026}
}