Electro-optic frequency comb Doppler thermometry
Abstract
We demonstrate a Doppler thermometer based on direct optical frequency comb spectroscopy of an Rb vapor with a chirped electro-optic frequency comb (EOFC). The direct EOFC Doppler thermometer is accurate to within its approximately 1 K statistical uncertainty. We experimentally compare direct EOFC spectroscopy with conventional Doppler spectroscopy using a single-frequency, step-scanned laser probe. Our results show that direct EOFC spectroscopy mitigates transit-induced optical pumping distortion of the atomic lineshape, which is the dominant systematic temperature shift in alkali atom Doppler thermometry. Optical Bloch equation simulations of conventional and direct EOFC Doppler spectroscopy confirm that EOFC spectroscopy can use higher optical power to reduce statistical noise without optical pumping distortion. Our results indicate that EOFC Doppler thermometry is a promising approach to realizing a primary thermometer with size and measurement rate sufficient for applications including pharmaceutical manufacturing and nuclear waste monitoring.
Keywords
Cite
@article{arxiv.2601.10575,
title = {Electro-optic frequency comb Doppler thermometry},
author = {Sean M. Bresler and Erin M. Adkins and Stephen P. Eckel and Tobias K. Herman and David A. Long and Benjamin J. Reschovsky and Daniel S. Barker},
journal= {arXiv preprint arXiv:2601.10575},
year = {2026}
}
Comments
10 pages, 4 figures