Electric Field Manipulation of Rydberg States for Very Low Frequency Fields Detection

Abstract: The very low frequency(VLF) band is widely used in submarine communication and geophysical exploration for its strong penetration and long-distance propagation. This paper theoretically and experimentally investigates Rydberg EIT in 133Cs vapor under VLF and DC fields. A model is established to describe the EIT spectral response under dual-field conditions, with theoretical predictions showing agreement with experimental results. We propose a novel calibration-free method to measure VLF electric fields, bypassing traditional Stark shift measurements. This method detects additional splitting intervals of Stark sublevels, separated from the degenerate energy level under a DC field. This phenomenon arises from the averaging effect of sublevel sinusoidal oscillations in the spectrum induced by the VLF field. The splitting interval is proportionally dependent on the VLF field amplitude. The VLF electric field sensor is enhanced by increasing the strength of the DC field, extending the traceable measurement limit for weak VLF electric fields by more than an order of magnitude. This work highlights the potential for precise VLF electric field measurements, significantly advancing the calibration-free detection capabilities of Rydberg atom sensors for low-frequency applications.