English

Optimization and vectorization of a Mz-type optically-pumped Rubidium magnetometer

Atomic Physics 2026-04-06 v1

Abstract

Optically pumped magnetometers (OPMs) have demonstrated significant potential in weak magnetic field detection due to their high sensitivity. In this study, we developed an Mz-type optically pumped rubidium magnetometer using a paraffin-coated anti-relaxation vapor cell. The system optimization and performance characterization were conducted inside a magnetic shield. Specifically, the pump light intensity and radio-frequency (RF) magnetic field were jointly optimized by using the linewidth-amplitude ratio as the core metric. Based on the frequency-domain noise spectrum, the sensitivity in open-loop mode was measured to be approximately 30.8 pT/Hz^{1/2}. Furthermore, a closed-loop feedback locking technique was applied, reducing the measured noise floor under the tested conditions and improving the sensitivity to 22.9 pT/Hz^{1/2}, with a measured -3 dB bandwidth of 123 Hz. The dynamic characteristics were evaluated via magnetic-field step response, showing that the system could track magnetic-field changes stably under closed-loop operation. Finally, by using tri-axial modulation and frequency-domain demodulation, we overcame the scalar measurement limitation of traditional Mz magnetometers. This work realizes vector magnetic field detection and provides a technical basis for applications such as geomagnetic navigation and magnetic anomaly detection.

Keywords

Cite

@article{arxiv.2604.02884,
  title  = {Optimization and vectorization of a Mz-type optically-pumped Rubidium magnetometer},
  author = {Zhengyu Su and Yang Li and Yongbiao Yang and Yanhua Wang and Jun He and Junmin Wang},
  journal= {arXiv preprint arXiv:2604.02884},
  year   = {2026}
}
R2 v1 2026-07-01T11:52:36.133Z