English

Zeeman-tunable Modulation Transfer Spectroscopy

Atomic Physics 2020-01-08 v4 Instrumentation and Detectors Optics Quantum Physics

Abstract

Active frequency stabilization of a laser to an atomic or molecular resonance underpins many modern-day AMO physics experiments. With a flat background and high signal-to-noise ratio, modulation transfer spectroscopy (MTS) offers an accurate and stable method for laser locking. Despite its benefits, however, the four-wave mixing process that is inherent to the MTS technique entails that the strongest modulation transfer signals are only observed for closed transitions, excluding MTS from numerous applications. Here, we report for the first time the observation of a magnetically tunable MTS error signal. Using a simple two-magnet arrangement, we show that the error signal for the 87^{87}Rb F=2F=3F=2 \rightarrow F'=3 cooling transition can be Zeeman-shifted over a range of >>15 GHz to any arbitrary point on the rubidium D2\text{D}_2 spectrum. Modulation transfer signals for locking to the 87^{87}Rb F=1F=2F=1 \rightarrow F'=2 repumping transition as well as 1 GHz red-detuned to the cooling transition are presented to demonstrate the versatility of this technique, which can readily be extended to the locking of Raman and lattice lasers.

Keywords

Cite

@article{arxiv.1906.04154,
  title  = {Zeeman-tunable Modulation Transfer Spectroscopy},
  author = {Chloe So and Nicholas L. R. Spong and Charles Möhl and Yuechun Jiao and Teodora Ilieva and Charles S. Adams},
  journal= {arXiv preprint arXiv:1906.04154},
  year   = {2020}
}

Comments

5 pages, 5 figures

R2 v1 2026-06-23T09:49:13.479Z