Atomic Quantum Sensor for Ultralow-Frequency Electric Field Measurements

Rydberg-assisted atomic electrometry with thermal vapors offers a promising approach for detecting external electric fields. This technique, however, has proven quite challenging for measuring low frequencies because of the effects of metal-alkali atoms absorbing on the interior surface of the vacuum enclosure. We apply high-contrast Rydberg-electromagnetically-induced-transparency (EIT) spectroscopy to investigate the impact systematically, including laser power and electric field. Our system enhances frequency measurements below 10 Hz, demonstrating significant progress in improving the performance of Rydberg atomic electrometry. Consequently, our study reveals a standard quantum limit for data capacity and experimentally illustrates it across bandwidths ranging from 10 Hz to 1 MHz. This study provides valuable insights for future precision measurements and field sensing applications.
Comment: 7 pages, 5 figures